Can the male germline offer insight into mammalian brain size expansion?

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-09-18 DOI:10.1111/andr.13766
Stephen J. Bush, Anne Goriely
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Abstract

Recent advances in single‐cell transcriptomic data have greatly expanded our understanding of both spermatogenesis and the molecular mechanisms of male infertility. However, this growing wealth of data could also shed light on a seemingly unrelated biological problem: the genetic basis of mammalian brain size expansion throughout evolution. It is now increasingly recognized that the testis and brain share many cellular and molecular similarities including pivotal roles for the RAS/MAPK and PI3K/AKT/mTOR pathways, mutations in which are known to have a pronounced impact on cell proliferation. Most notably, in the stem cell lineages of both organs, new mutations have been shown to increase cellular output over time. These include ‘selfish’ mutations in spermatogonial stem cells, which disproportionately increase the proportion of mutant sperm, and—to draw a parallel—human‐specific mutations in neural stem cells which, by increasing the number of neurons, have been implicated in neocortical expansion. Here we speculate that the origin for many ‘expansion’‐associated mutations is the male germline and that as such, a deeper understanding of the mechanisms controlling testicular turnover may yield fresh insight into the biology and evolution of the brain.
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雄性生殖系能否揭示哺乳动物脑容量扩张的奥秘?
单细胞转录组数据的最新进展极大地扩展了我们对精子发生和男性不育分子机制的了解。然而,这些日益丰富的数据还可以揭示一个看似无关的生物学问题:哺乳动物大脑体积在整个进化过程中不断扩大的遗传基础。现在越来越多的人认识到,睾丸和大脑在细胞和分子方面有许多相似之处,包括RAS/MAPK和PI3K/AKT/mTOR通路的关键作用,而这些通路的突变已知会对细胞增殖产生明显影响。最值得注意的是,在这两个器官的干细胞系中,新的突变已被证明会随着时间的推移增加细胞的产量。这包括精原干细胞中的 "自私 "突变,它不成比例地增加了突变精子的比例;与此类似,神经干细胞中的人类特异性突变,通过增加神经元的数量,被认为与新皮质扩展有关。在此,我们推测许多与 "扩张 "相关的突变起源于男性生殖细胞,因此,更深入地了解控制睾丸更替的机制可能会对大脑的生物学和进化产生新的见解。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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