Modified circular RNA and its uses

By introducing N6-methyladenosine (m6A) into circular RNA, the immunogenicity of circular RNA is manipulated, addressing the lack of effective methods for biotechnological applications and enhancing its adjuvant properties for immune responses and tumor immunity.

JP2026094352APending Publication Date: 2026-06-09THE BOARD OF TRUSTEES OF THE LELAND STANFORD JUNIOR UNIV

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
THE BOARD OF TRUSTEES OF THE LELAND STANFORD JUNIOR UNIV
Filing Date
2026-03-04
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The interaction of RIG-I with circular RNA, particularly in the context of foreign circRNA detection, has not been fully investigated, and existing methods for manipulating the immunogenicity of circular RNA are lacking, which is crucial for biotechnological applications.

Method used

The introduction of N6-methyladenosine (m6A) into circular RNA molecules to modulate their immunogenicity, either by reducing or increasing it, through methods such as in vitro transcription and conjugation with RNA-binding proteins, to induce or suppress innate immune responses.

Benefits of technology

The modified circular RNA effectively induces or reduces immunogenicity, acting as a potent adjuvant for antigen-specific T cell activation and antitumor immunity, and can sequester RNA-binding proteins within cells.

✦ Generated by Eureka AI based on patent content.

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Abstract

The present invention provides compositions and methods for manipulating the immunogenicity of circular RNA. [Solution] In this specification, at least one N6-methyladenosine (m 6 A method for producing recombinant circular RNA molecules including A) is presented. 6 A-modified circRNAs can be used to deliver substances to cells and sequester RNA-binding proteins within the cells. Methods for modulating the immunogenicity of circular RNAs are also provided.
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Description

[Technical Field]

[0001] Cross-reference of related applications This application claims priority to U.S. Provisional Patent Application No. 62 / 892,776, filed on 28 August 2019, which is incorporated herein by reference in its entirety.

[0002] Statements regarding sequence listings The sequence listing associated with this application is presented in text format, not in paper form, and is incorporated herein by reference. The name of the text file containing the sequence listing is STDU2_37833_101_SeqList_ST25.txt. The file is approximately 4kb in size, was created on August 24, 2020, and filed electronically. field This application relates to a method for modifying circular RNA to reduce or increase its immunogenicity, as well as a method for using modified circular RNA. [Background technology]

[0003] Tens of thousands of circular RNAs (circRNAs) have been identified in eukaryotes. Viruses such as hepatitis delta virus and plant viroids possess circRNA genomes, and many viruses produce circular RNA as a normal part of their replication cycle. Recent studies suggest a new picture of the innate immune system, partly based on circRNA. While the introduction of certain exogenous circRNAs can activate antiviral and immunogene expression programs, endogenous circRNAs, as a whole, inhibit protein kinase R and can set a threshold for innate immunity during viral infection.

[0004] The mammalian innate immune system relies on pattern recognition receptors (PRRs) that recognize pathogen-associated molecular patterns (PAMPs), which are common among viruses and bacteria. RIG-I and MDA5 are cytosolic PRRs that sense foreign nucleic acids. MDA5 is known to detect long dsRNAs, while RIG-I has been shown to recognize the 5' triphosphate on short dsRNAs. Linear RNA ligands for RIG-I activation have been extensively characterized, but the interaction of RIG-I with circRNAs, particularly in the context of foreign circRNA detection, has not been investigated.

[0005] N6-methyladenosine (m 6 A) is one of the most abundant RNA modifications. On mRNA, m 6 A has been shown to regulate a variety of functions, including splicing, translation, and degradation, which can exert effects at both the cellular and tissue levels. Existing research has shown that m 6 A is also present on circRNA, suggesting its potential to induce cap-independent translation. However, m 6 The effects of A on circRNA function and its role in circRNA detection by RIG-I are unknown. [Overview of the project] [Problems that the invention aims to solve]

[0006] For use in biotechnology with circular RNA platforms, compositions and methods for manipulating the immunogenicity of circular RNA remain necessary. [Means for solving the problem]

[0007] (Summary of the invention) This specification presents compositions and methods for manipulating the immunogenicity of circular RNA, as well as their uses.

[0008] In some embodiments, this disclosure relates to N6-methyladenosine (m 6 A) We present a vaccine composition containing a circular RNA molecule that does not contain any residues.

[0009] In some embodiments, the present disclosure relates to a composition comprising a DNA sequence encoding a circular RNA, wherein the circular RNA is N6-methyladenosine (m 6 A) We present a composition that does not contain any residues.

[0010] The disclosure also presents a method for inducing an innate immune response in a subject that requires induction of an innate immune response, the method comprising administering to the subject an effective amount of a composition comprising a DNA sequence encoding a circular RNA described herein.

[0011] This disclosure also relates to a method for inducing an innate immune response in a subject that requires the induction of an innate immune response, wherein an effective amount of m is delivered to the subject. 6 We also present a method that includes the step of administering a vaccine composition containing a circular RNA molecule that does not contain an A residue.

[0012] This specification also provides a method for producing circular RNA by in vitro transcription, comprising the steps of: preparing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphate and RNA polymerase; transcribing linear RNA from the DNA template; and circulating the linear DNA to form circular RNA; wherein the ribonucleotide triphosphate is N6-methyladenosine-5' triphosphate (m 6 A method is also presented in which circular RNA, completely free of ATP, can induce an innate immune response in a target.

[0013] Also provided herein is a method for generating circular RNA molecules by in vitro transcription, the method comprising the steps of: providing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphates, and an RNA polymerase; transcribing linear RNA from the DNA template; and circularizing the linear RNA to form circular RNA; wherein the ribonucleotide triphosphates comprise N6-methyladenosine-5’-triphosphate (m 6 ATP); and also provided is a method wherein the circular RNA has reduced immunogenicity compared to circular RNA produced using the same method but in the absence of m 6 ATP.

[0014] The present disclosure provides a method for delivering a substance to a cell, the method comprising: (a) generating a recombinant circular RNA molecule comprising at least one N6-methyladenosine (m 6 A); (b) conjugating the substance to the recombinant circular RNA molecule to produce a complex comprising the recombinant circular RNA molecule conjugated to the substance; and (c) contacting the cell with the complex, whereby the substance is delivered to the cell.

[0015] The present disclosure also provides a method for sequestering an RNA-binding protein within a cell, the method comprising: (a) generating a recombinant circular RNA molecule comprising at least one N6-methyladenosine (m 6 A) and one or more RNA-binding protein-binding domains; and (b) contacting a cell comprising the RNA-binding protein with the recombinant circular RNA molecule, whereby the RNA-binding protein binds to the one or more RNA-binding protein-binding domains and is sequestered within the cell.

[0016] The present disclosure provides a method for reducing the innate immunogenicity of a circular RNA molecule, the method comprising: (a) providing a circular RNA molecule that induces an innate immune response in a subject; and (b) introducing at least one N6-methyladenosine (m 6We further present a method that includes the step of introducing A) into a circular RNA molecule to obtain a modified circular RNA molecule with reduced innate immunogenicity.

[0017] Also provided is a method for increasing the innate immunogenicity of a circular RNA molecule in a target, comprising the steps of (a) creating a circular RNA molecule lacking the RRACH motif (SEQ ID NO: 18); and (b) replacing one or more adenosines in the circular RNA sequence with another base (e.g., U, C, G, or inosine) to obtain a modified circular RNA molecule with increased innate immunogenicity. [Brief explanation of the drawing]

[0018] [Figure 1-1] Figure 1A includes images illustrating agarose gel electrophoresis of circFOREIGN before gel purification (left) and TapeStation analysis of the resulting purified RNA (right). Figure 1B is a graph showing the gene expression of innate immune genes in HeLa cells 24 hours after RNA transfection. The relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to the expression after mock transfection. Mean ± SEM is shown (n=3). *Student's t-test comparing circFOREIGN transfection with gel-purified RNA transfection shows p<0.05. [Figure 1-2]Figure 1C is an HPLC chromatogram for circFOREIGN purification. The output waveform shows the recovered fraction (left) and TapeStation analysis of the purified RNA (right). Figure 1D is a graph showing the gene expression of innate immune genes in HeLa cells 24 hours after RNA transfection. The relative expression of the indicated mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to the expression after mock transfection. Mean ± SEM is shown (n=3). *Student's t-test comparing circFOREIGN transfection with the indicated RNA transfection shows p<0.05. [Figure 2-1] Figure 2A is a schematic diagram illustrating subcutaneous injection of agonist RNA with OVA. ICS and antibody titers for T cells were measured at the time points indicated after primary and secondary immunization. Figure 2B is a graph illustrating that circRNA stimulates a transfection agent-independent anti-OVA T cell response after primary vaccination. The mean value (n=5) shows a p<0.05 result by the Kruskal-Wallis test. Figure 2C is a graph illustrating that circRNA stimulates a transfection agent-independent anti-OVA antibody titer after secondary vaccination. The mean value (n=5) shows a p<0.05 result by the Anova-Tukey test. [Figure 2-2]Figure 2D is a schematic diagram illustrating vaccination with circFOREIGN with OVA delivered by subcutaneous injection. After 14 days, OVA-expressing B16 melanoma cells were established in the left and right flanks. The tumors were measured and imaged. Figure 2E is a figure including images showing the quantitative bioluminescence measurements in the left and right tumors of mice vaccinated with PBS or circFOREIGN before tumor establishment. The p-values ​​are calculated by the Wilcoxon signed-rank test. There are 5 mice in each group. Figure 2F is a figure including graphs showing the quantitative bioluminescence measurements in the left and right tumors of mice vaccinated with PBS or circFOREIGN before tumor establishment. The p-values ​​are calculated by the Wilcoxon signed-rank test. There are 5 mice in each group. Figure 2G is a graph showing that mice vaccinated with circFOREIGN survive twice as long as negative control mice. The graph shows the survival curve for mice vaccinated with PBS or circFOREIGN before tumor establishment. The p-values ​​are calculated by the log-rank test. Each group consists of n=5 mice. [Figure 3-1] Figure 3A is a graph showing the gating strategy for FACS analysis of IFNγ+ CD8+ T cells. Figure 3B is a graph showing that circFOREIGN stimulates a PEI-independent anti-OVA-specific T cell response after secondary immunization. Mean values ​​are shown (n=5), and p<0.05 by the Anova-Tukey test. Figure 3C is a graph showing that circFOREIGN stimulates a PEI-independent anti-OVA antibody titer after secondary immunization. Mean values ​​are shown (n=5), and p<0.05 by the Anova-Tukey test. [Figure 3-2] Figure 3D is a diagram containing graphs illustrating gating strategies for FACS analysis of cDC1 and cDC2 cells. Figure 3E is a diagram containing graphs illustrating how immunization with circFOREIGN activates dendritic cells (DCs) in mice. [Figure 3-3]Figure 3F is a graph showing the measurement of left and right tumor volumes in mice vaccinated with PBS or circFOREIGN. The p-values ​​are calculated using the Wilcoxon signed-rank test. Figure 3G is a graph showing survival curves for mice vaccinated with PBS or the positive control polyI:C. The p-values ​​are calculated using the log-rank test. [Figure 4-1] Figure 4A is a heatmap of peptide counts by ChIRP-MS for circZKSCAN1, circSELF, and circFOREIGN. The enzymes are classified as m6A writers, m6A readers, and m6A erasers. Figure 4B is a graph showing that the m6A mechanism associates with circZKSCAN1 and circSELF, but not with circFOREIGN, as indicated by ChIRP-MS. The enrichment factor relative to the RNase-treated control is shown. [Figure 4-2] Figure 4C is a schematic model showing the ZKSCAN1 intron that directs protein-assisted splicing, resulting in m6A-modified circSELF, and the phage td intron that directs autocatalytic splicing, forming unmodified circFOREIGN. Figure 4D is a graph showing that m6A-irCLIP identifies a highly reliable m6A position proximal to the circRNA splice junction. The ZKSCAN1 intron is sufficient to direct m6A modification on circSELF compared to td intron-directed circFOREIGN. The density of m6A-irCLIP reads was normalized to reads per million. Figure 4E is a graph showing the density of m6A-irCLIP reads near the circRNA splice junction of endogenous human circRNA in HeLa cells. The density of m6A-irCLIP reads was normalized to reads per million for reads proximal to the circRNA splice junction. [Figure 5]Figure 5A is a graph showing that m6A-irCLIP identifies highly reliable m6A locations in circSELF or circFOREIGN. It shows Fisher's exact test for RT stops enriched in circSELF or circFOREIGN. The density of m6A-irCLIP reads was normalized to reads per million. Figure 5B is a graph showing the frequency of m6A in endogenous linear RNA. Figure 5C is an image showing TapeStation analysis of in vitro transcription of circFOREIGN with and without RNase R treatment, incorporating the indicated level of m6A modification. Figure 5D is an image of qRT-PCR across the splice junction confirming the formation of unmodified and m6A-modified circRNA during in vitro transcription. The figure shows agarose gels of unmodified and m6A-modified circRNA after qRT-PCR using the indicated "inverted" primer. [Figure 6]Figure 6A is a graph illustrating that transfection of wild-type HeLa cells with unmodified circFOREIGN stimulates an immune response, while transfection with m6A-modified circFOREIGN does not. The graph shows the gene expression of innate immune genes 24 hours after RNA transfection. The relative expression of the indicated mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to the expression after mock transfection. Mean ± SEM (n=3) is shown, and *Student's t-test comparing gene stimulation by linear RNA with that of the indicated RNA shows p<0.05. Figure 6B is a graph illustrating that transfection of a circFOREIGN plasmid lacking the RRACH m6A consensus motif (SEQ ID NO: 17) stimulates an immune response at a higher level than circFOREIGN. The RRACH motif (n=12 sites) was mutated to RRUCH (sequence number 19) throughout the exon sequence. Mutation of all adenosines to uracil within the first 200 bases (n=37 sites) following the splice junction further increases immunogenicity. The graph shows the gene expression of innate immune genes after DNA plasmid transfection. Relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to expression after mock transfection. Mean ± SEM is shown (n=3). Student's t-test comparing circFOREIGN transfection with transfection of the shown RNA yielded **p<0.01 and ***p<0.001. Figure 6C is a graph illustrating that transfection of the circFOREIGN plasmid, in which all adenosines are replaced with uracil, results in increased immunogenicity. The relative expression levels of the displayed mRNA and the transfected RNA were measured by qRT-PCR, and the results were normalized to the expression levels after mock transfection.The mean ± SEM (n=3) shows that the p-value of Student's t-test comparing transfection with *circFOREIGN to transfection with the indicated RNA is < 0.01. Figure 6D is a graph showing that m6A-modified circFOREIGN mitigates the anti-OVA T cell response after primary vaccination. The mean (n=10) shows that the p-value of *Anova-Tukey test is < 0.05. Figure 6E is a graph showing that m6A-modified circRNA mitigates the anti-OVA antibody titer after secondary vaccination. The mean (n=10) shows that the p-value of *ANOVA-Tukey test is < 0.05. [Figure 7] Figure 7A is a schematic model of the effects of unmodified circFOREIGN and m6A-modified circFOREIGN on immunogenicity. Figure 7B is a graph showing that circFOREIGN stimulates an anti-OVA-specific T cell response, and 1% m6A-modified circFOREIGN alleviates immunity after secondary immunization. The mean value is shown (n=10), and the p-value by the Anova-Tukey test is < 0.05. Figure 7C is a graph showing that circFOREIGN stimulates anti-OVA antibody titers, and 1% m6A-modified circRNA alleviates immunity after secondary immunization. The mean value is shown (n=5), and the p-value by the Anova-Tukey test is < 0.05. [Figure 8-1] Figure 8A shows Western blot images of wild-type HeLa cells and two YTHDF2 knockout (KO) clones. Figure 8B is a graph showing the gene expression of innate immune genes 24 hours after RNA transfection of HeLa YTHDF2- / - clone #2. Relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to expression after mock transfection. Mean ± SEM values ​​are shown (n=3). Figure 8C is a schematic diagram of the YTHDF1 / 2 constructs used. Figure 8D shows Western blot images of YTHDF2-λ, YTHDF2, YTHDF2N, YTHDF2N-λ, YTHDF1N, and YTHDF1N-λ. [Figure 8-2] Figure 8E is a graph showing qRT-PCR against circRNA-BoxB or control actin RNA following enrichment with the indicated YTH protein by RIP-qPCR. Mean ± SEM is shown (n=3). *P<0.05 by Student's t-test. Figure 8F is a graph showing that transfection of YTHDF2 KO cells with unmodified circBoxB tethered to the C-terminal YTH domain of YTHDF2 is insufficient to alleviate the immune response. Relative expression of indicated mRNA and transfected RNA was measured by qRT-PCR, and the results were normalized to expression after mock transfection. Mean ± SEM is shown (n=3). *P<0.05 by Student's t-test comparing cells transfected with / without YTHDF2. Figure 8G is a graph showing that transfection of YTHDF2 KO cells with unmodified circBoxB tethered to an RFP-YTH domain protein fusion is insufficient to alleviate the immune response. Relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to expression after mock transfection. Mean ± SEM is shown (n=3). *P<0.05 in Student's t-test comparing cells transfected with / without YTHDF2. Figure 8H is a graph showing that transfection of unmodified circBoxB tethered to YTHDF1 is insufficient to alleviate the immune response. The graph shows the gene expression of innate immune genes 24 hours after RNA transfection in wild-type HEK 293T cells. The relative expression of the indicated mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to the expression after transfection with the plasmid expressing YTHDF1N-λN. Mean ± SEM values ​​are shown (n=3). [Figure 9-1]Figure 9A includes a schematic model showing the response to unmodified circFOREIGN or m6A-modified circFOREIGN. Transfection of YTHDF2- / - HeLa cells with either unmodified circFOREIGN or m6A-modified circFOREIGN stimulated an immune response. The right panel of Figure 9A shows graphs of innate immune gene expression 24 hours after RNA transfection. Relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to expression after mock transfection. Mean ± SEM is shown (n=3). Student's t-test was used to compare transfection with circFOREIGN with 0% m6A to transfection with the shown RNA. Figure 9B shows that ectopic expression of YTHDF2 rescues the response to unmodified circFOREIGN in YTHDF2 KO HeLa cells compared to that of m6A-modified circFOREIGN. The left panel of Figure 9B is a schematic model showing the response to m6A-modified circFOREIGN after rescue. The right panel of Figure 9B is a graph showing the gene expression of innate immune genes 24 hours after RNA transfection. The relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR and normalized to the expression after mock transfection. Mean ± SEM is shown (n=3). Student's t-test was used to compare circFOREIGN with 0% m6A with circFOREIGN with 1% m6A, with p<0.05. [Figure 9-2]Figure 9C illustrates how tethering of YTHDF2 to unmodified circFOREIGN shields against circRNA-mediated immunity. The left panel of Figure 9C is a schematic model showing in vivo tethering of the protein to RNA via lambda N and Box B, resulting in immunogenicity mitigation. The upper right panel of Figure 9C is a schematic diagram showing the protein domain architecture of full-length wild-type YTHDF2 with and without the lambda N tethering tag, and the N-terminal domains of YTHDF2 with and without the lambda N tethering tag. The lower right panel of Figure 9C is a graph showing qRT-PCR against circRNA-Box B or control actin RNA following enrichment of the indicated YTH protein by RIP-qPCR. Mean ± SEM values ​​are shown (n=3). Student's t-test was used to compare the N-terminus of YTHDF2 with lambda N tethering to the N-terminus of YTHDF2 without tethering, and the result was p<0.05. Figure 9D is a graph showing that transfection of wild-type HeLa cells with unmodified circBoxB tethered to full-length wild-type YTHDF2 mitigated the immune response. The graph shows the gene expression of innate immune genes 24 hours after RNA transfection. The relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to mock transfection. Wild-type YTHDF2-lambda N (gray) was ectopically expressed as a negative control for immunogenicity. Transfection with circBoxB alone was used as a positive control for immunogenicity. Mean ± SEM results are shown (n=3). Using Student's t-test, comparing circBoxB with wild-type YTHDF2 with lambda N tethering to circBoxB with wild-type YTHDF2 without lambda N tethering, p<0.05 was obtained. Figure 9E is a graph showing that transfection of YTHDF2 KO cells with unmodified circBoxB tethered to the N-terminal domain of YTHDF2 was insufficient to mitigate the immune response.The graph shows the gene expression of innate immune genes 24 hours after RNA transfection. The relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR, and the results were normalized to mock transfection. The N-terminal domain of YTHDF2-lambda N (black) was ectopically expressed as a negative control for immunogenicity. Mean ± SEM results are shown (n=3). Student's t-test was used to compare circBoxB with the N-terminus of YTHDF2 with lambda N tethering with circBoxB with the N-terminus of YTHDF2 without tethering. [Figure 10] Figure 10A is a graph showing that RIG-I knockout rescues cell death induced by the depletion of the m6A writer METTL3. The graph shows the multiplicative change in cell death in wild-type HeLa cells or RIG-I KO HeLa cells after transfection with the indicated RNA. Mean ± SEM values ​​are shown (n=approximately 50,000 cells analyzed). Student's t-test was used to compare mock transfection with transfection with the indicated RNA, with *p<0.05 and ***p<0.001. Figure 10B is a table showing the raw cell counts from the FACS analysis depicted in Figure 10A. Figure 10C is an image showing the METTL3 knockdown efficiency by Western blotting in wild-type HeLa cells and RIG-I KO HeLa cells transfected with METTL3 siRNA or non-targeting control siRNA. Figure 10D shows images of RIG-I protein expression verified by Western blotting in wild-type HeLa cells and RIG-I knockout HeLa cells. Cells were transfected with METTL3 siRNA or non-targeting siRNA under conditions equivalent to those of a FACS experiment. [Figure 11]Figure 11A is a graph showing that circFOREIGN does not induce ATPase activity of RIG-I. RIG-I and RNA were incubated, and ATP was added. At the indicated time, the reaction was quenched and the Pi concentration was measured. Mean ± SEM values ​​are shown (n=2). Figure 11B is a figure containing representative electron microscope images of RIG-I filaments after incubation of RIG-I with the indicated RNA. Figure 11C is an image illustrating the results of an in vitro RIG-I binding assay with purified RIG-I, K63-conjugated polyubiquitin, and the indicated RNA ligand. The depicted Native gel electrophoresis shift assay shows that binding to RIG-I does not distinguish between unmodified circFOREIGN and m6A-modified circFOREIGN. Figure 11D is an image illustrating the results of in vitro reconstitution with or without purified RIG-I, MAVS, the indicated RNA ligand, and K63-bound polyubiquitin. The depicted native gel for the fluorescently labeled MAVS 2CARD domain shows that circFOREIGN-induced MAVS filament formation is dependent on K63-bound polyubiquitin. Figure 11E is an image illustrating in vitro reconstitution of circRNA-mediated induction of IRF3 dimerization. RIG-I, IRF3, and the indicated RNA ligand were incubated. The native gel for radiolabeled IRF3 with the indicated RNA ligand is shown. Cytoplasmic RNA (cytoRNA) and the indicated RNA were added at 0.5 ng / mL, respectively. [Figure 12]Figure 12A is an image illustrating the in vitro reconstitution with purified RIG-I, MAVS, K63-Ubn, and the indicated RNA ligand. The native gel for the fluorescently labeled MAVS 2CARD domain is shown. Figure 12B is a figure containing representative electron microscope images of MAVS filaments after the MAVS polymerization assay with the indicated RNA. The scale bar points to 600 nm. Figure 12C is a graph showing the quantification of the total number of MAVS filaments observed in five electron microscope images for each agonist RNA. *P<0.05 by Student's t-test. Figure 12D is an image illustrating the in vitro reconstitution of circRNA-mediated induction of IRF3 dimerization. The native gel for radiolabeled IRF3 with the indicated RNA ligand is shown. S1 is the cell extract. [Figure 13] Figure 13A is a figure containing immunofluorescence images showing that circFOREIGN colocalizes with RIG-I and K63-bound polyubiquitin chains. A representative field of view is shown. Figure 13B is a graph showing the quantitative colocalization of circFOREIGN with RIG-I and K63-Ubn (n=152). Forsyth images representative of the replicated experiments were collected across 10 fields of view across biological replicates. Figure 13C is a figure containing immunofluorescence images showing that 10% m6A circFOREIGN increased colocalization with YTHDF2. A representative field of view is shown. Forsyth images representative of the replicated experiments were collected across >10 fields of view. Figure 13D is a graph showing the quantitative colocalization of circFOREIGN and 10% m6A circFOREIGN with YTHDF2 and RIG-I. *Pearson's χ2 test shows p<0.05. [Figure 14] This is a schematic diagram illustrating a hypothetical mechanism by which RIG-I recognizes foreign circRNAs, depending on K63-binding polyubiquitin. [Figure 15]This graph shows that transfection of wild-type HeLa cells with unmodified circRNA (i.e., lacking m6A modification) stimulates an immune response. The graph shows the gene expression of innate immune genes 24 hours after RNA transfection. The relative expression of the shown mRNA and the transfected RNA was measured by qRT-PCR and the results were normalized to the expression after mock transfection. Mean ± SEM values ​​are shown (n=3). [Modes for carrying out the invention]

