Tissue-specific and pathogens-specific toxic agents, ribozymes, dnazymes and antisense oligonucleotides, and methods of use thereof

Abstract

The present invention relates to the discovery, identification and characterization of toxic agents which are lethal to pathogens and methods for targeting such toxic agents to a pathogen or pathogen infected cells in order to treat and / or eradicate the infection. In particular, the present invention relates to toxic agents which target bacteria at different stages of the bacterial life cycle, which are delivered alone or in combination to bacteria or bacteria-infected cells. The invention relates to toxic agents which are lethal to diseased cells and methods for targeting such toxic agent to a diseased cell in order to treat and / or eradicate the disease. The present invention relates to promoter elements which are pathogen-specific or tissue-specific and the use of such promoter elements to achieve pathogen-specific or tissue-specific expression of the toxic agent(s) and / or ribozyme(s) of the present invention. Specifically, the invention relates to the delivery of one or more toxic gene products, antisense RNAs, or ribozymes, or combination thereof. The invention provides a novel system by which multiple pathogenic targets may be simultaneously targeted to cause the death of a pathogen, or cell infected with a pathogen. Further, the invention has important implications in the eradication of drug-resistant bacterium and bacterial pathogens. The invention provides a novel system by which multiple targets may be simultaneously targeted to cause the death of a diseased cell. The invention has important implications in the eradication of drug-resistant pathogens (such as antibiotic resistant bacteria) and drug-resistant diseased cells (such as drug-resistant cancer cells).

Description

1. INTRODUCTION[0001] The present invention relates to the discovery, identification, and characterization of toxic agents which are lethal to pathogens and methods for targeting and delivering such toxic agents to a pathogen or pathogen infected cell in order to treat and / or eradicate an infection. In particular, the present invention relates to toxic agents which target bacteria at different stages of the bacterial life cycle, which are delivered alone or in combination to bacteria or bacteria-infected cells. In particular, the invention relates to a phage delivery vehicle approach for the treatment of bacterial infections in humans and animals. The invention also relates to toxic agents which are lethal to diseased cells and methods for targeting such toxic agents to a diseased cell in order to treat and / or eradicate the disease. The present invention relates to promoter elements which are pathogen-specific. The invention also relates to promoter elements which are used to achiev...

AI Technical Summary

Benefits of technology

[0026] The toxic agent approaches of the invention offer advances for antimicrobial therapeutics including but not limited to: (1) the bypass of de novo or built-in drug resistance, which sophisticated microbes may have or develop (2) the decreased ability of cells to counteract ribozymes or toxic agents delivered into them, (3) the use of broad RNA targets and non-RNA targets available in microbes that can be attacked in simultaneously (4) the flexibility of custom design of the present delivery vehicle can be readily tailored to different families of organisms or different species of organisms, (5) the ease of assembly construction and manufacture of the modified delivery vehicle, (6) the availability of a variety of methods of administration of the pharmaceutical preparations of the invention such as topically, or via injection, inhalation, or ingestion, etc. (7) the ability to lyophilize the pharmaceutical preparation and thus confer stability to the antimicrobial therapeutic, (8) the reduced immunogenicity of the therapeutic preparations, and (9) the availability of animal test systems that enable the evaluation of the ribozymes and / or toxic agents of the invention. Therefore, the unique delivery approach and an aggressive mechanism for depriving the pathogen essential or important gene products can achieve the timely defeat of pathogen within the infected host. Accordingly, the invention has important implication in the eradication of drug-resistant pathogens.

Problems solved by technology

Infectious diseases sicken or kill millions of people each year.

Infections by this organism are associated with high mortality (60%), which is attributed to the high intrinsic resistance of members of this genus to many structurally unrelated antibiotics.

Only a very limited number of new antibiotics have come onto the market in the last decade, yet the number of deadly bacteria that are resistant to these drug therapies has soared.

Additionally, the failure of many of these therapies to target specific infectious agents has lead to overuse or inappropriate use of the therapies, which in turn has lead to the development of drug resistant microbes.

The development of drug resistance in many infectious agents has reduced the efficacy and increased the risk of using the traditional antimicrobial therapies.

However, a large number of difficulties exist in the art surrounding antisense technology.

Commonly, delivery of an exogenous antisense molecule to the target cell is difficult or impossible to achieve.

Further, antisense molecules do not consistently lead to a decrease in protein expression.

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