用于评估导致非性腺组织出现性别差异的性染色体效应的小鼠模型。
Mouse models for evaluating sex chromosome effects that cause sex differences in non-gonadal tissues.
作者信息
Arnold Arthur P
机构信息
Department of Physiological Science and Laboratory of Neuroendocrinology of the Brain Research Institute, University of California, Los Angeles, CA 90095-1606, USA.
出版信息
J Neuroendocrinol. 2009 Mar;21(4):377-86. doi: 10.1111/j.1365-2826.2009.01831.x.
Abstract
XX and XY cells have a different number of X and Y genes. These differences in their genomes cause sex differences in the functions of cells, both in the gonads and in non-gonadal tissues. This review discusses mouse models that have shed light on these direct genetic effects of sex chromosomes that cause sex differences in physiology. Because many sex differences in tissues are caused by different effects of male and female gonadal hormones, it is important to attempt to discriminate between direct genetic and hormonal effects. Numerous mouse models exist in which the number of X or Y genes is manipulated, aiming to observe the effects on phenotype. In two models, namely the four core genotypes model and SF1 knockout gonadless mice, it is possible to detect sex chromosome effects that are not explained by group differences in gonadal hormones. Moreover, mouse models are available to determine whether the sex chromosome effects are caused by X or Y genes.
摘要
XX细胞和XY细胞具有不同数量的X和Y基因。它们基因组中的这些差异导致性腺和非性腺组织中细胞功能的性别差异。本综述讨论了一些小鼠模型,这些模型揭示了性染色体导致生理性别差异的这些直接遗传效应。由于组织中的许多性别差异是由雄性和雌性性腺激素的不同作用引起的,因此区分直接遗传效应和激素效应很重要。存在许多操纵X或Y基因数量的小鼠模型,旨在观察对表型的影响。在两种模型中,即四核心基因型模型和SF1基因敲除的无性腺小鼠模型中,可以检测到性腺激素组间差异无法解释的性染色体效应。此外,还有小鼠模型可用于确定性染色体效应是由X基因还是Y基因引起的。
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