[0019] This disclosure relates, at least in part, to the N6-methyladenosine (m) of human circular RNA molecules (circRNA). 6 A) This is based on the discovery that RNA modification reduces the immunogenicity of circRNA. Exogenous circRNAs are potent adjuvants that induce antigen-specific T cell activation, antibody production, and antitumor immunity in vivo, and their m 6 A modification has been found to activate immunogenes and eliminate their adjuvant activity. 6 The A leader protein YTHDF2 is m 6 It is important for sequestering A-circRNA and suppressing innate immunity.

[0020] definition To facilitate understanding of this technology, numerous terms and phrases are defined below. Further definitions are provided throughout the "Modes for Carrying Out the Invention."

[0021] As used herein, the terms “nucleic acid,” “polynucleotide,” “nucleotide sequence,” and “oligonucleotide” are interchangeable and refer to polymers or oligomers of pyrimidine bases and / or purine bases, preferably cytosine, thymine, and uracil, and adenine and guanine, respectively. The terms encompass any deoxyribonucleotide, ribonucleotide, or peptide nucleic acid components and any chemical variants thereof, such as methylated, hydroxymethylated, or glycosylated forms of these bases. Polymers or oligomers may be heterogeneous or homogeneous in a composition, may be isolated from naturally occurring sources, or may be artificially or synthetically produced. In addition, nucleic acids can be DNA or RNA or mixtures thereof, and may be constitutively or transiently present in single-stranded or double-stranded forms, including homo-double-stranded, hetero-double-stranded, and hybrid states thereof. In some embodiments, nucleic acids or nucleic acid sequences include other types of nucleic acid structures, such as DNA / RNA helices, peptide nucleic acids (PNAs), morpholino nucleic acids (see, e.g., Braasch and Corey, Biochemistry, 41(14):4503-4510 (2002) and U.S. Patent No. 5,034,506), located nucleic acids (LNAs; see, Wahlestedt et al., Proc. Natl. Acad. Sci. USA, 97:5633-5638 (2000)), cyclohexynyl nucleic acids (see, Wang, J. Am. Chem. Soc., 122:8595-8602 (2000)), and / or ribozymes. The terms “nucleic acid” and “nucleic acid sequence” may also include chains containing non-natural nucleotides, modified nucleotides, and / or non-nucleotide components that may perform the same function as natural nucleotides (e.g., “nucleotide analogs”).

[0022] As used herein, the term “nucleoside” refers to a purine or pyrimidine base conjugated to a ribose or deoxyribose sugar. Nucleosides commonly found in DNA or RNA include cytidine, cytosine, deoxyriboside, thymidine, uridine, adenosine, adenine deoxyriboside, guanosine, and guanine deoxyriboside. As used herein, the term “nucleotide” refers to one of the monomeric units from which DNA polymers or RNA polymers are constructed, and which comprises a purine or pyrimidine base, a pentose sugar, and a phosphate group. The nucleotides of DNA are deoxyadenylic acid, thymidylic acid, deoxyguanylic acid, and deoxycytidylic acid. The corresponding nucleotides of RNA are adenylic acid, uridylic acid, guanylic acid, and cytidylic acid.

[0023] In this specification, the terms “peptide,” “polypeptide,” and “protein” are used interchangeably and refer to polymeric forms of amino acids comprising at least two or more consecutive amino acids, which may include coding amino acids and non-coding amino acids, chemically modified or biochemically modified amino acids or derivatized amino acids, and polypeptides having a modified peptide backbone.

[0024] The nomenclature for nucleotides, nucleic acids, nucleosides, and amino acids used herein conforms to the International Union of Pure and Applied Chemistry (IUPAC) standards (see, for example, bioinformatics.org / sms / iupac.html).

[0025] As used herein, the term “RRACH motif” refers to a 5-nucleotide DNA motif or RNA motif, where R can be A or G, and H can be A, C or T / U. The RRACH motif has a consensus sequence in DNA, 5'-(A or G)-(A or G)-AC-(A or C or T)-3' (SEQ ID NO: 17), or a consensus sequence in RNA, 5'-(A or G)-(A or G)-AC-(A or C or U)-3' (SEQ ID NO: 18). 6 A modification typically occurs within the RRACH motif in eukaryotic cells. In many cell types, m 6 The addition of A is catalyzed by a multi-component methyltransferase complex comprising METTL3, METTL14, and WTAP. In some embodiments, the RRACH motif (SEQ ID NOs. 17-18) is m 6 The A modification may be reduced or eliminated. For example, the RRACH motif may be modified into the RRUCH motif (sequences 19-20).

[0026] An "antigen" is a molecule that elicits an immune response in mammals. An "immune response" may involve, for example, the production of antibodies and / or the activation of immune effector cells. In the context of this disclosure, an antigen may include any subunit, fragment, or epitope of any proteinaceous or nonproteinaceous molecule (e.g., carbohydrates or lipids) that elicits an immune response in mammals. An "epitope" means a sequence of antigen recognized by an antibody or antigen receptor. In the art, an epitope is also referred to as an "antigenic determinant." An antigen may be a protein or peptide of viral, bacterial, parasitic, fungal, protozoan, prion, cell, or extracellular origin that elicits an immune response in mammals, preferably resulting in protective immunity.

[0027] As used herein, the term “recombinant” means a product of a variety of combinations of cloning, restriction, polymerase chain reaction (PCR) and / or ligation steps, resulting in a construct having a structurally coding or structurally non-coding sequence that is distinguishable from endogenous nucleic acids found in the natural system. The DNA sequence encoding a polypeptide may be assembled from cDNA fragments, or from a series of synthetic oligonucleotides that yield synthetic nucleic acids expressible from recombinant transcription units contained within intracellular or cell-free transcription and translation systems. Genomic DNA containing the sequence of interest may also be used in the formation of recombinant genes or transcription units. The non-coding DNA sequence may be located at the 5' or 3' end of the open reading frame; in these cases, such sequences may not interfere with the manipulation or expression of the coding region but may act to modulate the creation of the desired product through various mechanisms. Alternatively, a DNA sequence encoding untranslated RNA may also be considered recombinant. Therefore, the term “recombinant” nucleic acid may also refer to nucleic acids that do not exist in nature, for example, nucleic acids created by artificial combinations of two sequence segments separated in a way that does not exist in nature, through human intervention. These artificial combinations are often achieved by chemical synthesis or artificial manipulation of isolated nucleic acid segments, for example, by genetic engineering. Such artificial combinations are typically made by replacing codons with codons that encode the same amino acid, a conserved amino acid, or a non-conserved amino acid. Alternatively, artificial combinations may be carried out to create a combination of desired functions by linking nucleic acid segments having the desired function together. These artificial combinations are often achieved by chemical synthesis or artificial manipulation of isolated nucleic acid segments, for example, by genetic engineering. When recombinant polynucleotides encode polypeptides, the sequence of the encoded polypeptide may be a naturally occurring ("wild-type") sequence or a variant (e.g., a mutant) of a naturally occurring sequence.Therefore, the term "recombinant" polypeptide does not necessarily refer to polypeptides whose sequences do not occur naturally. Rather, a "recombinant" polypeptide is encoded by a recombinant DNA sequence, but the polypeptide sequence may be a naturally occurring ("wild-type") sequence or a sequence that does not occur naturally (e.g., a mutant or mutant). Thus, a "recombinant" polypeptide may contain naturally occurring amino acid sequences, even if they involve human intervention.

[0028] The term "binding domain" refers to a protein domain that can non-covalently bind to another molecule. Binding domains can, for example, bind to DNA molecules (DNA-binding proteins), RNA molecules (RNA-binding proteins), and / or protein molecules (protein-binding proteins). In the case of protein domains that bind to proteins, the protein may bind to itself (forming homodimers, homotrimers, etc.) or / or to one or more molecules by one or more different proteins.

[0029] Circular RNA Circular RNA (circRNA) is a single-stranded RNA molecule that is linked from head to tail and was initially discovered in pathogenic genomes such as hepatitis D virus (HDV) and plant viroids. CircRNA is recognized as a class of non-coding RNA that is ubiquitous within eukaryotic cells. Due to their remarkable stability, circRNAs produced via backsplicing are hypothesized to function in intercellular communication or memory.

[0030] Although the function of endogenous circRNAs is unknown, their large number and the presence of viral circRNA genomes suggest the existence of a circRNA-mediated immune system, as evidenced by recent discoveries of human circRNA-mediated modulation of viral resistance via NF90 / NF110 regulation (Li et al., 2017) and modulation of autoimmunity via PKR regulation (Liu et al., 2019). As supported herein, circRNAs can act as potent adjuvants that induce specific T-cell and B-cell responses. In addition, circRNAs can induce both innate and adaptive immune responses and have the ability to inhibit tumor establishment and growth.

[0031] While intron identification determines circRNA-mediated immunity (Chen et al., previously cited), since introns are not part of the final circRNA product, it is hypothesized that introns can direct the conferral of one or more covalent chemical markings to circRNA. Of the more than 100 known RNA chemical modifications, m 6 A is the most abundant modification on linear mRNA and long non-coding RNA, present in 0.2% to 0.6% of all adenosine in mammalian poly(A) tail transcripts (Roundtree et al., Cell, 169:1187-1200 (2017)). 6 A has recently been detected on mammalian circRNAs (Zhou et al., Cell Reports, 20:2262~2276 (2017)). As described herein, human circRNAs, at birth, are programmed with one or more covalent m based on introns that program their backsplicing. 6 It is thought that it is marked by A modification.

[0032] In some embodiments, the method described herein involves at least one N6-methyladenosine (m 6The process involves a step of producing a recombinant circular RNA molecule containing A). Recombinant circRNAs can be produced or manipulated using conventional molecular biology methods. As disclosed above, recombinant circRNA molecules are typically produced by backsplicing of linear RNA. In one embodiment, circular RNA is produced from linear RNA by backsplicing from downstream of the 5' splicing site (splicing donor) to upstream of the 3' splicing site (splicing acceptor). Circular RNA can thus be produced by any non-mammalian splicing method. For example, linear RNA containing various types of introns, including self-splicing group I introns, self-splicing group II introns, spliceosome introns, and tRNA introns, can be circularized. In particular, group I and group II introns have the advantage of being easily usable for the production of circular RNA in vitro and in vivo due to their ability to undergo self-splicing, which is due to their autocatalytic ribozyme activity.

[0033] Alternatively, circular RNA can be produced in vitro from linear RNA by chemical or enzymatic ligation of the 5' and 3' ends of the RNA. Chemical ligation can be carried out, for example, by using cyanogen bromide (BrCN) or ethyl-3-(3'-dimethylaminopropyl)carbodiimide (EDC) to activate the phosphomonoester group of the nucleotide, enabling the formation of a phosphodiester bond (Sokolova, FEBS Lett, 232:153~155 (1988); Dolinnaya et al., Nucleic Acids Res., 19:3067~3072 (1991); Fedorova, Nucleosides Nucleotides Nucleic Acids, 15:1137~1147 (1996)). Alternatively, enzymatic ligation can be used to circulate RNA. Exemplary ligases that may be used include T4 DNA ligase (T4 Dnl), T4 RNA ligase 1 (T4 Rnl 1), and T4 RNA ligase 2 (T4 Rnl 2).

[0034] In other embodiments, sprint ligation may be used to circularize RNA. Sprint ligation involves the use of an oligonucleotide sprint that hybridizes with two ends of a linear RNA, integrating the ends of the linear RNA for ligation. The hybridization of the sprint, which may be a deoxyribonucleotide or a ribonucleotide, aligns the 5'-phosphate and 3'-OH of the RNA terminus with the orientation of ligation. Subsequent ligation may be carried out using the chemical or enzymatic methods described above. Enzymatic ligation may be carried out, for example, with T4 DNA ligase (requiring DNA sprinting), T4 RNA ligase 1 (requiring RNA sprinting), or T4 RNA ligase 2 (requiring DNA or RNA sprinting). When the structure of the hybridized sprint-RNA complex interferes with enzyme activity, chemical ligation using BrCN or EDC may be more efficient than enzymatic ligation in some cases (see, for example, Dolinnaya et al., Nucleic Acids Res, 21(23):5403~5407 (1993); Petkovic et al., Nucleic Acids Res, 43(4):2454~2465 (2015)).

