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老年男性睾丸中精子端粒更长的悖论:女性生殖系跨代端粒侵蚀导致的出生队列效应。

The paradox of longer sperm telomeres in older men's testes: a birth-cohort effect caused by transgenerational telomere erosion in the female germline.

作者信息

Stindl Reinhard

机构信息

apo-med-center, Alpharm, Plättenstrasse 7-9, 2380 Perchtoldsdorf, Austria, Europe.

出版信息

Mol Cytogenet. 2016 Feb 8;9:12. doi: 10.1186/s13039-016-0224-1. eCollection 2016.

DOI:10.1186/s13039-016-0224-1
PMID:26858775
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4745172/
Abstract

Longer telomeres in the somatic cells of an individual have been regarded as a marker of youth and biological fitness within a population. Yet, several research groups have reported the surprising findings of longer telomeres in the germ cells of older men, which translated into longer leukocyte telomere length in their offspring. Although all these studies were purely cross-sectional, a longitudinal trend in the aging testes of individual males was taken for granted. Recently, a high-profile study reported a negative birth-cohort effect on leukocyte mean telomere length in human populations, namely the progressive loss of telomeric sequence between healthy human generations. This is what I based my theory of telomere-driven macroevolution on, 12 years ago. On the basis of published data on telomere length inheritance, I identified the source of human intergenerational telomere erosion in the female germline. Accordingly, because of the resulting birth-cohort effect, there is no need for any paradoxical telomere lengthening in older men's gonads to interpret the old-father-long-telomered-offspring data.

摘要

个体体细胞中较长的端粒被视为该群体中年轻和生物适应性的一个标志。然而,几个研究小组报告了令人惊讶的发现:老年男性生殖细胞中的端粒更长,这导致其后代白细胞端粒长度也更长。尽管所有这些研究都只是横断面研究,但个体男性衰老睾丸中的纵向趋势被视为理所当然。最近,一项备受瞩目的研究报告了人类群体中出生队列对白细胞平均端粒长度的负面影响,即在健康人类代际之间端粒序列的逐渐丢失。这就是我12年前提出端粒驱动宏观进化理论的依据。根据已发表的端粒长度遗传数据,我确定了女性生殖系中人类代际端粒侵蚀的来源。因此,由于由此产生的出生队列效应,无需用老年男性性腺中任何矛盾的端粒延长来解释老年父亲端粒长后代的数据。

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