在近交系鸡的高级互交系中进行 QTL 的精细定位和复制。

Fine mapping and replication of QTL in outbred chicken advanced intercross lines.

机构信息

Department of Animal Breeding and Genetics, Swedish University of Agricultural Sciences, Uppsala, Sweden.

出版信息

Genet Sel Evol. 2011 Jan 17;43(1):3. doi: 10.1186/1297-9686-43-3.

DOI:10.1186/1297-9686-43-3

PMID:21241486

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3034666/

Abstract

BACKGROUND

Linkage mapping is used to identify genomic regions affecting the expression of complex traits. However, when experimental crosses such as F(2) populations or backcrosses are used to map regions containing a Quantitative Trait Locus (QTL), the size of the regions identified remains quite large, i.e. 10 or more Mb. Thus, other experimental strategies are needed to refine the QTL locations. Advanced Intercross Lines (AIL) are produced by repeated intercrossing of F(2) animals and successive generations, which decrease linkage disequilibrium in a controlled manner. Although this approach is seen as promising, both to replicate QTL analyses and fine-map QTL, only a few AIL datasets, all originating from inbred founders, have been reported in the literature.

METHODS

We have produced a nine-generation AIL pedigree (n = 1529) from two outbred chicken lines divergently selected for body weight at eight weeks of age. All animals were weighed at eight weeks of age and genotyped for SNP located in nine genomic regions where significant or suggestive QTL had previously been detected in the F(2) population. In parallel, we have developed a novel strategy to analyse the data that uses both genotype and pedigree information of all AIL individuals to replicate the detection of and fine-map QTL affecting juvenile body weight.

RESULTS

Five of the nine QTL detected with the original F(2) population were confirmed and fine-mapped with the AIL, while for the remaining four, only suggestive evidence of their existence was obtained. All original QTL were confirmed as a single locus, except for one, which split into two linked QTL.

CONCLUSIONS

Our results indicate that many of the QTL, which are genome-wide significant or suggestive in the analyses of large intercross populations, are true effects that can be replicated and fine-mapped using AIL. Key factors for success are the use of large populations and powerful statistical tools. Moreover, we believe that the statistical methods we have developed to efficiently study outbred AIL populations will increase the number of organisms for which in-depth complex traits can be analyzed.

摘要

背景

连锁图谱用于鉴定影响复杂性状表达的基因组区域。然而，当使用实验杂交（如 F2 群体或回交）来定位包含数量性状基因座（QTL）的区域时，所鉴定的区域大小仍然相当大，即 10Mb 或更多。因此，需要其他实验策略来细化 QTL 位置。高级互交系（AIL）是通过 F2 动物的反复杂交和连续几代，以受控的方式降低连锁不平衡而产生的。尽管这种方法被认为很有前途，既可以重复 QTL 分析，也可以精细定位 QTL，但文献中仅报道了少数来自近交系的 AIL 数据集。

方法

我们从两个在 8 周龄时体重差异选择的杂交鸡系中产生了一个 9 代 AIL 系谱（n=1529）。所有动物在 8 周龄时称重，并对位于 9 个基因组区域的 SNP 进行基因型分析，这些区域在 F2 群体中先前检测到了显著或提示性的 QTL。同时，我们开发了一种新的策略来分析数据，该策略使用所有 AIL 个体的基因型和系谱信息来复制检测和精细定位影响青少年体重的 QTL。

结果

在 F2 群体中检测到的 9 个 QTL 中有 5 个得到了确认，并使用 AIL 进行了精细定位，而对于其余 4 个 QTL，则仅获得了它们存在的提示性证据。除了一个 QTL 分为两个连锁 QTL 外，所有原始 QTL 均被确认为单个基因座。

结论

我们的结果表明，在对大型杂交群体进行分析时，许多在全基因组范围内具有显著或提示意义的 QTL 都是可以通过 AIL 进行复制和精细定位的真实效应。成功的关键因素是使用大群体和强大的统计工具。此外，我们相信，我们开发的用于有效研究杂交 AIL 群体的统计方法将增加可以深入分析复杂性状的生物体数量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/feca/3034666/9fe21997aaac/1297-9686-43-3-1.jpg

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在近交系鸡的高级互交系中进行 QTL 的精细定位和复制。

Fine mapping and replication of QTL in outbred chicken advanced intercross lines.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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