[0035] One or more m 6 A-modified circular RNA molecules can be produced using any suitable method known in the art for introducing non-native nucleotides into nucleic acid sequences. In some embodiments, m 6 A can be introduced into an RNA sequence using an in vitro transcription method, such as the in vitro transcription method described by Chen et al., previously cited. An exemplary in vitro transcription reaction requires a buffer system containing a purified linear DNA template, ribonucleotide triphosphates, DTT, magnesium, and a suitable phage RNA polymerase (e.g., SP6, T7, or T3) containing a promoter. As will be understood by those skilled in the art, the exact conditions used in the transcription reaction depend on the amount of RNA required for the specific application.

[0036] Any number of adenosines in a specific circRNA molecule produced as described herein shall be the corresponding number of m 6 It can be modified by (e.g., replaced by) A. Ideally, at least one adenosine molecule within the circRNA molecule is m 6 It is replaced by A. In some embodiments, at least 1% (e.g., 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9% or more) of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) is replaced by N6-methyladenosine. In other embodiments, at least 10% (e.g., 10%, 11%, 12%, 13%, 14%, 15%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or more) of the adenosine in the recombinant circular RNA molecule is replaced by N6-methyladenosine. For example, all (i.e., 100%) of the adenosine in the recombinant circular RNA molecule is replaced by N6-methyladenosine (m 6 A) can be replaced by m, which is introduced into recombinant circular RNA molecules. 6 It is understood that the number of A modifications depends on the specific use of circRNA as further described herein.

[0037] In some embodiments, a method for producing a circular RNA molecule by in vitro transcription includes the steps of: preparing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphates and RNA polymerase; transcribing linear RNA from the DNA template; and circularizing the linear DNA to form a circular RNA. In some embodiments, the ribonucleotide triphosphate is N6-methyladenosine-5' triphosphate (m 6 It contains no ATP whatsoever. In some embodiments, circular RNA can induce an innate immune response in a subject. In some embodiments, circular RNA can induce an innate immune response in a subject.

[0038] In some embodiments, a method for producing a circular RNA molecule by in vitro transcription includes the steps of: preparing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphates and RNA polymerase; transcribing linear RNA from the DNA template; and circularizing the linear DNA to form a circular RNA. In some embodiments, the ribonucleotide triphosphate is N6-methyladenosine-5' triphosphate (m 6 Contains ATP). In some embodiments, circular RNA is used in the same way, but m 6 It exhibits lower immunogenicity compared to circular RNA produced using the absence of ATP. The immunogenicity of circular RNA can be determined by measuring the inflammatory response after treatment with the circular RNA. In some embodiments, the immunogenicity of circular RNA can be determined by measuring the levels of a type I or type II interferon response or one or more pro-inflammatory cytokines that result after treatment with the circular RNA. For example, the immunogenicity of circular RNA can be determined by measuring the levels of interferon alpha (IFNα), interferon beta (IFNβ), interferon gamma (IFNγ), interferon omega (IFNω), interleukin-1 beta (IL-1β), interleukin-6 (IL-6), tumor necrosis factor alpha (TNF-α), interleukin-12 (IL-12), interleukin-23 (IL-23), or interleukin-17 (IL-17) after treatment with the circular RNA. In some embodiments, immunogenicity may be determined by measuring the expression or activity of one or more of the following: retinoic acid-inducible gene 1 (RIG-I), melanoma differentiation-associated protein 5 (MDA5), 2'-5'-oligoadenylate synthase (OAS), OAS-like protein (OASL), and double-stranded RNA-dependent protein kinase (PKR). Immunogenicity may be evaluated in vitro or in vivo. If the inflammatory response after treatment with the first circular RNA is reduced compared to the inflammatory response after treatment with the second circular RNA, the first circular RNA is less immunogenic than the second circular RNA.

[0039] In some embodiments, circular RNA is designed to have a desired level of immunogenicity. For example, circular RNA may be designed to be highly immunogenic, lowly immunogenic, substantially non-immunogenic, or designed to be non-immunogenic. The immunogenicity of circular RNA may be controlled by modifying the number of RRACH motifs present within the circular RNA, in which case an increase in the number of RRACH motifs results in decreased immunogenicity, and a decrease in the number of RRACH motifs results in increased immunogenicity. In some embodiments, the circular RNA or the DNA sequence encoding it contains 1-5, 5-10, 10-25, 25-100, 100-250, 250-500, or more than 500 RRACH motifs.

[0040] In some embodiments, at least 1% of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) In some embodiments, at least 10% of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) In some embodiments, all of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) is correct.

[0041] In some embodiments, less than 1% of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) For example, less than 0.9%, less than 0.8%, less than 0.7%, less than 0.5%, less than 0.4%, less than 0.3%, less than 0.2%, or less than 0.1% of adenosine in a recombinant circular RNA molecule is m 6 A is possible. In some embodiments, recombinant circular RNA may have 1-5, 5-10, 10-25, 25-100, 100-250, 250-500 or more m 6 Contains A residue.

[0042] Circular RNAs are generally more stable than their linear counterparts, mainly because they lack the free ends necessary for exonuclease-mediated degradation. However, to further improve their stability, the following methods are described herein. 6 A-modified circRNAs can be further modified. Other types of modifications can improve cyclization efficiency, circRNA purification, and / or protein expression from circRNAs. For example, recombinant circRNAs can also be manipulated to include "homologous arms" (i.e., arms of 9-19 nucleotides in length located at the 5' and 3' ends of the precursor RNA, intended to bring the 5' and 3' splicing sites closer together), spacer sequences, and / or phosphorothioate (PS) caps (Wesselhoeft et al., Nat. Commun., 9:2629 (2018)). Recombinant circRNAs can also be manipulated to include 2'-O-methyl conjugates, fluoroconjugates, or O-methoxyethyl conjugates, phosphorothioate backbones, or 2',4'-cyclic 2'-O-ethyl modifications to increase their stability (Holdt et al., Front Physiol., 9:1262 (2018); Kruetzfeldt et al., Nature, 438(7068):685~9 (2005); and Crooke et al., Cell Metab., 27(4):714~739 (2018)).

[0043] In some embodiments, a circular RNA molecule contains at least one intron and at least one exon. As used herein, the term “exon” refers to a nucleic acid sequence present in a gene that, after the excision of introns during transcription, is represented by the mature form of the RNA molecule. Exons can be translated into proteins (e.g., messenger RNA (mRNA)). As used herein, the term “intron” refers to a nucleic acid sequence present in a given gene that is removed by RNA splicing during the maturation of the final RNA product. Introns are generally found between exons. During transcription, introns are removed from precursor messenger RNA (premRNA), and exons are joined via RNA splicing.

[0044] In some embodiments, the circular RNA molecule comprises a nucleic acid sequence containing one or more exons and one or more introns. In some embodiments, the circular RNA molecule contains one or more exons. In some embodiments, the circular RNA molecule contains no introns at all.

[0045] In some embodiments, the circular RNA molecule may include an artificial sequence. The artificial sequence may confer desirable properties, such as desired binding properties. For example, the artificial sequence may bind to one or more RNA-binding proteins, or it may be complementary to one or more microRNAs. In some embodiments, the artificial sequence may be a scrambled form of a gene sequence or a sequence derived from naturally occurring circular RNA. The scrambled sequence typically has the same nucleotide composition as the sequence from which it is derived. Methods for producing scrambled nucleic acids are known to those skilled in the art. In some embodiments, the circular RNA includes an artificial sequence but does not include an exon. In some embodiments, the circular RNA includes an artificial sequence but also includes at least one exon.

[0046] Therefore, circular RNA can be produced by endogenous or exogenous introns, as described in WO2017 / 222911. Numerous intron sequences are known from a wide variety of organisms and viruses, including sequences derived from genes encoding proteins, ribosomal RNA (rRNA), or transfer RNA (tRNA). Representative intron sequences can be found in the Group I Intron Sequence and Structure Database (rna.whu.edu.cn / gissd / ) and the Database for Bacterial Group II Introns (webapps2.ucalgary.ca / ). ~ groupii / index.html), Database for Mobile Group II Introns(fp.ucalgary.ca / group2introns), Yeast Intron DataBase(emblS16 heidelberg.de / ExternalInfo / seraphin / yidb.html), Ares Lab Yeast Intron Database(compbio.soe.ucsc.edu / yeast_introns.html), U12 Intron Database (genome.crg.es / cgibin / u12db / u12db.cgi) and Exon-Intron Database (bpg.utoledo.edu / ~ It is available in a variety of databases, including afedorov / lab / eid.html.

[0047] In certain embodiments, recombinant circular RNA molecules are encoded by nucleic acids containing self-splicing group I introns. Group I introns are a distinctly different class of RNA self-splicing introns that catalyze their intrinsic excision from mRNA, tRNA, and rRNA precursors in a wide range of organisms. All known group I introns present in the eukaryotic nucleus interrupt functional ribosomal RNA genes located within ribosomal DNA loci. Nuclear group I introns, thought to be widespread among eukaryotic microorganisms and plasmodium (myxomycetes), contain abundant self-splicing introns. Self-splicing group I introns contained within circular RNA molecules may be obtained from, or derived from, any suitable organism, such as bacteria, bacteriophages, and eukaryotic viruses. Self-splicing group I introns may also be found in certain organelles, such as mitochondria and chloroplasts, and such self-splicing introns can be incorporated into the nucleic acids encoding circular RNA molecules.

[0048] In certain embodiments, recombinant circular RNA molecules are encoded by nucleic acids containing self-splicing group I introns of the phage T4 thymidylate synthase (td) gene. While the group I introns of the phage T4 thymidylate synthase (td) gene are well characterized as being circular, the exons remain linear and undergo splicing together (Chandry and Belfort, Genes Dev., 1:1028-1037 (1987); Ford and Ares, Proc. Natl. Acad. Sci. USA, 91:3117-3121 (1994); and Perriman and Ares, RNA, 4:1047-1054 (1998)). When the order of td introns flanking any exon sequence is reversed (i.e., the 5' half is positioned at the 3' position, and vice versa), the exon is cyclized via two autocatalytic transesterification reactions (Ford and Ares, cited above; Puttaraju and Been, Nucleic Acids Symp. Ser., 33:49~51 (1995)).

[0049] In some embodiments, the recombinant circular RNA described herein may include an internal ribosome entry site (IRES) that can be operably ligated to a polypeptide-encoding RNA sequence. Incorporation of the IRES enables translation of one or more open reading frames derived from the circular RNA. The IRES element attracts the eukaryotic ribosome translation initiation complex and promotes translation initiation (see, for example, Kaufman et al., Nuc. Acids Res., 19:4485~4490 (1991); Gurtu et al., Biochem. Biophys. Res. Comm, 229:295~298 (1996); Rees et al., BioTechniques, 20:102~110 (1996); Kobayashi et al., BioTechniques, 21:399~402 (1996); and Mosser et al., BioTechniques, 22:150~161 (1997)).

[0050] In this technical field, numerous IRES sequences are known and can be incorporated into circular RNA molecules. For example, IRES sequences can originate from a wide variety of viruses, including picornavirus leader sequences (e.g., encephalomyocarditis virus (EMCV) UTR) (Jang et al., J. Virol., 63:1651~1660 (1989)), polio leader sequences, hepatitis A virus leaders, hepatitis C virus IRESs, human rhinitis virus type 2 IRESs (Dobrikova et al., Proc. Natl. Acad. Sci., 100(25):15125~15130 (2003)), IRES elements derived from foot-and-mouth disease virus (Ramesh et al., Nucl. AcidRes., 24:2697~2700 (1996)), and giardiavirus IRESs (Garlapati et al., J. Biol. Chem., 279(5):3389~3397 (2004)). Yeast-derived IRES sequences, human angiotensin II type 1 receptor IRES (Martin et al., Mol. Cell Endocrinol., 212:51~61 (2003)), fibroblast growth factor IRES (e.g., FGF-1 IRES and FGF-2 IRES; Martineau et al., Mol. Cell. Biol., 24(17):7622~7635 (2004)), vascular endothelial growth factor IRES (Baranick et al., Proc. Natl. Acad. Sci. USA, 105(12):4733~4738 (2008)) Various nonviral IRES sequences, including but not limited to those mentioned above (Stein et al., Mol. Cell. Biol., 18(6):3112~3119 (1998); Bert et al., RNA, 12(6):1074~1083 (2006)) and insulin-like growth factor 2 IRES (Pedersen et al., Biochem. J., 363(1):37~44 (2002)), can also be incorporated into circular RNA molecules.

[0051] In some cases, recombinant circular RNA may contain a sequence encoding a protein or polypeptide operably ligated to an IRES. Recombinant circular RNA containing an IRES can be designed to produce a polypeptide of any desired size. For example, a circular RNA may contain an IRES operably ligated to an RNA sequence encoding an immunogenic polypeptide, such as an antigen derived from bacteria, viruses, fungi, protists, or parasites. Alternatively, a circular RNA may contain an IRES operably ligated to an RNA sequence encoding a therapeutic polypeptide, such as an enzyme, hormone, neurotransmitter, cytokine, antibody, tumor suppressor, or cytotoxic agent, for treating hereditary disorders, cancer, or other diseases.

[0052] In this technical field, IRES elements are well known, and nucleotide sequences and vectors encoding IRES elements are commercially available from various sources, such as Clontech (MountainView, CA), Invivogen (San Diego, CA), Addgene (Cambridge, MA), GeneCopoeia (Rockville, MD), and IRESite: a database of experimentally validated IRES structures (iresite.org).

[0053] Polynucleotides encoding the RNAs, polypeptides, introns, and IRESs desired for use in this disclosure can be prepared using standard molecular biology methods. For example, polynucleotide sequences can be prepared using recombination methods, such as by screening cell-derived cDNA libraries and genomic libraries or by excising polynucleotides from vectors known to contain polynucleotides. Polynucleotides may also be prepared by synthesis based on known sequences rather than by cloning. Complete sequences can be assembled from duplicate oligonucleotides prepared by standard methods, and then assembled and ligated into complete sequences (see, e.g., Edge, Nature, 292:756 (1981); Nambair et al., Science, 223:1299 (1984); and Jay et al., J. Biol. Chem., 259:6311 (1984)). Other methods for obtaining or synthesizing nucleic acid sequences include site-directed mutagenesis and polymerase chain reaction (PCR) (disclosed, e.g., Greene, MR and Sambrook, J., "Molecular Cloning: A Laboratory Manual," Cold Spring Harbor Laboratory Press, 4th edition (June 15, 2012)), automated polynucleotide synthesizers (see, e.g., Jayaraman et al., Proc. Natl. Acad. Sci. USA, 88:4084~4088 (1991)), oligonucleotide-directed synthesis (Jones et al., Nature, 54:75~82 (1986)), oligonucleotide-directed mutagenesis of existing nucleotide regions (Riechmann et al., Nature, 332:323~327 (1988) and Verhoeyen et al., Science, 239:1534~1536 (1988)), and T4 This includes, but is not limited to, enzymatic filling of oligonucleotide gaps using DNA polymerase (Queen et al., Proc. Natl. Acad. Sci. USA, 86:10029~10033 (1989)).

[0054] Recombinant circular RNA molecules can be any appropriate length or size. For example, a recombinant circular RNA molecule may contain nucleotides between approximately 200 and approximately 6,000 nucleotides (e.g., within a range defined by approximately 300, 400, 500, 600, 700, 800, 900, 1,000, 2,000, 3,000, 4,000, 5,000 nucleotides or any two of the aforementioned values). In some embodiments, the recombinant circular RNA molecule contains nucleotides between approximately 500 and approximately 3,000 nucleotides (a range defined by approximately 550, 650, 750, 850, 950, 1,100, 1,200, 1,300, 1,400, 1,500, 1,600, 1,700, 1,800, 1,900, 2,100, 2,200, 2,300, 2,400, 2,500, 2,600, 2,700, 2,800, 2,900 nucleotides or any two of the aforementioned values). In one embodiment, the recombinant circular RNA molecule contains approximately 1,500 nucleotides.

[0055] circRNA as an adjuvant m 6 CircRNA molecules that do not contain A can be used to induce an immune response in a target. Therefore, in some embodiments, m 6 CircRNAs lacking A can be used as adjuvants, for example, as part of a vaccine composition.

[0056] In some embodiments, immunogenic circular RNA is administered to a target that requires it. In some embodiments, immunogenic circular RNA is m 6 It does not contain A residues.

[0057] In some embodiments, the circular RNA includes a sequence encoding a polypeptide. The polypeptide may be, for example, an antigenic polypeptide. In some embodiments, the polypeptide includes multiple (i.e., at least two) antigens. The antigens may be derived from viruses, bacteria, parasites, fungi, protozoa, prions, cells, or extracellular sources. In some embodiments, at least one antigen is a tumor antigen. In some embodiments, the circular RNA of the vaccine composition includes an internal ribosome entry site (IRES) operably linked to the polypeptide-encoding sequence.

[0058] In some embodiments, the circular RNA is synthesized ex vivo before administration to the subject. In some embodiments, the circular RNA is prepared using in vitro transcription.

[0059] In some embodiments, the circular RNA is administered to the subject as naked RNA. In some embodiments, the circular RNA forms a complex with nanoparticles, such as polyethyleneimine (PEI) nanoparticles.

[0060] In some embodiments, a vector containing a DNA sequence encoding circular RNA is administered to a subject. In some embodiments, the DNA sequence encoding circular RNA is the m of circular RNA 6 It includes features that prevent a modification. For example, the DNA sequence may not contain the RRACH motif (SEQ ID NO: 17). The vector may be a non-viral vector, such as a plasmid. In some embodiments, the vector is a viral vector, such as an adenovirus vector, adeno-associated virus vector, retrovirus vector, lentiviral vector, or herpesvirus vector.

[0061] In some embodiments, the vector is targeted to one or more specific cell types. For example, the vector may bind specifically or preferentially to one cell type, but not specifically or preferentially to another. In some embodiments, the vector is targeted to cancer cells.

[0062] In some embodiments, the vaccine composition includes circular RNA. In some embodiments, the vaccine composition includes N6-methyladenosine (m 6 A) Contains a circular RNA molecule that does not contain any residues. In some embodiments, the circular RNA lacks the RRACH motif (SEQ ID NO: 18). In some embodiments, the circular RNA contains one or more RRUCH motifs (SEQ ID NO: 20).

[0063] In some embodiments, the vaccine composition includes N6-methyladenosine (m 6 A) A circular RNA molecule that does not contain any residues, and also contains at least one antigen.

