大型三代同堂的人类家庭揭示了合子后镶嵌现象和生殖系突变积累的可变性。

Large, three-generation human families reveal post-zygotic mosaicism and variability in germline mutation accumulation.

机构信息

Department of Human Genetics, University of Utah, Salt Lake City, United States.

Howard Hughes Medical Institute and Department of Genetics, Stanford University, Stanford, United States.

出版信息

Elife. 2019 Sep 24;8:e46922. doi: 10.7554/eLife.46922.

DOI:10.7554/eLife.46922

PMID:31549960

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6759356/

Abstract

The number of de novo mutations (DNMs) found in an offspring's genome increases with both paternal and maternal age. But does the rate of mutation accumulation in human gametes differ across families? Using sequencing data from 33 large, three-generation CEPH families, we observed significant variability in parental age effects on DNM counts across families, ranging from 0.19 to 3.24 DNMs per year. Additionally, we found that ~3% of DNMs originated following primordial germ cell specification in a parent, and differed from non-mosaic germline DNMs in their mutational spectra. We also discovered that nearly 10% of candidate DNMs in the second generation were post-zygotic, and present in both somatic and germ cells; these gonosomal mutations occurred at equivalent frequencies on both parental haplotypes. Our results demonstrate that rates of germline mutation accumulation vary among families with similar ancestry, and confirm that post-zygotic mosaicism is a substantial source of human DNM.

摘要

后代基因组中发现的新生突变 (DNM) 数量随父本和母本年龄的增加而增加。但是，人类配子中的突变积累率是否在不同家庭之间存在差异？利用来自 33 个大型三代 CEPH 家族的测序数据，我们观察到家族间 DNM 计数的父母年龄效应存在显著差异，范围从每年 0.19 到 3.24 个 DNM。此外，我们发现约 3%的 DNM 是在父母的原始生殖细胞特化后产生的，并且与非嵌合生殖系 DNM 在突变谱上不同。我们还发现，第二代中的近 10%的候选 DNM 是合子后发生的，存在于体细胞和生殖细胞中；这些性染色体突变在两个亲本单倍型上以相同的频率发生。我们的研究结果表明，具有相似祖先的家庭中生殖系突变积累的速度存在差异，并证实合子后镶嵌性是人类 DNM 的一个重要来源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2899/6759356/0f236fc8c5d8/elife-46922-fig1.jpg

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大型三代同堂的人类家庭揭示了合子后镶嵌现象和生殖系突变积累的可变性。

Large, three-generation human families reveal post-zygotic mosaicism and variability in germline mutation accumulation.

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