对生长速度高低两个方向选择的鸡群体进行主效、上位性和性别特异性 QTL 定位分析，以研究体组成。

Mapping main, epistatic and sex-specific QTL for body composition in a chicken population divergently selected for low or high growth rate.

机构信息

Department of Poultry Science/Institute of Bioinformatics, University of Georgia, Athens, GA 30602, USA.

出版信息

BMC Genomics. 2010 Feb 11;11:107. doi: 10.1186/1471-2164-11-107.

DOI:10.1186/1471-2164-11-107

PMID:20149241

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2830984/

Abstract

BACKGROUND

Delineating the genetic basis of body composition is important to agriculture and medicine. In addition, the incorporation of gene-gene interactions in the statistical model provides further insight into the genetic factors that underlie body composition traits. We used Bayesian model selection to comprehensively map main, epistatic and sex-specific QTL in an F2 reciprocal intercross between two chicken lines divergently selected for high or low growth rate.

RESULTS

We identified 17 QTL with main effects across 13 chromosomes and several sex-specific and sex-antagonistic QTL for breast meat yield, thigh + drumstick yield and abdominal fatness. Different sets of QTL were found for both breast muscles [Pectoralis (P) major and P. minor], which suggests that they could be controlled by different regulatory mechanisms. Significant interactions of QTL by sex allowed detection of sex-specific and sex-antagonistic QTL for body composition and abdominal fat. We found several female-specific P. major QTL and sex-antagonistic P. minor and abdominal fatness QTL. Also, several QTL on different chromosomes interact with each other to affect body composition and abdominal fatness.

CONCLUSIONS

The detection of main effects, epistasis and sex-dimorphic QTL suggest complex genetic regulation of somatic growth. An understanding of such regulatory mechanisms is key to mapping specific genes that underlie QTL controlling somatic growth in an avian model.

摘要

背景

阐明身体成分的遗传基础对于农业和医学都很重要。此外，在统计模型中纳入基因-基因相互作用，可以更深入地了解身体成分特征的遗传因素。我们使用贝叶斯模型选择，全面绘制了两个鸡系之间的 F2 互交的主效、上位性和性别特异性 QTL，这两个鸡系是为了高或低生长速度而进行了分歧选择。

结果

我们在 13 条染色体上鉴定出了 17 个具有主效的 QTL，以及一些与性别特异性和性别拮抗相关的 QTL，用于胸肉产量、大腿+鸡腿产量和腹部脂肪。两个不同的胸肌（胸大肌和胸小肌）都有不同的 QTL 集，这表明它们可能受到不同的调控机制控制。通过性别对 QTL 的显著相互作用，可以检测到身体成分和腹部脂肪的性别特异性和性别拮抗 QTL。我们发现了几个雌性特异性的胸大肌 QTL 和性别拮抗的胸小肌和腹部脂肪 QTL。此外，几个位于不同染色体上的 QTL 相互作用，影响身体成分和腹部脂肪。

结论

主效、上位性和性别二态性 QTL 的检测表明，体生长的遗传调控很复杂。了解这些调控机制是在禽类模型中映射控制体生长的特定基因的关键。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2f24/2830984/d45184ad3514/1471-2164-11-107-1.jpg

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对生长速度高低两个方向选择的鸡群体进行主效、上位性和性别特异性 QTL 定位分析，以研究体组成。

Mapping main, epistatic and sex-specific QTL for body composition in a chicken population divergently selected for low or high growth rate.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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