[0064] In some embodiments, the circular RNA of the vaccine composition is prepared using in vitro transcription. In some embodiments, the circular RNA exists in the composition as naked RNA. In some embodiments, the circular RNA forms a complex with nanoparticles, such as polyethyleneimine (PEI) nanoparticles.

[0065] Vaccine compositions may be administered to subjects in need to treat or prevent a disease, disorder, or condition. Therefore, in some embodiments, a method for inducing an innate immune response in subjects in need of such induction includes the step of administering an effective amount of the vaccine composition to the subject.

[0066] circRNA as a delivery medium N6-methyladenosine (m) of non-natural circRNA 6 A) Modification inhibits the induced innate immune response, m 6A-modified circRNA molecules can be used to deliver a variety of substances to cells without being removed by the host immune system. Therefore, this disclosure also relates to a method for delivering a substance to a cell, comprising (a) at least one N6-methyladenosine (m 6 A method is also presented which includes the steps of: (a) creating a recombinant circular RNA molecule containing; (b) conjugating a substance to the recombinant circular RNA molecule to create a complex containing the recombinant circular RNA molecule conjugated to the substance; and (c) bringing cells into contact with the complex, thereby delivering the substance to the cells. The recombinant circular RNA molecule described above, m 6 The description of methods for producing A-modified, recombinant circular RNA molecules and their components also applies to the same aspects of methods for delivering substances to cells.

[0067] Any suitable substance, compound, or material may be delivered to a cell using the disclosed circular RNA molecule. The substance may be a biological substance and / or a chemical substance. For example, the substance may be a biomolecule such as a protein (e.g., peptide, polypeptide, protein fragment, protein complex, fusion protein, recombinant protein, phosphoprotein, glycoprotein, or lipoprotein), lipid, nucleic acid, or carbohydrate. Other substances that may be delivered to a cell using the disclosed circular RNA molecule include, but are not limited to, hormones, antibodies, growth factors, cytokines, enzymes, receptors (e.g., nerve receptors, hormone receptors, nutrient receptors, and cell surface receptors) or their ligands, cancer markers (e.g., PSA, TNF-alpha), myocardial infarction markers (e.g., troponin or creatine kinase), toxins, drugs (e.g., toxic drugs), and metabolites (e.g., including vitamins). In some embodiments, the substance is a protein or peptide such as an antigen, epitope, cytokine, toxin, tumor suppressor protein, growth factor, hormone, receptor, mitogen, immunoglobulin, neuropeptide, neurotransmitter, or enzyme. If a substance is an antigen or epitope, the antigen or epitope may be obtained from or derived from a pathogen (e.g., a virus or bacteria) or cancer cells (i.e., a "cancer antigen" or "tumor antigen").

[0068] In other embodiments, the substance may be a low molecular weight. As used herein, the term “low molecular weight” typically refers to low molecular weight (<900 daltons) organic compounds with a size on the order of 1 nm that can modulate biological processes. Low molecular weights exhibit a wide range of biological functions and are used in diverse applications, including intracellular signaling, pharmaceuticals, and insecticides. Examples of low molecular weights include amino acids, fatty acids, phenolic compounds, alkaloids, steroids, pyrine, and retinoids.

[0069] Any suitable method for biomolecular conjugation can be used to conjugate a substance to a recombinant circular RNA molecule, thereby forming a complex containing the recombinant circular RNA molecule conjugated to the substance. Ideally, the substance is covalently linked to the recombinant circular RNA molecule. The covalent linkage can occur via a linkage site present on the circular RNA molecule or on the substance. The linkage site is desirable to contain a chemical bond that can enable the release of a specific intracellular substance. Suitable chemical bonds are well known in the art and include disulfide bonds, acid-instability bonds, photo-instability bonds, peptidase-instability bonds, and esterase-instability bonds. Typical covalent conjugation methods target the side chains of specific amino acids, such as cysteine ​​and lysine. The cysteine ​​and lysine side chains contain thiol and amino groups, respectively, which allow them to undergo modification with a wide variety of reagents (e.g., linkage reagents). Bioconjugation methods are further described, for example, in N. Stephanopoulos and MBFrancis, Nature, Chaemical Biology, 7:876-884 (2011); Jain et al., Pharm Res., 32(11):3526-40 (2015); and Kalia et al., Curr. Org. Chem., 14(2):138-147 (2010).

[0070] Following the formation of a complex containing a substance ligated to a recombinant circular RNA molecule, the method includes the step of bringing a cell into contact with the complex, thereby delivering the substance to the cell. Any suitable prokaryotic or eukaryotic cell can be brought into contact with the complex. Examples of suitable prokaryotic cells include, but are not limited to, cells derived from the genera Bacillus (such as Bacillus subtilis and Bacillus brevis), Escherichia (such as E. coli), Pseudomonas, Streptomyces, Salmonella, and Erwinia. Particularly useful prokaryotic cells include diverse strains of Escherichia coli (e.g., K12, HB101 (ATCC accession number: 33694), DH5α, DH10, MC1061 (ATCC accession number: 53338), and CC102).

[0071] In the art, suitable eukaryotic cells are known, including, for example, yeast cells, insect cells, and mammalian cells. Examples of suitable yeast cells include those derived from the genera Hansenula, Kluyveromyces, Pichia, Rhinosporidium, Saccharomyces, and Schizosaccharomyces. Suitable insect cells include Sf-9 cells and HIS cells (Invitrogen, Carlsbad, Calif.), which are described, for example, Kitts et al., Biotechniques, 14:810~817 (1993); Lucklow, Curr. Opin. Biotechnol., 4:564~572 (1993); and Lucklow et al., J. Virol., 67:4566~4579 (1993).

[0072] In certain embodiments, the cells are mammalian cells. Numerous suitable mammalian cells are known in the art, many of which are available from the American Type Culture Collection (ATCC, Manassas, Va.). Examples of suitable mammalian cells include, but are not limited to, Chinese hamster ovary cells (CHO) (ATCC accession number: CCL61), CHODHFR- cells (Urlaub et al., Proc. Natl. Acad. Sci. USA, 97:4216~4220 (1980)), human embryonic kidney (HEK) 293 cells or 293T cells (ATCC accession number: CRL1573), and 3T3 cells (ATCC accession number: CCL92). Other suitable mammalian cell lines include the monkey COS-1 cell line (ATCC accession number: CRL1650) and COS-7 cell line (ATCC accession number: CRL1651), as well as the CV-1 cell line (ATCC accession number: CCL70). Further exemplary mammalian host cells include primate cell lines and rodent cell lines, including transformed cell lines. In addition to normal diploid cells and cell lines derived from in vitro cultures of primary tissues, primary explants are also suitable. Other suitable mammalian cell lines include, but are not limited to, mouse neuroblastoma N2A cells, HeLa cells, mouse L-929 cells, and the BHK hamster cell line or HaK hamster cell line, all of which are available from ATCC. In this art, methods for selecting appropriate mammalian host cells and for transforming, culturing, amplifying, screening, and purifying such cells are well known (see, for example, Ausubel et al., "Short Protocols in Molecular Biology," 5th edition, John Wiley & Sons, Inc., Hoboken, NJ (2002)).

[0073] Preferably, the mammalian cell is a human cell. For example, the mammalian cell may be a human immune cell, in particular a cell capable of presenting cellular antigens or epitopes to the immune system. Examples of human immune cells include lymphocytes (e.g., B lymphocytes or T lymphocytes), monocytes, macrophages, neutrophils, and dendritic cells. In one embodiment, the cell is a macrophage.

[0074] A complex containing a recombinant circular RNA molecule conjugated to a substance can be introduced into a cell by any suitable method, including, for example, transfection, transformation, or transduction. In this specification, the terms “transfection,” “transformation,” and “transduction” are used interchangeably and refer to the introduction of one or more exogenous polynucleotides into a host cell by physical or chemical means. Many transfection techniques are known in the art, including, for example, calcium phosphate DNA coprecipitation; DEAE dextran; electroporation; cationic liposome-mediated transfection; tungsten particle-enhanced microparticle guns; and strontium phosphate DNA coprecipitation.

[0075] In some embodiments, the complex may be delivered to cells in the form of naked RNA conjugated to a substance. In some embodiments, the complex may form a complex with nanoparticles for delivery to cells, such as polyethyleneimine (PEI) nanoparticles.

[0076] In some embodiments, the composition comprises RNA conjugated into a substance and may optionally include a pharmaceutically acceptable carrier. The selection of the carrier is determined in part by the specific circular RNA molecule and the type of cell(s) into which the circular RNA molecule is introduced. Thus, a variety of suitable compositions are possible. For example, the composition may contain preservatives such as methylparaben, propylparaben, sodium benzoate, and benzalkonium chloride. Optionally, a mixture of two or more preservatives may be used. In addition, buffers may also be used in the composition. Suitable buffers include, for example, citric acid, sodium citrate, phosphoric acid, potassium phosphate, and a variety of other acids and salts. Optionally, a mixture of two or more buffers may be used. Methods for preparing compositions for pharmaceutically acceptable use are known to those skilled in the art and are described in more detail, for example, in "Remington: Science and Practice of Pharmacy," Lippincott Williams & Wilkins, 21st edition (May 1, 2005).

[0077] In other embodiments, compositions containing a complex comprising a recombinant circular RNA molecule conjugated to a substance may be formulated as an inclusion complex, such as a cyclodextrin inclusion complex, or as a liposome. Liposomes may be used to target host cells or to extend the half-life of the circular RNA molecule. Methods for preparing liposome delivery systems are described, for example, in Szoka et al., Ann. Rev. Biophys. Bioeng., 9:467 (1980) and U.S. Patents 4,235,871; 4,501,728; 4,837,028 and 5,019,369. The complex may also be formulated as nanoparticles.

[0078] CircRNA for sequestering RNA-binding proteins The disclosure also relates to a method for sequestering RNA-binding proteins within a cell, comprising (a) at least one N6-methyladenosine (m 6A) a step of creating a recombinant circular RNA molecule containing one or more RNA-binding protein-binding motifs; and (b) a step of contacting a cell containing an RNA-binding protein with the recombinant circular RNA molecule, thereby causing the RNA-binding protein to bind to one or more RNA-binding protein-binding motifs and be sequestered within the cell. The recombinant circular RNA molecule described above, m 6 The descriptions of A modification, methods for producing recombinant circular RNA molecules, and methods for contacting cells with circRNA and its components also apply to the same aspects of methods for sequestering RNA-binding proteins within cells.

[0079] RNA-binding proteins play a major role in RNA metabolism, coordination of RNA-protein and protein-protein interactions, and regulation of RNA splicing, maturation, translation, transport, and turnover. Abnormal expression, dysfunction, and aggregation of RNA-binding proteins have been identified in several major classes of human diseases, including neuropathy, muscular atrophy, and cancer. Therefore, RNA-binding proteins, in particular when abnormally expressed intracellularly, may be associated with disease.

[0080] RNA-binding proteins typically contain one or more RNA recognition motifs (RRMs) (also referred to as "RNA-binding motifs"). Numerous RRMs are known for various different RNA-binding proteins. The ribonucleoprotein (RNP) domain (also known as "RNA recognition motif (RRM)" and "RNA-binding domain (RBD)") is one of the most abundant protein domains in eukaryotes. The RNP domain contains an RNA-binding domain of approximately 90 amino acids, including two consensus sequences: RNP-1 and RNP-2. RNP-1 mainly consists of eight conserved, positively charged, aromatic residues, while RNP-2 is a small, conserved sequence composed of six amino acid residues. The RNP domain has been shown to be necessary and sufficient for binding to RNA molecules due to its broad specificity and affinity. Other RNA-binding domains include, but are not limited to, zinc finger domains, hnRNPK homology (KH) domains, and double-stranded RNA-binding motifs (dsRBMs) (see, e.g., Clery A, H.-T., Allain F., "From Structure to Function of RNA Binding Domains," "Madame Curie Bioscience Database," Austin (TX): Landes Bioscience (2000-2013)). Recombinant circular RNA molecules are constructed to contain one or more domains recognized by RRMs or RNA-binding motifs (i.e., "RNA-binding protein-binding domains"). The selection of RNA-binding protein-binding domains to be incorporated into recombinant circRNA molecules depends on specific RNA-binding proteins that are targeted for sequestering within cells. Recombinant circular RNA molecules can be constructed to contain one or more RNA-binding protein-binding domains using conventional molecular biology and / or recombinant DNA methods.

[0081] In certain embodiments, RNA-binding proteins are abnormally expressed in cells that come into contact with recombinant circRNA molecules. As mentioned above, abnormal expression of RNA-binding proteins is associated with diseases such as neuropathy, muscular atrophy, and cancer. The expression of RNA-binding proteins is "abnormal" in the sense that it is non-normal. In this respect, a gene encoding an RNA-binding protein may result in abnormal levels of RNA-binding protein as a result of abnormal expression in the cell. Alternatively, gene expression may be normal, but the production of RNA-protein may be dysregulated or dysfunctional, resulting in abnormal levels of protein in the cell. Abnormal expression includes, but is not limited to, overexpression, underexpression, complete absence of expression, or transient dysregulation of expression (e.g., the gene is expressed at an inappropriate time in the cell). The expression of mutant or variant RNA-binding proteins at normal levels in the cell may also be considered an abnormality in RNA-binding protein expression. Therefore, in some embodiments, RNA-binding proteins are encoded by a nucleic acid sequence containing at least one mutation (e.g., deletion, insertion, or substitution).

[0082] In some embodiments, circular RNA may be delivered to cells in the form of naked RNA. In some embodiments, circular RNA may form a complex with nanoparticles for delivery to cells, such as polyethyleneimine (PEI) nanoparticles.

[0083] Modulation of circRNA on innate immunogenicity Depending on its final application, it may be desirable to modulate the innate immunogenicity of the circular RNA molecule. In this specification, the terms “innate immunogenicity” and “innate immunity” are used interchangeably and refer to nonspecific defense mechanisms that occur rapidly after exposure to an antigen, or within a few hours of exposure. These mechanisms include physical barriers such as skin, chemicals in the blood, and immune system cells that attack foreign cells in an organism. For example, when a circRNA molecule is used to sequester RNA-binding proteins within a cell, the innate immunogenicity induced by the circRNA molecule may be reduced to minimize its removal and maximize its protein sequestering effect. In this regard, this disclosure provides a method for reducing the innate immunogenicity of a circular RNA molecule in a subject, comprising the steps of (a) preparing a circular RNA molecule that induces an innate immune response in the subject; and (b) N6-methyladenosine (m 6 A) We present a method comprising the step of introducing at least one nucleoside selected from pseudouridine and inosine into a circular RNA molecule to obtain a modified circular RNA molecule with reduced innate immunogenicity. The circular RNA molecule described above, m 6 The description of methods for producing A-modified, recombinant circular RNA molecules and their components also applies to the same embodiments of methods for reducing the innate immunogenicity of circular RNA in a given subject.

[0084] Pseudouridine (also known as "psi" or "Y"), one of the most abundant modified nucleosides found in RNA, is present in a wide range of intracellular RNAs and is highly conserved across species. Pseudouridine is derived from uridine (U) via base-specific isomerization catalyzed by Ψ-synthase. Inosine is a nucleoside formed when hypoxanthine is joined to a ribose ring (also known as ribofuranose) via a β-N9 glycosidic bond. Inosine is generally found in tRNA and is essential for the proper translation of the gene code within fluctuating base pairs. Figure 15 supports the idea that the introduction of inosine or pseudouridine into circular RNA affects circRNA-mediated immunity. Independent of any theory, the introduction of inosine or pseudouridine into circular RNA affects its m 6 One approach is to prevent A modification. Ideally, at least 1% (e.g., 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9% or more) of the circular RNA molecule should be m 6 A contains pseudouridine and / or inosine. In other embodiments, at least 10% (e.g., 10%, 11%, 12%, 13%, 14%, 15%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or more) of the circular RNA molecule is m 6 A contains pseudouridine and / or inosine.

[0085] Alternatively, in embodiments in which circRNA is used to deliver antigenic proteins (e.g., tumor antigens or cancer antigens) to cells, the innate immunogenicity of circRNA molecules can be increased. For this purpose, the disclosure also presents a method for increasing the innate immunogenicity of a circular RNA molecule in a subject, comprising the steps of (a) creating a circular RNA molecule lacking the RRACH motif (SEQ ID NO: 18); and / or (b) substituting one or more adenosines in at least one exon with another base (e.g., U, G, C, or inosine) to result in a modified circular RNA molecule with increased innate immunogenicity. The descriptions above for circular RNA molecules, recombinant circular RNA molecules, and methods for creating their components also apply to the same embodiments for increasing the innate immunogenicity of circular RNA in a subject.

[0086] As discussed in the following examples, RRACH (SEQ ID NOs: 17-18) is m 6 This is a consensus motif for A modification. Therefore, in some embodiments, a circular RNA molecule may be manipulated to lack the RRACH motif (SEQ ID NO: 18) by replacing the "A" in the motif with another base or combination of bases, such as uracil ("U"), guanine ("G"), or cytosine ("C"), however any nucleotide within the RRACH motif may be replaced with another base or combination of bases. Ideally, at least 1% (e.g., 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9% or more) of the adenosine in the circular RNA molecule is replaced with another base (e.g., uracil) or combination of bases. In other embodiments, at least 10% (e.g., 10%, 11%, 12%, 13%, 14%, 15%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or more) of the adenosine in the circular RNA molecule is replaced by another base (e.g., uracil) or a combination of bases. For example, all (i.e., 100%) of the adenosine in the circular RNA molecule is replaced by another base (e.g., uracil) or a combination of bases.

[0087] Methods for reducing or increasing the innate immunogenicity of circular RNA molecules may further include the step of administering modified circular RNA to a subject. Modified circular RNA or compositions comprising modified circular RNA may be administered to a subject (e.g., a mammal) using standard administration methods, including oral, intravenous, intraperitoneal, subcutaneous, intrapulmonary, transdermal, intramuscular, intranasal, oral, sublingual, vaginal, or suppository administration.

[0088] In some embodiments, circular RNA may be delivered to cells in the form of naked RNA. In some embodiments, circular RNA may form a complex with nanoparticles for delivery to cells, such as polyethyleneimine (PEI) nanoparticles.

[0089] The following examples further illustrate the present invention, but should not be considered to limit its scope in any way. [Examples]

[0090] The following materials and methods were used in the experiments described in the examples.

[0091] plasmid Plasmids encoding phage introns that express circRNA via autocatalytic splicing have been described by Chen et al., previously cited. Using IN-FUSION® HD assemblies (Takara Bio Inc., 638910), we constructed plasmids encoding phage introns and incorporating a BoxB motif to express exogenous circGFP. Plasmids expressing YTHDF1N and YTHDF2N with and without λN were generously provided by Dr. Chuan He (University of Chicago). Plasmids expressing a cleaved form of the YTHDF2 protein domain were constructed using IN-FUSION® HD. All plasmids were grown in NEB® Turbo Competent E. coli Cells (New England Biolabs, C2984H) in LB medium and purified using the ZYMOPURE II® Plasmid Prep kit (Zymo Research, D4200).

