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一种新的主要组织相容性复合体进化理论:超越对免疫基因的选择。

A new theory of MHC evolution: beyond selection on the immune genes.

作者信息

van Oosterhout Cock

机构信息

Evolutionary Biology Group, Biological Sciences, University of Hull, Hull HU6 7RX, UK.

出版信息

Proc Biol Sci. 2009 Feb 22;276(1657):657-65. doi: 10.1098/rspb.2008.1299.

DOI:10.1098/rspb.2008.1299
PMID:18986972
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2660941/
Abstract

The major histocompatibility complex (MHC) is a dense region of immune genes with high levels of polymorphism, which are arranged in haplotype blocks. Traditional models of balancing selection (i.e. overdominance and negative frequency dependence) were developed to study the population genetics of single genes. However, the MHC is a multigene family surrounded by linked (non-neutral) polymorphisms, and not all of its features are well explained by these models. For example, (i) the high levels of polymorphism in small populations, (ii) the unexpectedly large genetic differentiation between populations, (iii) the shape of the allelic genealogy associated with trans-species evolution, and (iv) the close associations between particular MHC (human leucocyte antigen, HLA) haplotypes and the approximately 100 pathologies in humans. Here, I propose a new model of MHC evolution named Associative Balancing Complex evolution that can explain these phenomena. The model proposes that recessive deleterious mutations accumulate as a 'sheltered load' nearby MHC genes. These mutations can accumulate because (i) they are rarely expressed as homozygotes given the high MHC gene diversity and (ii) purifying selection is inefficient with low recombination rates (cf. Muller's ratchet). Once fixed, these mutations add to balancing selection and further reinforce linkage through epistatic selection against recombinants.

摘要

主要组织相容性复合体(MHC)是一个免疫基因密集区域,具有高度多态性,这些基因以单倍型块的形式排列。传统的平衡选择模型(即超显性和负频率依赖)是为研究单基因的群体遗传学而建立的。然而,MHC是一个多基因家族,周围环绕着连锁(非中性)多态性,这些模型并不能很好地解释其所有特征。例如,(i)小群体中的高度多态性,(ii)群体间意外大的遗传分化,(iii)与跨物种进化相关的等位基因谱系形状,以及(iv)特定MHC(人类白细胞抗原,HLA)单倍型与人类约100种病理之间的密切关联。在此,我提出一种名为关联平衡复合体进化的MHC进化新模型,该模型可以解释这些现象。该模型提出,隐性有害突变作为“隐蔽负荷”在MHC基因附近积累。这些突变能够积累是因为(i)鉴于MHC基因的高度多样性,它们很少以纯合子形式表达,以及(ii)在低重组率情况下纯化选择效率低下(参见穆勒棘轮)。一旦固定,这些突变会增加平衡选择,并通过对重组体的上位选择进一步加强连锁。

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