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A Breeding Method for Analyzing Polygene Aggregation Effects of Improving Lamb Size in Goats

A litter size and multi-gene technology, which is applied in biochemical equipment and methods, microbial measurement/inspection, DNA/RNA fragments, etc., can solve the problems of low breeding efficiency, time-consuming, poor selection effect of single gene molecular markers, etc. , to achieve the effect of reducing breeding time, increasing litter size, and increasing genetic progress

Active Publication Date: 2021-04-27
SOUTH CHINA AGRI UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0010] The purpose of the present invention is to overcome the defects and deficiencies of the prior art in the genetic selection of litter size traits, to provide a multi-gene aggregation molecular marker that affects the litter size traits of goats and a multi-gene aggregation breeding method for improving the litter size traits of goats , to overcome the shortcomings of conventional breeding techniques such as long time-consuming, low breeding efficiency and poor selection effect of single gene molecular markers for complex economic traits

Method used

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  • A Breeding Method for Analyzing Polygene Aggregation Effects of Improving Lamb Size in Goats
  • A Breeding Method for Analyzing Polygene Aggregation Effects of Improving Lamb Size in Goats
  • A Breeding Method for Analyzing Polygene Aggregation Effects of Improving Lamb Size in Goats

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Experimental program
Comparison scheme
Effect test

Embodiment 1

[0076] The establishment of the PCR-RFLP detection method of embodiment 1GnRHR gene

[0077] (1) Primer design

[0078] According to the goat GnRHR gene sequence (Gene ID on NCBI: 100860755), utilize Primer5.0 software to design a pair of primers, sequence is as follows:

[0079] GnRHR:

[0080] SEQ ID NO.4: Upstream primer PCR-F: 5'-TCTTGAAGCTGTATCAGCCATA-3';

[0081] SEQ ID NO.5: Downstream primer PCR-R: 5'-GTGTTGAAAATTGTGGAGAGTAGA-3'.

[0082] (2) PCR amplification system and program setting

[0083] PCR reaction system: 10 μL system contains 1 μL of genomic DNA template, 0.2 μL of upstream and downstream primers, 5 μL of TaqDNA polymerase, supplemented with deionized double-distilled water to the final volume.

[0084] PCR reaction program: pre-denaturation at 94°C for 2 min, 35 cycles (denaturation at 94°C for 30 s, annealing at 56°C for 30 s, extension at 72°C for 30 s), extension at 72°C for 5 min, and storage at 4°C.

[0085] The PCR reaction product was detected ...

Embodiment 2

[0102] The establishment of the PCR-HRM detection method of embodiment 2FSHR gene

[0103] (1) Primer design for high resolution melting curve (HRM)

[0104] According to the goat FSHR gene sequence (Gene ID on NCBI: 100861291), utilize Primer5.0 software to design a pair of primers, sequence is as follows:

[0105] FSHR:

[0106] SEQ ID NO.6: Upstream primer PCR-F: 5'-TACCAGCTCCCAACGCAGAC-3';

[0107] SEQ ID NO.7: Downstream primer PCR-R: 5'-GACAGAGTCGATGGTGGCAT-3'.

[0108] (2) High resolution melting curve (HRM) reaction conditions

[0109] Use 55-65°C temperature gradient PCR to understand the optimal annealing temperature of the primers to obtain specific PCR products and improve the sensitivity of high-resolution melting.

[0110] PCR reaction system (10 μL): DNA template 1 μL, upstream and downstream primers 0.3 μL, dye 5 μL, RNase-freewater 3.4 μL.

[0111]The PCR reaction program was: pre-denaturation at 94°C for 2 min, 40 cycles (denaturation at 94°C for 10 s, a...

Embodiment 3

[0129] The establishment of the PCR-RFLP detection method of embodiment 3BMP6 gene

[0130] (1) Primer design

[0131] According to the goat BMP6 gene sequence (Gene ID on NCBI: 100860793), utilize Primer5.0 software to design a pair of primers, sequence is as follows:

[0132] BMP6:

[0133] SEQ ID NO.8: Upstream primer PCR-F: 5'-TGTGCCCTCACCTGCTGTCTC-3';

[0134] SEQ ID NO.9: Downstream primer PCR-R: 5'-CCCGGCCTTCCTCTTTAACTC-3'.

[0135] (2) PCR amplification system and program setting

[0136] PCR reaction system: 10 μL system contains 1 μL of genomic DNA template, 0.2 μL of upstream and downstream primers, 5 μL of TaqDNA polymerase, supplemented with deionized double-distilled water to the final volume.

[0137] PCR reaction program: pre-denaturation at 94°C for 2 min, 35 cycles (denaturation at 94°C for 30 s, annealing at 59°C for 30 s, extension at 72°C for 30 s), extension at 72°C for 5 min, and storage at 4°C.

[0138] PCR reaction product is detected with 2% agar...

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Abstract

The invention belongs to the fields of molecular biotechnology and molecular marker breeding, and in particular relates to a breeding method for analyzing the polygene aggregation effect of improving the litter size trait of goats. GnRHR, FSHR and BMP6 genes were selected as candidate genes affecting litter size traits in goats, and there was one polymorphic site in each of these three genes. Carry out GnRHR-FSHR-BMP6 polygene aggregation effect analysis model to described molecular marker, find that AATTCC type is the optimal combination genotype, the present invention can accelerate the genetic progress of litter size trait of Chongqing black goat by optimizing this combination genotype, And it can improve the efficiency of its early selection, which is of great significance to the cultivation of new breeds (lines) of high-quality high-passage goats.

Description

technical field [0001] The invention belongs to the technical fields of goat molecular biotechnology and molecular markers, and in particular relates to a breeding method for analyzing the effect of multigene aggregation for increasing the litter size of goats. In the present invention, the aggregation effect analysis of the molecular marker and the litter size of goats is applied to the early breeding work of the litter size traits of goats. Background technique [0002] At present, the degree of intensification of the goat industry is not high, most of them are free-range breeding, and the degree of improved breeds is low, the level of productivity is not high, and the economic benefits are not ideal. Therefore, the healthy and sustainable development of the sheep industry is a top priority. Reproductive traits are important economic traits. For breeding stock, fecundity is productivity, and reproductive performance is directly related to the economic effect of the mutton...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): C12Q1/6888C12N15/11
CPCC12Q1/6888C12Q2600/124C12Q2600/156
Inventor 李耀坤杨新月刘德武柳广斌孙宝丽
Owner SOUTH CHINA AGRI UNIV
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