[0092] RNA synthesis and purification RNA was synthesized by in vitro transcription using the MEGAscript T7 Transcription Kit (Ambion, AM1334) and incubation at 37°C for one night or at least 8 hours, following the manufacturer's instructions. Using the MEGASCRIPT® T7 Transcription Kit (Ambion, AM1334), 6 By in vitro transcription, ATP (Trilink, N-1013) is added in the ratio specified by the ATP in the transcription kit, and in the same manner, m 6A-labeled RNA was synthesized. The transcribed circFOREIGN was purified using an RNEASY® Mini column (Qiagen, 74106), and then treated with RNase R (Epicenter, RNR07250) in the following manner: the secondary structure of circFOREIGN was denatured for 5 minutes at 72°C followed by 2 minutes on ice; RNase R was added in a ratio of 1U:1μg RNA, and incubated at 37°C for 2-3 hours. CircRNALinear RNA was not treated with RNase R. Next, circFOREIGN was purified using an RNEASY® column. Next, circFOREIGN or linear RNA was treated with FASTAP® phosphatase in the following manner: FASTAP® was added in a ratio of 1U:1μg circFOREIGN, incubated at 37°C for 2 hours, and then purified using an RNEASY® column. RNA quality was evaluated by tapestation analysis (Agilent, 5067-5576).

[0093] circFOREIGN was gel-purified using Gel Loading Buffer II (Thermo Fisher Scientific, AM8547) by denaturing RNA for 3 minutes at 72°C followed by 2 minutes on ice, and then loaded onto 1% low-melting-point agarose. Following gel extraction on a blue light transilluminator (Clare Chemical), and thawing at room temperature for 10 minutes, purification was performed using the ZYMOCLEAN® Gel Recovery Kit (ZymoResearch, R1011) according to the manufacturer's instructions, except for melting with rotation for 10 minutes.

[0094] HPLC fractionation was performed using a 4.6 × 300 mm exclusion column (Sepax Technologies, 215980P-4630) with a particle size of 5 μm and a pore size of 2000 Å. Nuclease-free TE buffer was used as the mobile phase at a flow rate of 0.3 ml / min. The RNA fraction was collected manually, lyophilized, and then purified with RNA Clean & Concentrator-5 (Zymo Research, R1013) before subsequent quality control and experimental use.

[0095] m 6 A-irCLIP Using the Poly(A)Purist MAG Kit (Thermo Fisher Scientific, AM1922), mRNA (polyA - ) removes ribosomal RNA (ribo) using the RIBOMINUS® Eukaryote System v2 kit (Thermo Fisher Scientific, A15026). - By removing circRNA, 10 μg of total RNA was enriched with circRNA. Then, RNA Fragmentation Buffer (RNA) was used at 75°C for 12 minutes to obtain the resulting polyA - / ribo - RNA was fragmented into pieces ranging in size from 35 to 100 nt. The fragmented RNA was then denatured and subsequently incubated in IPP buffer (50 mM Tris-HCl, pH 7.4; 100 mM NaCl; 0.05% NP-40; 5 mM EDTA) at 4°C for 2 hours. 6The RNA was incubated with antibody A (Synaptic Systems, 202003). Then, the RNA and antibody were crosslinked using UV light (254 nm) in two rounds at 0.15 J (Stratalinker 2400). The crosslinked RNA and antibody were then incubated with Protein A Dynabeads (Thermo Fisher Scientific, 10002D) at 4°C for 2 hours. Next, the beads were washed once with IPP buffer while rotating at 4°C for 10 minutes, once with low-salt buffer (50 mM Tris, pH 7.4; 50 mM NaCl; 1 mM EDTA; 0.1% NP-40) while rotating at 4°C for 10 minutes, and once with high-salt buffer (50 mM Tris-HCl pH 7.4, 1 M NaCl, 1% NP-40, 0.1% SDS) while rotating at 4°C for 10 minutes. The beads were then transferred to an unused 1.5 mL tube and washed twice with PNK buffer (20 mM Tris-HCl, pH 7.4; 10 mM MgCl2; 0.2% Tween 20). The library was then prepared using the irCLIP method (Zarnegar et al., 2016). The library was inspected for quality using Bioanalyzer and sequenced on NextSeq 500 with custom sequencing primer P6_seq as described in the irCLIP method. Reads were mapped to the hg38 sequence, then to a custom-assembled circGFP sequence, and PCR duplication was removed using the UMI tool (Smith et al., 2017). Reproducible RT stops were identified using the FAST-iCLIP pipeline (Flynn et al., 2015).

[0096] m 6 A-RIP-seq Using the Poly(A)Purist MAG Kit (Thermo Fisher Scientific, AM1922), mRNA (polyA -) removes ribosomal RNA (ribo) using the RIBOMINUS® Eukaryote System v2 kit (Thermo Fisher Scientific, A15026). - By removing ), 10 μg of total RNA was enriched with circRNA. The remaining RNA was then treated with RNase R to remove residual linear RNA. Then, polyA - / ribo - RNase R + RNA was fragmented using RNA Fragmentation Buffer (Thermo Fisher Scientific, AM8740) at 75°C for 12 minutes. 3 μg of antibody was administered. 6Protein A (Synaptic Systems, 202003) was conjugated to Protein A Dynabeads at room temperature for 2 hours. The antibody-conjugated beads were then washed with IPP buffer (50 mM Tris-HCl, pH 7.4; 100 mM NaCl; 0.05% NP-40; 5 mM EDTA) and resuspended in IPP with 1 μL of RIBOLOCK® (Thermo Fisher Scientific, EO0382). The fragmented RNA in the IPP buffer was incubated with the antibody and beads at 4°C for 2 hours, with rotation. Next, the RNA-bound beads were washed once with IPP buffer for 10 minutes at 4°C while rotating, once with low-salt buffer (50 mM Tris, pH 7.4; 50 mM NaCl; 1 mM EDTA; 0.1% NP-40) for 5 minutes at 4°C while rotating, and once with high-salt buffer (50 mM Tris-HCl, pH 7.4, 1 M NaCl, 1% NP-40, 0.1% SDS) for 5 minutes at 4°C while rotating. The beads were then resuspended in 300 μL of high-salt buffer and transferred to an unused 1.5 mL tube. The beads were washed with PNK buffer (20 mM Tris-HCl, pH 7.4; 10 mM MgCl2; 0.2% Tween 20), then resuspended in 500 μL of Trizol and incubated at 25°C for 5 minutes. 150 μL of chloroform:isoamyl alcohol was added and mixed at 25°C for 2 minutes prior to incubation. After spinning at 4°C and 13,000 × g for 10 minutes, the aqueous layer was transferred to a new 1.5 mL tube and purified with RNA Clean & Concentrator-5 (Zymo Research, R1013). The RNA was eluted in 10 μL of nuclease-free water. To the eluted RNA and 10% input RNA, 10 μL of end repair mix (4 μL of 5x concentrated PNK buffer; 1 μL of RIBOLOCK®, 1 μL of FASTAP®; 2 μL of T4 PNK; and 2 μL of nuclease-free water) was added.The reaction was incubated at 37°C for 1 hour. 20 μL of linker ligation mix (2 μL of 10x RNA ligation buffer; 2 μL of 100 mM DTT; 2 μL of L3 linker (Zarnegar et al., 2016); 2 μL of T4 RNA ligase buffer; 12 μL of 50% w / v PEG8000) was added. The reaction mixture was incubated at 25°C for 3 hours and then purified using an RNA Clean & Concentrator-5 column. The processed RNA was eluted in 10 μL of nuclease-free water. Libraries were prepared using the irCLIP method (Zarnegar et al., 2016) and sequenced on a NextSeq 500 using custom sequencing primers (P6_seq (Zarnegar et al., 2016)). Reads were aligned to the hg38 and circGFP sequences. The BAM file was normalized for reads mapped to the genome.

[0097] Reverse transcription and real-time PCR analysis (RT-qPCR) Total RNA was isolated from cells using DIRECT-ZOL® RNA Miniprep (Zymo Research, R2052) with digestion by TRIZOL® (Invitrogen, 15596018) and DNase I on a column, according to the manufacturer's instructions. RT-qPCR analysis was performed in triplicate using Brilliant II SYBR Green qRT-PCR Master Mix (Agilent, 600825) and LightCycler 480 (Roche). The primers used are shown in Table 1. mRNA levels were normalized to actin or GAPDH levels. For circRNA transfection, the relative expression of the indicated mRNA gene was normalized to the level of transfected RNA and plotted as a multiplicative change relative to the expression level of cells that underwent mock transfection or linear RNA transfection.

[0098] [Table 1]

[0099] Cell system and maintenance Human HeLa (cervical adenocarcinoma, ATCC CCL-2) cells and HEK293T (fetal kidney, ATCC CRL-3216) cells were grown in Dulbecco's modified Eagle medium (DMEM, Invitrogen, 11995-073) supplemented with 100 units of penicillin-streptomycin per ml (Gibco, 15140-163) and 10% (v / v) fetal bovine serum (Invitrogen, 12676-011). Cell growth was maintained at 37°C in a 5% CO2 atmosphere.

[0100] Cell culture and transient transfection Cells were seeded 24 hours before transfection. Cells were brought to 70-80% confluence and transfected with RNA using Lipofectamine 3000 (Thermo Fisher Scientific, L3000008). 500 ng of linear RNA or circFOREIGN was transfected into one well of a 24-well plate using Lipofectamine 3000 (Thermo Fisher Scientific, L3000008). Nucleic acids with P3000 and Lipofectamine 3000 were diluted according to the manufacturer's instructions and incubated at room temperature in Opti-MEM (Invitrogen, 31985-088) for 5 minutes. The nucleic acids and Lipofectamine 3000 were then mixed together and incubated at room temperature for 15 minutes, after which the nucleic acid-Lipofectamine 3000 complex was dropped into a monolayer culture. To express ectopic proteins, cells were electroporated using the NEON™ Transfection System (Thermo Fisher Scientific MPK5000S) according to the manufacturer's instructions. In most cases, cells were placed in buffer R at a rate of 2 × 10 cells per 1 mL. 7The cells were resuspended individually, and 5 μg of DNA plasmid was electroporated into them using a 100 μL NEON® tip. After 12 hours, the cells were subcultured, and after 24 hours, they were seeded to 70-80% confluence. After 24 hours, the cells were then transfected with RNA using Lipofectamine as described above. 24 hours after transfection, the cells were washed once with PBS, and 300 μL of TRIZOL® reagent was added to each of the 24 wells. RNA was collected using DIRECT-ZOL® RNA Miniprep.

[0101] Western blot analysis HeLa cells were harvested and lysed 24 hours after transfection to extract total protein. Cells were lysed using RIPA buffer (150 mM NaCl, 1% Triton X-100, 0.5% sodium deoxycholate, 0.1% SDS, 50 mM Tris, pH 8.0). Proteins were fractionated by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), transferred to a nitrocellulose membrane, blocked for 1 hour at room temperature in phosphate-buffered saline containing 5% (wt / vol) nonfat milk, and then incubated overnight at 4°C with the primary antibodies shown in Table 2. Following the manufacturer's instructions, IRDye 800CW goat anti-rabbit IgG (Li-Cor, 926-32211) secondary antibody or IRDye 680CW donkey anti-goat IgG (Li-Cor, 926-68074) secondary antibody were used. Detection and quantification were performed by Western blotting using the Odyssey far-infrared imaging system (Li-Cor).

[0102] [Table 2] JPEG2026094352000003.jpg204150 JPEG2026094352000004.jpg208150 JPEG2026094352000005.jpg204150 JPEG2026094352000006.jpg209150 JPEG2026094352000007.jpg171150

[0103] Rescue using YTHDF2 and tethering YTHDF1 / 2 to CircBoxB As described above, cells were electroporated with plasmids expressing YTHDF1N or YTHDF2N with and without lambdapeptide (λN) (i.e., BoxB-binding protein) via the NEON® transfection system. After 12 hours, the cells were subcultured and seeded after 24 hours to 70-80% confluence. After 24 hours, 500 ng of circBoxB (circRNA with 5BoxB site) was transfected with Lipofectamine 3000. RNA was collected and qRT-PCR was performed using Brilliant II SYBR Green qRT-PCR Master Mix and LightCycler 480 as described above. Additional double denominations were secured for protein lysate recovery, and ectopic protein expression under these conditions was simultaneously confirmed by Western blotting.

[0104] RNA immunoprecipitation-qPCR Cells were electroporated with plasmids expressing Flag-tagged YTHDF1N or YTHDF2N, with and without λN, using the NEON® transfection system, and then subcultured in a 6-well format over the time courses described above. Approximately 3 million cells were harvested with 0.25% trypsin-EDTA (Thermo Fisher Scientific, 25200056) and then washed with PBS. The cells were then lysed in cell lysis buffer (50 mM Tris pH 8.0 with proteinase inhibitor, 100 mM NaCl, 5 mM EDTA, 0.5% NP-40) using a Covaris Ultrasonicator with the following settings: Fill Level: 10, Duty Cycle: 5%, Peak Incident Power: 140 W, Cycles / Burst: 200, time per tube: 300 seconds. Cell lysates were pelletized at 16,000 rcf for 15 minutes. The supernatant was collected and incubated with 100 μL of anti-FLAG® M2 magnetic beads (Sigma-Aldrich, St. Louis, MO) at room temperature for 2 hours with rotation to pull down YTHDF1N or YTHDF2N. The beads were washed three times with cell lysis buffer, once with PBS. The beads were resuspended in 500 μL of TRIZOL®, and total RNA was extracted using the RNEASY® Mini Kit (Qiagen, 74106). qRT-PCR was performed using Brilliant II SYBR Green qRT-PCR Master Mix and LightCycler 480 as described above. RNA levels were normalized as a percentage of the input within each biological repeat. Results are presented as a multiplicative change in circRNA enrichment over actin.

[0105] FACS analysis Cells were seeded in DMEM with antibiotic-free FBS at a rate of 60,000 cells per well in a 24-well format. After 24 hours, cells were transfected with siRNA as recommended by the manufacturer. DHARMAFECT® SMARTpool ON-TARGETplus METTL3 siRNA (Dharmacon, L-005170-02-0005) was used as the knockdown siRNA, and ON-TARGETplus Non-Targeting control siRNA (Dharmacon, D-001810-01-05) was used as the non-targeting siRNA. The culture medium was changed 12 and 36 hours after transfection. 48 hours after transfection, cells were harvested via 0.25% trypsin-EDTA and stained with Annexin V-647 (Thermo Fisher Scientific, A23204) in Annexin binding buffer for 15 minutes. Next, the cells were spun down and resuspended in DAPI in Annexin binding buffer (BD Biosciences, 556454) for 5 minutes. The cells were then resuspended in Annexin binding buffer without dye and passed through round-bottom tubes fitted with cell strainer caps (Corning, 352235). Flow analysis was performed on a custom-made FACS Aria II (BD Biosciences). Cells transfected using the same method as above were harvested, and protein lysates were collected. Knockdown of METTL3 was confirmed by Western blotting using an anti-METTL3 antibody.

[0106] Mouse immunization 8-12 week old female C57BL / 6 mice purchased from Jackson Laboratories were subcutaneously immunized at the base of the tail with 100 μg of OVA (Invivogen, vac-pova) per mouse, either with 25 μg of high molecular weight vaccine-grade PolyI:C (Invivogen, vac-pic) alone, or adjuvanted with 25 μg of circular RNA alone, or with 25 μg of modified RNA, either with in vivo jetPEI (Polyplus Transfection, 201-10G), or with in vivo jetPEI. The PEI / RNA complex was formulated according to the manufacturer's instructions. As shown in the figure, blood was collected from the mice at regular intervals via the lateral caudal vein or facial vein to analyze CD8+ T cell response and antibody response after vaccination. Where indicated, a booster vaccine was administered 5 weeks after the primary vaccination. For tumor establishment and growth studies, 500,000 OVA-expressing B16 melanoma cells, accompanied by Matrigel, were delivered to the left and right flanks of mice 14 days after a single RNA vaccination. Tumors were measured twice weekly, and bioluminescence was measured once weekly. Bioluminescence was measured by intraperitoneal injection of 3 mg of D-luciferin per 20 g mouse, and imaging was performed using an Ami HT Imager (Spectral Instruments) over a period of 20 seconds to 1 minute from exposure. All animal procedures were carried out in accordance with guidelines established by the Animal Welfare / Use Committee at Stanford University facilities.

[0107] CD8+ T cell assay Primary and memory CD8+ T cell responses were assessed 7 days after primary and secondary immunization. Briefly, peripheral blood mononuclear cells (PBMCs) were enriched using sucrose density gradient separation (Histopaque, 1083; Sigma Aldrich 10831) and cultured with 1 μg / mL of OVA-specific MHC class I-restricted peptide (SIINFEKL) (Invivogen, vac-sin) for 5 hours of ex vivo restimulation in the presence of BD Golgi Plug®. Stimulated cells were first stained for surface markers: anti-mouse CD8α (Biolegend, clones 53-6.7), anti-mouse CD3 (Biolegend, clone 17A2), and anti-mouse CD4 (Biolegend, clones RM4-5). These cells were then fixed in BD cytofix / cytoperm and subjected to intracellular staining with anti-mouse IFN-γ (BD Bioscience, clone XMG1.2) in BD cytoperm buffer. Dead cells were removed using live / dead aqua stain (Invitrogen). Labeled cells were collected on a FACS LSR-II cytometer, and the data were analyzed using Flow JO software (TreeStar).

[0108] antibodyELISA A 96-well plate (NuncMaxiSorp, 442404-21) was coated with 100 μl of 20 μg / mL OVA protein (Invivogen) overnight at 4°C. The plate was washed three times with PBS / 0.5% Tween-20 using a Bio-Rad automated plate washer, and then blocked with 200 μl of 4% BSA (Sigma Aldrich) at room temperature for 2 hours. Serum samples from immunized mice at the indicated time were sequentially diluted in PBS / 0.5% Tween-20 with 0.1% BSA and incubated on the blocked plate at room temperature for 2 hours. The wells were washed and incubated with anti-mouse IgG-HRP (1:5000), anti-mouse IgG1-HRP conjugate (1:5000), and anti-mouse IgG2c-HRP conjugate (1:2000) in PBS / 0.5% Tween-20 for 2 hours at room temperature. Detection antibodies were obtained from Southern Biotech. The plates were washed and stained with 100 μl of tetramethylbenzidine (TMB) substrate (Thermo Fisher Scientific, 34028) per well, followed by stopping the reaction with stop solution (Thermo Fisher Scientific, N600). The plates were analyzed using a Bio-Rad plate reading spectrophotometer at 450 nm with a correction at 595 nm. Antibody titer, expressed as the reciprocal of the serum dilution, yielded an optical density (OD) value of >0.3 at 450 nm.

