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阐明性腺激素在性别二态性基因共表达网络中的作用。

Elucidating the role of gonadal hormones in sexually dimorphic gene coexpression networks.

作者信息

van Nas Atila, Guhathakurta Debraj, Wang Susanna S, Yehya Nadir, Horvath Steve, Zhang Bin, Ingram-Drake Leslie, Chaudhuri Gautam, Schadt Eric E, Drake Thomas A, Arnold Arthur P, Lusis Aldons J

机构信息

Department of Human Genetics, University of California, Los Angeles, California 90095-1679, USA.

出版信息

Endocrinology. 2009 Mar;150(3):1235-49. doi: 10.1210/en.2008-0563. Epub 2008 Oct 30.

DOI:10.1210/en.2008-0563
PMID:18974276
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2654741/
Abstract

We previously used high-density expression arrays to interrogate a genetic cross between strains C3H/HeJ and C57BL/6J and observed thousands of differences in gene expression between sexes. We now report analyses of the molecular basis of these sex differences and of the effects of sex on gene expression networks. We analyzed liver gene expression of hormone-treated gonadectomized mice as well as XX male and XY female mice. Differences in gene expression resulted in large part from acute effects of gonadal hormones acting in adulthood, and the effects of sex chromosomes, apart from hormones, were modest. We also determined whether there are sex differences in the organization of gene expression networks in adipose, liver, skeletal muscle, and brain tissue. Although coexpression networks of highly correlated genes were largely conserved between sexes, some exhibited striking sex dependence. We observed strong body fat and lipid correlations with sex-specific modules in adipose and liver as well as a sexually dimorphic network enriched for genes affected by gonadal hormones. Finally, our analyses identified chromosomal loci regulating sexually dimorphic networks. This study indicates that gonadal hormones play a strong role in sex differences in gene expression. In addition, it results in the identification of sex-specific gene coexpression networks related to genetic and metabolic traits.

摘要

我们之前使用高密度表达阵列来研究C3H/HeJ和C57BL/6J品系之间的遗传杂交,并观察到两性之间数千个基因表达差异。我们现在报告对这些性别差异的分子基础以及性别对基因表达网络影响的分析。我们分析了经激素处理的去性腺小鼠以及XX雄性和XY雌性小鼠的肝脏基因表达。基因表达差异很大程度上源于成年期性腺激素的急性作用,而除激素外,性染色体的作用较小。我们还确定了脂肪、肝脏、骨骼肌和脑组织中基因表达网络的组织是否存在性别差异。尽管高度相关基因的共表达网络在两性之间基本保守,但有些表现出显著的性别依赖性。我们观察到体脂和脂质与脂肪和肝脏中的性别特异性模块有很强的相关性,以及一个富含受性腺激素影响基因的性二态网络。最后,我们的分析确定了调节性二态网络的染色体位点。这项研究表明性腺激素在基因表达的性别差异中起重要作用。此外,它还导致识别出与遗传和代谢特征相关的性别特异性基因共表达网络。

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