[0109] RIG-I ATPase assay 0.1 μM RIG-I was pre-incubated in buffer B (20 mM HEPES pH 7.5, 150 mM NaCl, 1.5 mM MgCl2) with the specified circular RNA or 5'ppp dsRNA 512 bp (0.4 ng / μl). The reaction was induced at 37°C by adding 2 mM ATP. After 2, 4, or 8 minutes following ATP addition, aliquots (10 μl) were taken and rapidly quenched with 100 mM EDTA. ATP hydrolysis activity was measured using GREEN® reagent (Enzo Life Sciences). GREEN® reagent (90 μl) was added to the quenched reaction in a 9:1 ratio, and OD was measured using a SYNERGY® 2 plate reader (BioTek). 650 We measured it.

[0110] RIG-I Native Gel Shift Assay RNA (1 ng / mL) was incubated with RIG-I (500 nM) in buffer A (20 mM HEPES pH 7.5, 50 mM NaCl, 1.5 mM MgCl2, 2 mM ATP, and 5 mM DTT) at room temperature for 15 minutes. Polyubiquitin was then added at the indicated concentration and incubated at room temperature for 5 minutes. The complex was analyzed on a Bis-Tris Native PAGE gel (Life Technologies) and stained with SYBR® Gold dye (Life Technologies). Fluorescence with SYBR® Gold was recorded using a FLA9000 scanner (Fujifilm Corporation) and analyzed using Multigauge (GE Healthcare).

[0111] RIG-I polymerization assay 0.4 μM RIG-I was incubated with specified circular RNA (1 ng / μl) in buffer A (20 mM HEPES pH 7.5, 50 mM NaCl, 1.5 mM MgCl2, 2 mM ATP, and 5 mM DTT) at room temperature for 15 minutes. The prepared samples were adsorbed onto a carbon-coated grid (Ted Pella) and stained with 0.75% uranyl formate. Images were retrieved using a TECNAI® G2 Spirit BioTWIN transmission electron microscope at 30,000x or 49,000x magnification.

[0112] Protein preparation Human RIG-I was expressed as previously reported (Peisley et al., 2013). Briefly, after induction with 0.5 mM IPTG, the protein was expressed in BL21 (DE3) at 20°C for 16–20 hours. Cells were homogenized using Emulsiflex C3 (Avestin), and the protein was purified using a three-step protocol including Ni-NTA affinity chromatography, heparin affinity chromatography, and size exclusion chromatography (SEC) in 20 mM HEPES, pH 7.5, 150 mM NaCl, and 2 mM DTT.

[0113] K63-Ubn was synthesized as previously reported (Dong et al., 2011). Briefly, mouse E1, human Ubc13, Uev1a, and ubiquitin were purified from BL21(DE3) cells and mixed in a reaction mixture containing 0.4 mM ubiquitin, 4 μM mE1, 20 μM Ubc13, and 20 μM Uev1a in a buffer (10 mM ATP, 50 mM Tris pH 7.5, 10 mM MgCl2, 0.6 mM DTT). After incubation of the reaction mixture at 37°C overnight, the synthesized K63-Ubn chains were diluted five-fold in 50 mM ammonium acetate pH 4.5 and 0.1 M NaCl, and separated over a gradient of 45 mL of 0.1–0.6 M NaCl in 50 mM ammonium acetate pH 4.5 using a Hi-Trap SP FF column (GE Healthcare). The high molecular weight fraction was applied to an S200 10 / 300 column equilibrated in 20 mM HEPES pH 7.5 and 0.15 M NaCl.

[0114] MAVS CARD was expressed as a fusion construct with a SNAP tag (CARD-S) in BL21(DE3) cells for 16–20 hours at 20°C after induction with 0.4 mM IPTG. The SNAP tag enables fluorescent labeling of MAVS CARD. The MAVS CARD-S fusion was purified using the Ni-NTA affinity chromatography described (Wu et al., 2016), except that 0.05% NP-40 was used instead of CHAPS. The purified CARD-S was denatured in 6 M guanidia chloride with constant shaking at 37°C for 30 minutes, followed by dialyzing in refolding buffer (20 mM Tris, pH 7.5, 500 mM NaCl, 0.5 mM EDTA, and 20 mM BME) for 1 hour at 4°C. The refolded CARD-S was passed through a 0.1 μm filter and then fluorescently labeled with Alexa647-benzylguanine (NEB) on ice for 15 minutes, according to the manufacturer's instructions. The labeled MAVS CARD-S was immediately used in the polymerization assay (described below).

[0115] MAVS polymerization assay The MAVS filament formation assay was performed as previously reported (Wu et al., 2013). MAVS CARDs fused to SNAP(CARD-S) were labeled with BG-Alexa 647 (New England Biolabs) on ice for 15 minutes. RIG-I (1 μM) was pre-incubated at room temperature for 15 minutes with varying concentrations of RNA and 2 mM ATP, either in or without 6 μM K63-Ubn (in 20 mM HEPES pH 7.5, 150 mM NaCl, 1.5 mM MgCl2, and 2 mM DTT). Subsequently, labeled monomer MAVS CARD-S (10 μM) was added to the mixture and further incubated at room temperature for 1 hour. MAVS filament formation was detected by Native PAGE analysis or by the negative dye EM. All samples underwent one round of freeze-thaw cycles, consisting of incubation on dry ice for 5 minutes followed by incubation at room temperature for 5 minutes, before electrophoresis on Bis-Tris gel (Life Technologies Corp.). Fluorescent gel images were scanned using an FLA9000 scanner (Fujifilm Corporation). As previously described (Ohi et al., 2004), samples from the MAVS polymerization assay were adsorbed onto a carbon-coated grid (Ted Pella) and stained with 0.75% uranyl formate. Images were retrieved using a TECNAI® G2 Spirit BioTWIN transmission electron microscope at 9,300x magnification.

[0116] Immunofluorescence and Quantitative Analysis FITC-labeled RNA was synthesized as described above, except that 100% of the UTP was replaced with 5% fluorescein 12 UTP (Thermo Fisher Scientific, 11427857910) during the in vitro transcription reaction mix. FITC-labeled 10% m 6A RNA is 10% m during the in vitro transcription reaction mix. 6 RNA was synthesized by further substitution of 100% ATP with A. RNase R treatment and FASTAP® treatment were performed as described. RNA quality was evaluated by Tapestation.

[0117] HeLa cells were seeded on 22×22 mm coverslips with a thickness of #1.5 in a 6-well format. After 12 hours, transient transfection with FITC-labeled circRNA was performed using Lipofectamine 3000 (Thermo Fisher Scientific, L3000015). After 12 hours, the cells were fixed in PBS (Thermo Fisher Scientific, 28908) with 1% formaldehyde for 10 minutes at room temperature. The formaldehyde-fixed slides were rinsed in PBS and permeabilized in 0.5% Triton X-100 in PBS for 10 minutes at room temperature. After permeabilization, the solution was rinsed and the slides were blocked with antibody diluent (Thermo Fisher Scientific, 003118) for 1 hour at room temperature. Anti-RIG-I rabbit polyclonal primary antibody (Cell Signaling Technology, 3743S) and anti-Ub-K63 mouse monoclonal antibody (eBioscience, 14-6077-82) were diluted 1:200 in antibody diluent and incubated overnight at 4°C. After washing with PBS, the slides were incubated with goat anti-rabbit IgG highly cross-adsorbed Alexa594 (Thermo Fisher Scientific, A-11037) and goat anti-mouse IgG highly cross-adsorbed Alexa647 (Thermo Fisher Scientific, A-21236), diluted 1:1000 in antibody diluent, at room temperature for 2 hours. The slides were washed with PBS, mounted using VECTASHIELD® with DAPI (Vector Labs, H-1200), and imaged using a Zeiss LSM 880 confocal microscope (Stanford Microscopy Facility). Forsy's localization of co-RIG-I and K63-polyUb was counted when they directly overlapped with FITC-circRNA and / or each other.

[0118] Anti-RIG-I rabbit polyclonal primary antibody (Cell Signaling Technology, 3743S) and anti-YTHDF2 mouse polyclonal antibody (USBiological, 135486) were each diluted 1:200 in antibody diluent. The remaining immunofluorescence steps, including secondary staining, mounting, and imaging, were performed as detailed above. Forsyth's localization of co-RIG-I and YTHDF2 was counted where they directly overlapped with FITC-circRNA and / or each other.

[0119] IRF3 dimerization assay The dimerization assay was performed as previously described (Ahmad et al., Cell, 172:797-810, e713 (2018)). Briefly, HEK293T cells were homogenized in hypotonic buffer (10 mM Tris pH 7.5, 10 mM KCl, 0.5 mM EGTA, 1.5 mM MgCl2, 1 mM sodium orthovanadate, 1x Mammalian Protease Arrest (GBiosciences)), and the cells were centrifuged at 1000 g for 5 minutes to pellet the nuclei. The supernatant (S1) containing the cytosolic and mitochondrial fractions was used for the in vitro IRF3 dimerization assay. A stimulation mix containing 10 ng / μl RIG-I and 2.5 ng / μl K63-Ubn, along with the indicated amount of RNA, was pre-incubated for 30 minutes at 4°C in 20 mM HEPES pH 7.4, 4 mM MgCl2, and 2 mM ATP. 35S-IRF3 was prepared by in vitro translation using the T7 TNT® Coupled Reticulocyte Lysate System (Promega) according to the manufacturer's instructions. The IRF3 activation reaction was induced by adding 1.5 μl of the pre-incubated stimulation mix to 15 μl of a reaction mixture containing 10 μg / μl S1 and 0.5 μl of 35S-IRF3 (in 20 mM HEPES pH 7.4, 4 mM MgCl2, and 2 mM ATP), and the mixture was incubated at 30°C for 1 hour. Subsequently, the sample was centrifuged at 18,000 g for 5 minutes, and the supernatant was subjected to Native PAGE analysis. IRF3 dimerization was visualized by autoradiography and phosphorescence imaging (Fujifilm Corporation, FLA9000).

[0120] Activation of dendritic cells Mice were subcutaneously immunized at the base of their tails with PBS (control) or circular RNA (25 μg per mouse). 24 hours after immunization, the mice were euthanized, and the inguinal lymph nodes in the cutaneous inflow area were excised. The inguinal lymph nodes in the cutaneous inflow area were gently crushed using the thumb rest of a 3 mL syringe plunger and digested with 1 mg / mL type IV collagenase at 37°C for 20–25 minutes.

[0121] The reaction was stopped with 2 mM EDTA, and the single-cell suspension was prepared by passing it through a 40 μm cell strainer.

[0122] statistical analysis All statistical analyses were performed using GraphPad Prism software (GraphPad Software, LaJolla, CA). Where appropriate, Student's t-test, Kruskal-Wallis test, or Anova-Tukey test were used. A p-value less than 0.05 was considered statistically significant.

[0123] [Example 1] This example supports the in vitro synthesis and characterization of immunogenic circRNAs.

[0124] In this specification, a cyclic green fluorescent protein (GFP) mRNA derived from the T4 bacteriophage, containing reordered td introns, referred to as "circFOREIGN," is highly immunogenic in cultured mammalian cells (Chen et al., previously cited). The TD introns program autocatalytic splicing during in vitro transcription to form circFOREIGN. Prolonged (>2 hours) treatment of circFOREIGN with the exonuclease RNase R degrades linear RNA byproducts, resulting in circRNA enrichment (Chen et al., previously cited). Subsequent alkaline phosphatase treatment removes the 5' phosphate from the free end. Delivery of exogenous circRNA to mammalian cells strongly stimulates the expression of immunogenes and provides protection against subsequent viral infection (Chen et al., previously cited). Recent reports suggest that exogenous circRNAs do not induce an immune response, but rather that 5' triphosphorylated linear RNA contaminants, resulting from incomplete digestion of RNase R, trigger the immune response (Wesselhoeft et al., Mol Cell., 74(3):508~520 (2019)). Wesselhoeft et al. used a short (30-minute) RNase R treatment followed by HPLC to remove linear RNA from circRNA. Immunostimulation with circFOREIGN, which was synthesized in vitro and treated with RNase R for 2 hours, was equivalent to circFOREIGN treated with a second round of phosphatase to remove the triphosphate on the contaminating linear RNA, whereas linear RNA treated with phosphatase significantly reduced immune activation (Chen et al., previously cited). Therefore, stimulation with circFOREIGN is independent of the presence of abnormal 5' triphosphate in the sample. However, to confirm that 5' triphosphate does not stimulate immunogene expression, all circFOREIGN molecules described herein were synthesized in the presence of phosphatase.

[0125] We investigated whether gel purification of circFOREIGN treated with RNase R alters the immunostimulation induced by circFOREIGN. We hypothesized that if contaminating linear RNA components contribute to the immunogenicity of circFOREIGN, gel extraction would eliminate these contaminants with different molecular weights. Since the circRNA product in the gel is linear, it is not immunostimulant. For this purpose, gel-purified circFOREIGN treated with both RNase R and alkaline phosphatase was compared to the same circFOREIGN preparation after gel purification. Following transfection of HeLa cells with each RNA preparation, qRT-PCR analysis of innate immune genes was performed 24 hours later. Gel-purified circFOREIGN stimulated innate immune genes with nearly the same potency (approximately 80-90% activity) compared to circRNA treated with RNase R alone (Figures 1A and 1B).

[0126] Synthetic circRNA treated with RNase R was also subjected to fractionation by HPLC. Size exclusion chromatography degraded the RNase R-treated circRNA into two fractions (Figure 1C). Enrichment and TapeStation analysis of each fraction showed that peak 1 from HPLC accurately reproduced the results from gel electrophoresis on RNase R-treated circFOREIGN (Figure 1C), while peak 2 reflected the presence of degraded RNA. The resulting chromatograms and fractions obtained by HPLC purification differed from previously reported separations (Wesselhoeft et al., cited above) due to differences in the measuring instruments. qRT-PCR following transfection of each fraction into HeLa cells revealed that the fraction containing circRNA retained an immune response, but with low activity (Figure 1D). Peak 2 contained small degraded RNA and undigested introns, but this fraction was not immunogenic. These results are consistent with the interpretation that phosphatase treatment throughout the sample preparation process inactivated immunogenic linear RNA. Therefore, the slight decrease in irritation in gel-purified circFOREIGN (Figure 1B) was not due to the loss of these RNA molecular species. The integrity of circFOREIGN was better preserved in gel purification than in HPLC purification, with less degradation to small RNA fragments in the former, which correlated with the good preservation of circFOREIGN's immunogenicity.

[0127] Small linear RNAs resulting from incomplete digestion of RNase R did not contribute to the immunogenicity of the circRNA in the preparations described above. The enzymatic purification process described above was considered to best preserve the integrity of circFOREIGN.

[0128] [Example 2] This embodiment confirms that circFOREIGN acts as a vaccine adjuvant in vivo.

[0129] circFOREIGN has already been shown to strongly stimulate immunogene expression in vitro (Chen et al., previously cited), but its behavior in vivo is unknown. Because circFOREIGN has the potential to activate innate immunity, it was hypothesized to act as a vaccine adjuvant to enhance vaccine efficacy. circFOREIGN was transcribed and purified in vitro, combined with chicken ovalbumin (OVA), and delivered to C57BL / 6J mice by subcutaneous injection. PolyI:C was used as a positive control for RNA adjuvants. circFOREIGN was delivered either as naked RNA or after packaging in polyethyleneimine (PEI), a transfection agent. T cells were collected, and intracellular cytokine staining (ICS) was performed 7 days after primary or secondary vaccination. Serum was also collected, and antibody responses were measured 5 weeks after vaccination (Figure 2A). The measured antibodies are shown in Table 3.

[0130] [Table 3]

[0131] As expected, induction of OVA-specific, interferon-gamma-positive (Ifnγ+) activated CD8 T cells required an adjuvant such as polyI:C (Figures 2B and 3A-3C). In particular, co-injection of circFOREIGN with naked circRNA (p=0.0088 compared to mock, Anova-Tukey test) or PEI nanoparticles (p=0.0039 compared to mock, Anova-Tukey test, Figure 2B) induced potent anti-OVA T cells at levels comparable to those induced by polyI:C. Measurement of OVA-specific antibodies revealed that circFOREIGN alone stimulated antibody production to levels comparable to those of the positive control polyI:C (Figures 2C and 3B). circFOREIGN did not require transfection reagents for the stimulation of OVA-specific CD8+ T cells or OVA-specific antibodies. In fact, the CD8+ T cell response was more pronounced with injections without PEI, and PEI was omitted in subsequent experiments.

[0132] Following immunization of mice with circFOREIGN or a control, dendritic cells (DCs) were isolated from lymph nodes in the lymph aspiration region. The circFOREIGN adjuvant activated both the cDC1 and cDC2 subsets, as determined by a greater-than-control increase in the cell surface expression of the costimulatory molecule CD86 (Figures 3D and 3E).

[0133] These results provide direct in vivo evidence that circRNA inoculation activated dendritic cells (DCs). DC activation can, in principle, facilitate the cross-presentation of antigens by CD4+ follicular helper (fh) T cells and CD8+ T cells, as well as their activation. However, circRNA can also directly affect T cells and other immune cell types.

[0134] [Example 3] This example confirms that circFOREIGN can induce antitumor immunity.

[0135] Since circFOREIGN delivery induces a CD8+ T cell response, we hypothesized that mice exposed to circFOREIGN and OVA would have acquired immunity against OVA-expressing tumors. Therefore, mice were vaccinated with circFOREIGN and OVA, and two weeks later, OVA-expressing B16 melanoma cells were implanted into the left and right flanks of the mice (Figure 2D). The OVA-B16 melanoma model was immunorestricted primarily via CD8+ effector T cells (Budhu et al., J Exp Med., 207(1):223~35 (2010)). Mice treated with circFOREIGN showed lower tumor growth compared to negative control mice treated with PBS (Figures 2E, 2F, and 3F). The correlation between the left and right tumors in each mouse supports the idea that vaccination had a systemic effect. Mice vaccinated with circFOREIGN once showed nearly twice the overall survival time compared to negative control mice (p=0.0173, log-rank test, Figure 2G), and were comparable to mice treated with the positive control high molecular weight polyI:C (Figure 3G).

[0136] The results of this example suggest that circRNA-mediated immunity can be utilized for potential therapeutic purposes.

[0137] [Example 4] In this example, endogenous circRNA is m 6 This confirms that they will meet with Organization A.

[0138] Given that mammalian cells possess endogenous circRNA, their immune response to circFOREIGN suggests that they can distinguish between self-circRNA and non-self-circRNA. As discussed above, circRNA is produced via backsplicing, which covalently connects the 3' and 5' ends of RNA exons. While intron recognition determines circRNA-mediated immunity (Chen et al., previously cited), introns are not part of the final circRNA product; therefore, we hypothesized that introns can direct the conferral of one or more covalent chemical markings to circRNA.

[0139] circZKSCAN1 is a human circRNA produced by its endogenous intron and is not immunogenic when expressed in human cells. Using the ZKSCAN1 intron, we programmed the production of circGFP, referred to as "circSELF". HeLa cells were transfected with DNA plasmids encoding circRNA, produced by protein-assisted splicing (circSELF) or autocatalytic splicing (circFOREIGN), and comprehensive identification of RNA-binding proteins was performed by mass spectrometry (ChIRP-MS) (Chen et al., previously cited). Covalent m 6 The writers, readers, and erasers of A-modification (Roundtree et al., previously mentioned) were analyzed in association with circRNA (Figure 4A). circZKSCAN1 is associated with WTAP and VIRMA (also known as the Virilizer homolog or KIAA1429), etc. 6 Components of the A-writer complex and m 6 It was found that circFOREIGN associates with the A leader proteins YTHDF2, HNRNPC, and HNRNPA2B1, but does not associate with them (Figure 4A). All circRNAs are putative m(FTO) and ALKBH5. 6 It did not associate with A demethylase ("eraser"). Importantly, circSELF contains the same circRNA sequence as circFOREIGN, but is no longer immunogenic (Chen et al., previously cited), m6 A writer protein and m 6 A leader protein is to associate (Figure 4A). Two different circRNAs (circSELF and circZKSCAN1) programmed by human introns are m 6 A writer protein and m 6 A leader protein and achieve equivalent levels of association (Figure 4B).

[0140] The results of this example show that m 6 A modification mechanism is transmitted to exon circRNAs as the memory of introns that mediate their biosynthesis, occurring independently of the circRNA sequence.

[0141] [Example 5] This example shows that self and foreign circRNAs have different m 6 A modification patterns, and m 6 A modification marks circRNAs as "self".

[0142] The m 6 A modification patterns of human and foreign circRNAs were defined. In human cells programmed to express appropriate circRNAs, RNase R treatment was used to enrich for circRNAs, and then m 6 A-UV-C crosslinking and m 6 A immunoprecipitation (m 6 A-irCLIP) was performed (Zarnegar et al., Nat. Meth., 13:489 - 492 (2016)) to map with high sensitivity to the m 6 A modification sites (Figure 4C). m 6 A-irCLIP for circSELF compared to circFOREIGN shows that circSELF has m 6It was revealed that A modification was acquired (Figure 4D). No significant difference in modification was observed throughout the rest of the transcript (Figure 5A). Since circSELF and circFOREIGN are the same exon sequence, circularized by human (self) introns or phage (foreign) introns, this result suggests that human introns acquire m 6 This indicated that the A modification was sufficient to position it on the resulting circRNA. Furthermore, m 6 Comparison of endogenous circRNAs subjected to A-irCLIP with the model human programmed circRNAs showed that both were similar m 6 This indicates that it has the A modification pattern (Figure 4E). 6 A is enriched transcriptome-wide on endogenous circRNA within the +40-100 nt band on the 3' side of the back splice junction (Figure 4E). 6 A is known to be enriched in the last exon of linear mRNA and non-coding RNA (lncRNA) (Figure 5B) (Dominissini et al., Nature, 485:201~206 (2012); Ke et al., Genes & Development, 29:2037~2053 (2015); Meyer et al., Cell, 149:1635~1646 (2012)). m at the 3' side of the back splice junction 6 The discovery of A modification is consistent with this pattern. Splicing occurs during transcription from the 5' end to the 3' end, and backsplicing from the 3' end to the 5' end is the last expected splicing event on circRNA (i.e., there are no introns left uncut by splicing).

[0143] Next, the chemical modification itself or the RNA-binding protein m 6 We hypothesized that chemical modification combined with the recognition of A would enable the marking of "self" circRNA. 6This was investigated by examining whether the incorporation of A into circFOREIGN blocks the recognition of "non-self" and reduces the immunogenicity of circFOREIGN. For this purpose, unmodified circFOREIGN or m 6 A-modified circFOREIGN was synthesized by in vitro transcription (Chen et al., previously cited), and circRNA was purified by RNase R treatment. 6 The incorporation of A-modification into circRNA did not affect the splicing that forms circRNA, and RNase R treatment enriched circRNA (Figures 5C and 5D). Next, recipient cells were transfected with circFOREIGN, and the expression of antiviral genes was measured. 6 While A modifications were concentrated at specific locations along the transcript, m during in vitro transcription 6 The incorporation of A was random. Thus, all adenosine was m 6 Replaced by A (100% m 6 A), or m 6 Only 1% of A is incorporated into circRNA, and on average, each circRNA contains 3 m 6 A modification was achieved. 100% m 6 A is likely to be hyperphysiological, but is not observed in vivo. 6 Model the continuous occurrence of A. 1% m 6 A is m on endogenous RNA 6 It models the total level of the A ratio but does not model the modification pattern. circFOREIGN potently induced a panel of antiviral genes, including RIG-I, MDA5, OAS, OASL, and PKR, but all of adenosine was m 6 When replaced by A modification, the induction of the antiviral gene was completely eliminated (Figure 6A, 100% m 6 A) 1% m 6 Incorporation of A significantly reduced the induction of antiviral genes, but did not eliminate them (Figure 6A). Thus, m 6A modification was sufficient to reduce the immunogenicity of exogenous circRNAs in cultured cells.

[0144] Next, by mutating all cases (n=12) of the sequences RRACH (sequence number 17) and RRUCH (sequence number 19) within the GFP exon, m 6 The circFOREIGN plasmid was modified to eliminate the A consensus motif (Dominissini et al., previously mentioned). It was hypothesized that when circFOREIGN is transcribed in the nucleus of human cells, METTL3 / 14 can modify circFOREIGN at low levels, and that this modification is eliminated in ΔRRACH mutants. HeLa cells were transfected with plasmids encoding wild-type or mutant circRNA, and circRNA levels and induction of innate immune genes were quantified by qRT-PCR. Gene induction was then normalized to the measured circRNA levels.

[0145] Mutations in the RRACH region significantly increased the induction of antiviral genes by circRNA by approximately twofold (Figure 6B). 6 Although A is enriched on the RRACH motif (SEQ ID NO: 18), it is not exclusively present on the RRACH motif. Therefore, a modified circFOREIGN plasmid was constructed in which all adenosines in the GFP exon were mutated to uracil (circFOREIGN lacking A, Figure 6C). Transfection with the plasmid encoding circRNA lacking A resulted in an approximately 100-fold increase in antiviral gene induction, surpassing that of circFOREIGN.

[0146] The results of this example present the first evidence that specific circRNA exon sequences influence immunity, and endogenous m 6 This specifically suggests that A modification weakens innate immunity.

[0147] [Example 6] This example shows the m of circRNA 6A modification dulls the vaccine response in vivo, m 6 This supports the idea that the A-leader protein YTHDF2 is necessary for blocking circRNA-mediated immunity.

[0148] m of circRNA 6 A modification also reduced the immunogenicity of circRNA as an adjuvant in vivo. 1% m 6 When A-modified circFOREIGN was used in the same adjuvant regime as unmodified circFOREIGN, 1% m 6 A modification was found to substantially reduce both the activated CD8 T cell response (Figure 6D compared to Figure 2B) and antibody titer (Figure 6E compared to Figure 2C). 1% m 6 Repeated immunization with A-modified circFOREIGN induced an attenuated but not entirely absent immune response (Figure 7). These results suggest that circFOREIGN is a potent immunostimulant in vivo, and that at 1% m 6 This demonstrates that A modification is sufficient to blunt circRNA-mediated immunity.

[0149] Next, immunity by circRNA, m 6 The mechanism of suppression by A was investigated. 6 A is recognized by a family of leader proteins, the most prominent of which are RNA-binding proteins containing a YTH domain (Dominissini et al., cited above, and Edupuganti et al., Nature Structural & Molecular Biology, 24:870 (2017)). YTHDF2 was detected (i) in association with endogenous circRNA or circSELF, the major m 6(i) It is a leader (Figures 4A and 4B), and (ii) it is a cytoplasmic protein, similar to endogenous circRNA and transfected circRNA (Chen et al., cited above; Rybak-Wolf et al., Molecular Cell, 58:870~885 (2015); Salzman et al., PLoS One, 7:e30733 (2012)), so we focused on this. YTHDF2 - / - Transfection of HeLa cells with circFOREIGN (Figure 8A) resulted in potent induction of antiviral genes (Figure 9A). Furthermore, 1% m 6 A or 10%m 6 The integration of A into circFOREIGN is also YTHDF2 - / - Independent YTHDF2 no longer suppressed the induction of antiviral genes within the cell (Figure 9A). - / - Clones also yielded very similar results (Figure 8B). Furthermore, YTHDF2 - / - Ectopic expression of YTHDF2 within cells is m 6 The fact that YTHDF2 rescued the suppression of immunogene induction in response to A-modified circFOREIGN (Figure 9B) suggests that m 6 This indicates the requirement for mediating the "self" recognition of circRNAs marked with A.

[0150] Next, we investigated which domain of YTHDF2 is necessary to suppress immune stimulation by circFOREIGN. Full-length YTHDF2 (Figure 9C) was artificially tethered to unmodified circFOREIGN, and m 6 The proximity of the A leader protein is necessary for suppressing immunity by circRNA. 6We determined whether the need for A modification could be avoided. Five consecutive BoxB RNA elements were introduced immediately after the splice junction of circFOREIGN, and this was named "circBoxB". In addition, the C-terminal lambda N peptide tag was cloned into a protein, and its expression was confirmed via Western blotting (Figures 8C and 8D). This enabled the recruitment of the YTH protein fused to the λN peptide, as confirmed by RIP-qPCR (Figures 9C and 8E). Transfection of the plasmid encoding the RNA molecule circBoxB strongly stimulated the antiviral gene on its own, while tethering with full-length YTHDF2 significantly attenuated the induction of the antiviral gene (Figure 9D).

[0151] To determine whether the N-terminal domain of YTHDF2 (YTHDF2N) is sufficient for immune evasion of circFOREIGN, the N-terminus of YTHDF2 was tethered to an unmodified circFOREIGN-BoxB. The N-terminus was not sufficient to suppress the immune response to circFOREIGN (Figure 9E). The N-terminal domain contributes to the intracellular localization of the YTHDF2-RNA complex, while the C-terminal domain is m 6 Since it selectively binds to A-modified RNA (Wang et al., Nature, 505:117~120 (2014)), the C-terminal domain is likely required to attenuate the induction of antiviral genes by circFOREIGN.

[0152] Next, we investigated whether the YTH domain could mark circFOREIGN as self by tethering YTH to unmodified circRNA (Figure 8F). Whether circFOREIGN was tethered to the YTH domain or not, no significant changes were observed in RIG-I gene expression. However, the tethering of circFOREIGN to YTH significantly increased the expression of MDA5 and OAS1. Since the full-length YTHDF2 protein is larger than each of its individual domains, we examined the effect of circFOREIGN tethering to red fluorescent protein (RFP) on cell recognition by unmodified circRNA (Figure 8G). A slight decrease in RIG-I gene expression stimulation was observed, but none of the other test immunosensors showed any changes in expression. This suggests that complete suppression of circFOREIGN's immunogenicity requires the entire YTHDF2 domain, and that interaction with other proteins and circRNA is insufficient.

[0153] To investigate whether other members of the YTH family are also involved in circFOREIGN immunosuppression, we used the BoxB motif to study another cytoplasmic m 6 We investigated the effect of the A leader protein YTHDF1 on tethering to circFOREIGN. The N-terminus of YTHDF1, like YTHDF2, did not attenuate the induction of antiviral genes (Figure 8H). In summary, these results suggest that full-length m is necessary to block circRNA-mediated immunity. 6 A leader protein is required, and circRNAs need to distinguish between "self" circRNAs and "foreign" circRNAs. 6 Chemical modification by A or m 6 This supports the requirement of the A leader protein.

[0154] [Example 7] This example is m 6 This supports the idea that METTL3, an A-writer protein, is required for self / non-self recognition of circRNAs.

[0155] In the transmission of "self" markings on circRNA, 6 In order to examine the necessity of A, m 6 We investigated the role of METTL3, a catalytic subunit of the reiter complex, in introducing A modification. Mettl3 plays a role in the timely turnover of RNA. 6 Due to its crucial role, METTL3 is essential for embryonic development (Batista et al., Cell Stem Cell, 15:707-719 (2014)). METTL3 depletion in many human cancer cell lines leads to cell death. One possible consequence of METTL3 depletion is the malignancy of endogenous circRNAs. 6 A deficiency in A modification leads to immune activation. RIG-I is an RNA-binding protein that senses viral RNA and is a signaling protein for the activation of immunogenes (Wu and Hur, Current Opinion in Virology, 12:91-98 (2015)). Exogenous circRNAs have been shown to co-localize with RIG-I in human cells, and RIG-I is necessary and sufficient for circRNA-mediated immunity (Chen et al., previously cited). Therefore, m 6 If A is required to prevent cells from recognizing their own circRNAs as foreign and triggering an immune response, then the simultaneous inactivation of RIG-I should improve the response. Indeed, METTL3 depletion in wild-type HeLa cells resulted in widespread cell death, but RIG-I inactivation in HeLa cells (Chen et al., previously cited) rescued the cells from death (Figure 10).

[0156] The results of this example are, 6 While A suggests that it inhibits RIG-I activation by its own RNA, indirect effects of METTL3 due to other RNA targets cannot be ruled out.

[0157] [Example 8] In this embodiment, the recognition of circFOREIGN by RIG-I differs significantly from that of linear RNA, and circFOREIGN directly binds to RIG-I and K63-linked polyubiquitin chains, m 6 This supports the distinction of A.

[0158] To investigate the mechanism by which circRNA stimulates the innate immune response, biochemical reconstitution using purified components was employed. First, the ability of circFOREIGN to induce ATP hydrolysis by RIG-I was evaluated. When RIG-I recognizes a 5'ppp dsRNA agonist, the protein's helicase domain hydrolyzes ATP (Hornung et al., Science, 314:994~997 (2006); Schlee et al., Immunity, 31:25~34 (2009)). Exposure of RIG-I to circFOREIGN or 5' hydroxyl linear RNA did not stimulate its ATPase activity, whereas 512 base pairs of 5' triphosphate dsRNA induced ATP hydrolysis by RIG-I (Figure 11A). Next, the ability of circFOREIGN to activate purified RIG-I by directly forming filaments on circFOREIGN was investigated. Electron microscopy imaging of RIG-I, circFOREIGN, and ATP did not reveal clear filament formation, whereas the positive control 5'ppp dsRNA induced polymerization of RIG-I (Figure 11B). Therefore, as predicted, circFOREIGN does not interact with or activate RIG-I in the same way as the 5'ppp RNA ligand.

[0159] An alternative mechanism of RIG-I activation involves a lysine 63 (K63)-bound polyubiquitin chain (K63-Ubn) that interacts with and stabilizes the RIG-I 2CARD domain oligomer (Jiang et al., Immunity, 36:959~973 (2012); Peisley et al., Nature, 509:110 (2014); Zeng et al., Cell, 141:315~330 (2010)). Unmodified circFOREIGN and m 6The ability of RIG-I to bind to A-modified circFOREIGN and its interaction with K63-linked polyubiquitin chains were evaluated. Native gel shift binding assays, performed with purified RIG-I and circFOREIGN, revealed that RIG-I bound to the positive control, a 162 bp 5' ppp dsRNA, both in the absence (Figure 11C, lane 2) and in the presence (Figure 11C, lanes 3-4) of K63-linked polyubiquitin. RIG-I also bound to unmodified circFOREIGN and m 6 RIG-I bound to all A-modified circFOREIGN molecules (Figure 11C, lanes 5-16). While K63-linked polyubiquitin chains are not considered necessary for RIG-I's binding to circFOREIGN, increased binding of RIG-I to circFOREIGN was observed at high concentrations of K63-linked polyubiquitin chains (Figure 11C, lane 7 compared to lane 8, lane 11 compared to lane 12, lane 15 compared to lane 16). These results suggest that RIG-I, at the level of conformational change rather than binding level, binds to unmodified circRNA and m 6 This suggests a distinction from A-modified circRNA. These results also support the fact that RIG-I's binding to circRNA differs from that of 5'ppp dsRNA ligands.

[0160] PRRs such as RIG-I and MDA5 examine many RNAs, but selectively undergo conformational changes for oligomerization upon interaction with immunogenic RNA ligands (Ahmad et al., Cell, 172(4):797~810.e13(2018)). Similarly, RIG-I's selectivity for the 5' triphosphate (present on viral RNA) over the m7Gppp cap (present on all mRNA) is due to conformational changes rather than ligand binding (Devarkar et al., Proc Natl Acad Sci USA, 113(3):596~601(2016)). Therefore, m 6We assessed RIG-I's ability to distinguish A-modified circRNAs at the binding level, in contrast to their conformational changes.

[0161] When RIG-I is activated, oligomerized RIG-I serves as a template for the polymerization of MAVS (Mitochondrial Anti-Viral Signaling protein; also known as IPS-1, Cardif, and VISA) into filaments, creating a platform for subsequent signal transduction leading to the activation and dimerization of the IRF3 transcription factor. Purified circFOREIGN, purified RIG-I, purified K63-linked polyubiquitin, and purified MAVS were reconstituted in vitro, and the transition of MAVS from monomer to filament was monitored by gel shift (Figure 12A) or electron microscopy (Figure 12B). Unmodified circFOREIGN strongly stimulated MAVS polymerization in a concentration-dependent manner in the presence of K63-linked polyubiquitin (Figure 12B). Importantly, m 6 When the A modification was incorporated into circFOREIGN at 1% or 100%, MAVS filament formation was substantially reduced or completely eliminated, respectively (Figures 12B and 12C). The fact that none of the circRNA substrates induced MAVS polymerization in the absence of K63-bound polyubiquitin indicates that polyubiquitin is required to stabilize the activated RIG-I conformation for subsequent MAVS polymerization and signaling to occur (Figure 11D). Electron microscopy quantification of MAVS filaments showed that unmodified circFOREIGN strongly induced MAVS filament formation, whereas circFOREIGN's m 6 We confirmed that the A modification suppresses the ability of MAVS to oligomerize (Figures 12B and 12C).

[0162] These in vitro results using purified components support the idea that unmodified circFOREIGN directly activates RIG-I in the presence of K63-linked polyubiquitin and activates MAVS in the absence of any other enzyme or RNA-binding protein. Binding to RIG-I is due to unmodified circRNA and m 6 The A-modified circRNA could not be distinguished (Figure 11C), and only unmodified circFOREIGN induced MAVS filament formation in the presence of K63-bound polyubiquitin (Figures 12A-12C). These results suggest that m 6 This suggests that the distinction in A occurs during the transition of MAVS from monomer to filament, and depends on RIG-I conformational changes rather than binding to RIG-I.

[0163] [Example 9] This embodiment confirms that circFOREIGN activates the dimerization of IRF3.

[0164] Following MAVS filament formation, the dimerization of the downstream transcription factor IRF3 completes innate immune signaling to the genome. To investigate the ability of circFOREIGN to activate IRF3, a cell-free assay was performed by first forming a RIG-I, RNA, K63-bound polyubiquitin complex, and then incubating it with radiolabeled IRF3 in the presence of a cell extract (S1) containing both cytosolic and mitochondrial fractions. circFOREIGN potently induced IRF3 dimerization in a concentration-dependent manner, whereas m 6A-modified circFOREIGN resulted in a substantial reduction in IRF3 dimerization (Figure 12D, lanes 5-7 compared to lanes 8-10). The known agonist, a 162 bp 5' ppp dsRNA, effectively stimulated RIG-I-mediated IRF3 dimerization when present in substotal amounts, and the increase in dsRNA inhibited the effective oligomerization of RIG-I on RNA (Figure 11D). 5'-hydroxyl linear RNA did not stimulate IRF3 dimerization, as predicted for the negative control (Figure 12D, lanes 2-4).

[0165] [Example 10] This embodiment supports the idea that circFOREIGN requires the formation of a proper complex before activation.

[0166] To understand the requirements for RIG-I oligomerization and activation, the order of addition of specific components for in vitro assays was investigated. 5'ppp RNA showed a more potent response when pre-incubated with RIG-I and K63-bound polyubiquitin before supplementation of S1 lysates. However, the addition of 5'ppp dsRNA after introduction of S1 lysates resulted in significant but reduced stimulating activity (Figure 11E, lanes 2 and 5 compared with lanes 8 and 9). Since no difference was observed between the presence or absence of polyubiquitin, the addition of K63-bound polyubiquitin during the S1 phase was ineffective (Figure 11E, lanes 2 and 5 compared with lanes 10 and 11). When circFOREIGN was added to S1 cell lysates and then mixed with RIG-I and polyubiquitin, no IRF3 dimerization activity was obtained (Figure 12D, lanes 11-13). These results likely suggest that, due to the rapid degradation or destabilization of free K63-linked polyubiquitin chains in cell lysates, polyubiquitin must first interact with RIG-I in the presence of the agonist circRNA to stabilize it. Therefore, the signaling complex must be formed before the addition of S1 cell lysates. Further experiments ruled out the role of endogenous RNA in circFOREIGN-mediated activation of IRF3 (Figure 11F).

[0167] In summary, the biochemical reconstitution experiments described above confirmed that circFOREIGN, RIG-I, and K63-Ubn form a three-component signaling competent complex for immune signaling.

[0168] [Example 11] This example shows the m 6 We will describe the significantly different localizations compared to A-marked circRNAs.

[0169] Immunofluorescence microscopy was performed to validate an in vitro assay for the direct sensing of circFOREIGN by RIG-I. HeLa cells were transfected with FITC-labeled circFOREIGN, immobilized with formaldehyde, and labeled with RIG-I and K63-conjugated polyubiquitin (Figure 13A). The majority of circFOREIGN-FITC co-localized with both RIG-I and K63-conjugated polyubiquitin (Figure 13B, 85.5%). When K63-conjugated polyubiquitin was present in the complex, its interaction with unmodified circFOREIGN activated RIG-I, which enabled subsequent stimulation of MAVS filament formation.

[0170] RIG-I activation involves unmodified circRNA and m 6 Since it distinguishes from A-modified circRNA, we hypothesized that YTHDF2 participates in a complex that inhibits RIG-I activation or reduces its binding to RIG-I. Previously, on circRNA, 1% m 6 I used the A modifier, but m 6 A is incorporated randomly, therefore in the RRACH consensus motif (sequence number 18), m 6 The A level was expected to be well below 1%. YTHDF2 is present in the RRACH motif (SEQ ID NO: 18), m 6 It binds to A (Dominissini et al., cited above; Meyer et al., cited above). Therefore, in the consensus sequence, m 6 For a good model of the arrangement of A, 10% m 6 A was incorporated into circFOREIGN. Immunofluorescence microscopy was performed on unmodified circFOREIGN or 10% m 6 The procedure was performed on A-modified circFOREIGN, RIG-I, and YTHDF2 (Figure 13C). 6In the presence of A modification, the percentage of circRNA co-localization with RIG-I and YTHDF2 more than doubled (33.8% to 65.3%), while the percentage of circFOREIGN interacting with RIG-I when alone decreased (Figure 13D, 61.9% to 29.3%). These results suggest that m 6 A modification supports the recruitment of YTHDF2 to the same complex as RIG-I, and immunofluorescence studies show that in cells, m 6 This provides orthogonal and spatial information about the remarkably different fates of unmodified circRNAs compared to A-modified circRNAs.

[0171] In summary, the data suggest that RIG-I recognizes foreign circRNAs via a mechanism dependent on K63-binding polyubiquitin (Figure 14). The formation of a complex of RIG-I, unmodified RNA, and K63-binding polyubiquitin induces MAVS filament formation and IRF3 dimerization, stimulating downstream interferon production. 6 A-modified circFOREIGN also binds to RIG-I, but it inhibits the activation of RIG-I, so m 6 Auto-circRNAs with A modification are safely ignored. In cells, YTHDF2 is m 6 It works together with A to inhibit immune signaling.

[0172] The above examples present in vivo evidence that circRNAs act as potent adjuvants, inducing specific T-cell and B-cell responses. CircRNAs are capable of inducing both innate and adaptive immune responses and have the ability to inhibit tumor establishment and growth. The results suggest that human circRNAs, at birth, are covalently linked based on introns that program their backsplicing. 6 This suggests that it is marked by A modification. RIG-I is unmodified circRNA and m 6It distinguishes between A-modified circRNA and other types of circRNA, and is activated only by the former. While RIG-I is necessary and sufficient for innate immunity against foreign circRNA (Chen et al., previously cited), the toll-like receptor is not responsive to circRNA (Wesslhoeft et al., previously cited). In contrast, foreign circRNA lacking RNA modification is recognized by RIG-I and K63-Ubn, and the m 6 A modifications are sufficient to mark them as "self" and prevent immune activation. All adenosine modifications or canonical m in model circRNAs 6 Modification of adenosine only within the A motif RRACH (sequence number 18) substantially increased the induction of antiviral genes by circRNA.

[0173] These results present the first evidence that specific circRNA exon sequences influence immunity, and endogenous m 6 This supports the idea that A modification weakens innate immunity. The m of 5' triphosphate linear RNA ligands... 6 A modification also eliminates binding to RIG-I and activation of RIG-I (Durbin et al., mBio, 7:e00833-00816 (2016); Peisley et al., Molecular Cell, 51:573~583 (2013)). Therefore, RIG-I is considered to be a general leader of circRNAs, and its activation is suppressed by RNA modification, a major characteristic of eukaryotic RNA. Unmodified circRNA and m 6While all AcircRNAs can bind to RIG-I, only unmodified circRNAs can activate RIG-I and induce MAVS filament formation. These results suggest that conformational changes in RIG-I are necessary to induce MAVS filament formation. This observation is similar to the selectivity of RIG-I over m7Gppp cap (present on all mRNA) for 5' triphosphate (present on viral RNA) rather than for ligand binding (Devarkar et al., previously cited). Cocrystallographic and biochemical analyses show that both 5' triphosphate and m7Gppp bind to RIG-I with the same affinity, but the latter induces significantly different conformational changes, causing RIG-I to filter endogenous mRNA and reduce ATPase activity (Devarkar et al., previously cited). In living cells, YTHDF2 inhibits conformational transduction of RIG-I, which is necessary for signal transduction downstream of immunogenes (Figure 13).

[0174] The above example systematically addresses the necessity, sufficiency, and domain requirements for YTHDF2-mediated suppression of circRNA-mediated immunity. The requirement for full-length YTHDF2 is that the YTH protein is m 6 The recruitment of A-modified RNAs to phase-separated condensates via their N-terminal denatured domains is consistent with recent models in which all domains are required for higher-order RNA-protein interactions (Luo, 2018). These results expand on existing knowledge about the function of YTHDF. While tethering of only the effector domain is sufficient to induce RNA degradation or translation (Wang et al., 2015; Wang et al., 2016), full-length proteins are required for the distinction between self and foreign circRNAs. These results suggest that m 6 Regarding A, it suggests a two-layer system that isolates and blocks endogenous circRNA to prevent activation of the RIG-I antiviral pathway. In addition to YTHDF2, other sensors and receptors also exist that are involved in the identification of endogenous circRNA as self.

[0175] All references cited herein, including publications, patent applications, and patents, are incorporated by reference to the same extent as each reference is individually and specifically indicated and expressed herein in whole.

[0176] Unless otherwise indicated herein, or unless the context expressly indicates otherwise, the use of the terms “a” and “an” and “it” as well as the terms “at least one” and similar terms in the context of the description of the present invention (in particular, in the context of the following claims) refers to both singular and plural referents. Unless otherwise indicated herein, or unless the context expressly indicates otherwise, the use of the term “at least one” (e.g., “at least one of A and B”) following one or more items in the list shall be understood to mean one item (A or B) selected from the enumerated items or any combination of two or more enumerated items (A and B). Unless otherwise noted, the terms “comprising,” “having,” “including,” and “containing” shall be understood to be open-ended terms (i.e., “including but not limited to.” Unless otherwise indicated herein, the enumeration of value ranges herein is intended solely as an abbreviation for referring to each individual value that falls within the range, and each individual value is incorporated herein as if it were individually enumerated herein. Unless otherwise indicated herein or the context otherwise clearly indicates otherwise, all methods described herein may be performed in any suitable order. The use of any and all examples or illustrative expressions (e.g., "etc.") presented herein is intended solely to better illustrate the invention and does not constitute a limitation on the scope of the invention unless otherwise claimed. No expression herein should be understood as referring to any unclaimed element as essential to the practice of the invention.

[0177] This specification describes preferred embodiments of the invention, including the best methods known to the inventors for carrying out the invention. Variations of these preferred embodiments may be apparent to those skilled in the art by reading the preceding description. The inventors expect that those skilled in the art will use such variations as appropriate, and the inventors intend that the invention may be carried out in ways other than those specifically described herein. Accordingly, the invention includes all modifications and equivalents of the subject matter enumerated in the claims accompanying this specification, to the extent permitted by applicable law. Furthermore, unless otherwise indicated herein, or unless the context explicitly indicates otherwise, any combination of all possible variations of the elements described above is also encompassed by the invention.

Claims

1. N6-methyladenosine (m 6 A) A vaccine composition containing a circular RNA molecule that does not contain any residues.

2. The vaccine composition according to claim 1, wherein the circular RNA lacks an RRACH motif.

3. A vaccine composition according to any one of claims 1 to 2, further comprising at least one antigen.

4. The vaccine composition according to any one of claims 1 to 2, comprising a circular RNA molecule operably linked to an internal ribosome entry site (IRES) that encodes a polypeptide.

5. The vaccine composition according to claim 4, wherein the sequence encoding the polypeptide encodes at least one antigen.

6. The vaccine composition according to claim 3 or 5, wherein at least one antigen is derived from a virus, a bacterium, a parasite, a fungus, a protozoan, a prion, a cell, or an extracellular antigen.

7. The vaccine composition according to claim 3 or 5, wherein at least one antigen is a tumor antigen.

8. The vaccine composition according to any one of claims 1 to 7, wherein the circular RNA molecule is produced using in vitro transcription.

9. The vaccine composition according to any one of claims 1 to 8, wherein circular RNA is present in the composition as naked RNA.

10. The vaccine composition according to any one of claims 1 to 8, wherein the circular RNA forms a complex with nanoparticles.

11. The vaccine composition according to claim 10, wherein the nanoparticles are polyethyleneimine (PEI) nanoparticles.

12. A method for inducing an innate immune response in a subject that requires induction of an innate immune response, comprising the step of administering to the subject an effective amount of the vaccine composition according to any one of claims 1 to 11.

13. A composition comprising a DNA sequence encoding a circular RNA, wherein the circular RNA is N6-methyladenosine (m 6 A) A composition that does not contain any residues whatsoever.

14. The composition according to claim 13, wherein the DNA sequence does not contain any RRACH motifs.

15. The composition according to claim 13 or 14, wherein the viral vector or nonviral vector comprises a DNA sequence.

16. The composition according to claim 15, wherein the viral vector is an adenovirus vector, an adeno-associated virus vector, a retrovirus vector, a lentivirus vector, or a herpesvirus vector.

17. The composition according to claim 15, wherein the nonviral vector is a plasmid.

18. A method for inducing an innate immune response in a subject that requires induction of an innate immune response, comprising the step of administering to the subject an effective amount of the composition according to any one of claims 13 to 17.

19. A method for producing circular RNA molecules by in vitro transcription, (a) A step of preparing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphates, and RNA polymerase; (c) the step of transcribing linear RNA from a DNA template; and (d) A step of forming circular RNA by circularizing linear DNA. Including; Ribonucleotide triphosphates are N6-methyladenosine-5' triphosphate (m 6 Contains no ATP whatsoever; Circular RNA can elicit an innate immune response in a target. method.

20. Circular RNA, m 6 The method according to claim 19, which does not contain A at all.

21. A method for producing circular RNA molecules by in vitro transcription, (a) A step of preparing a DNA template encoding a circular RNA molecule, ribonucleotide triphosphates, and RNA polymerase; (c) the step of transcribing linear RNA from a DNA template; and (d) A step of forming circular RNA by circularizing linear DNA. Including; Ribonucleotide triphosphates are N6-methyladenosine-5' triphosphate (m 6 (including ATP); Circular RNA uses the same method, but m 6 It exhibits lower immunogenicity compared to circular RNA produced using the absence of ATP. method.

22. At least 1% of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) The method according to claim 21.

23. At least 10% of the adenosine in recombinant circular RNA molecules is N6-methyladenosine (m 6 A) The method according to claim 22.

24. The method according to claim 23, wherein all of the adenosines in the recombinant circular RNA molecule are N6-methyladenosine (m 6 A).

25. A method for reducing the innate immunogenicity of circular RNA molecules, (a) the step of preparing a circular RNA molecule that induces an innate immune response in the subject; and (b) N6-methyladenosine (m 6 A) A step of introducing at least one nucleoside selected from pseudouridine and inosine into a circular RNA molecule to obtain a modified circular RNA molecule with reduced innate immunogenicity. A method that includes this.

26. The method according to claim 25, further comprising the step of administering a modified circular RNA to a subject.

27. Of the circular RNA molecules, at least 1% are m 6 A, the method according to claim 25 or 26, comprising pseudouridine and / or inosine.

28. Of the circular RNA molecules, at least 10% are m 6 The method according to claim 21, comprising A, pseudouridine and / or inosine.

29. A method for increasing the innate immunogenicity of circular RNA molecules, (a) a step of producing a circular RNA molecule lacking the RRACH motif; and (b) A step of replacing one or more adenosines with other bases to obtain a modified circular RNA molecule with increased innate immunogenicity, A method that includes this.

30. The method according to claim 29, further comprising the step of administering a modified circular RNA to a subject.

31. The method according to claim 29 or 30, wherein at least 1% of the adenosine in the circular RNA molecule is replaced by uracil.

32. The method according to claim 30, wherein at least 10% of the adenosine in the circular RNA molecule is replaced by uracil.

33. The method according to claim 32, wherein all of the adenosine molecules in the circular RNA molecule are replaced by uracil.

34. A method of delivering substances to cells, (a) at least one N6-methyladenosine (m 6 A) A step of creating a recombinant circular RNA molecule containing; (b) The step of conjugating a substance to a recombinant circular RNA molecule to create a complex containing the recombinant circular RNA molecule conjugated to the substance; and (c) A step of bringing cells into contact with the complex, thereby delivering a substance to the cells. A method that includes this.

35. The method according to claim 34, wherein the substance is a protein or a peptide.

36. The method according to claim 34 or 35, wherein the substance is an antigen or an epitope.

37. The method according to claim 34, wherein the substance is a low molecular weight substance.

38. The method according to any one of claims 34 to 37, wherein a substance is covalently linked to a recombinant circular RNA molecule.

39. A method for sequestering RNA-binding proteins within a cell, (a) at least one N6-methyladenosine (m 6 A) The step of creating a recombinant circular RNA molecule containing one or more RNA-binding protein-binding domains; and (b) A step of bringing a cell containing an RNA-binding protein into contact with a recombinant circular RNA molecule, thereby binding the RNA-binding protein to one or more RNA-binding protein-binding domains and sequestering it within the cell. A method that includes this.

40. The method according to claim 39, wherein the RNA-binding protein is abnormally expressed within the cell.

41. The method according to claim 39 or 40, wherein the RNA-binding protein is encoded by a nucleic acid sequence containing at least one mutation.

42. The method according to any one of claims 39 to 41, wherein the RNA-binding protein is associated with the disease.

43. At least 1% of the adenosine in the recombinant circular RNA molecule is N6-methyladenosine (m 6 A) The method according to any one of claims 39 to 42.

44. At least 10% of the adenosine in recombinant circular RNA molecules is N6-methyladenosine (m 6 A) The method according to claim 43.

45. All of the adenosine molecules within the recombinant circular RNA molecule are N6-methyladenosine (m 6 A) The method according to claim 44.

46. The method according to any one of claims 39 to 45, wherein the recombinant RNA molecule comprises a self-splicing group I intron and at least one exon of the phage T4 thymidylate synthase (td) gene.

47. The method according to any one of claims 39 to 46, wherein the recombinant circular RNA molecule includes an internal ribosome entry site (IRES).

48. The method according to any one of claims 39 to 47, wherein the recombinant circular RNA molecule comprises nucleotides between 200 and 6,000 nucleotides.

49. The method according to claim 48, wherein the recombinant circular RNA molecule comprises about 1,500 nucleotides.