Placental Evolution: Innovating how to Feed Babies.

IF 8.7 1区 生物学 Q1 GENETICS & HEREDITY
Julie C Baker
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Abstract

The evolution of the placenta was transformative. It changed how offspring are fed during gestation from depositing all the resources into an egg to continually supplying resources throughout gestation. Placental evolution is infinitely complex, with many moving parts, but at the core it is driven by a conflict over resources between the mother and the baby, which sets up a Red Queen race, fueling rapid diversification of morphological, cellular, and genetic forms. Placentas from even closely related species are highly divergent in form and function, and many cellular processes are distinct. If we could extract the entirety of genomic information for placentas across all species, including the many hundreds that have evolved in fish and reptiles, we could find their shared commonality, and that would tell us which of the many pieces really matter. We do not have this information, but we do have clues. Convergent evolution mechanisms were repeatedly used in the placenta, including the intense selective pressure to co-opt an envelope protein to build a multinucleated syncytium, the use of the same hormones and structural proteins in placentas derived from separate embryonic origins that arose hundreds of millions of years apart, and the co-option of endogenous retroviruses to form capsids as a way of transport and as mutagens to form new enhancers. As a result, the placental genome is the Wild West of biology, set up to rapidly change, adapt, and innovate. This ability to adapt facilitated the evolution of big babies with big brains and will continue to support offspring and their mothers in our ever-changing global environment.

胎盘进化:创新婴儿喂养方式
胎盘的进化是一场变革。它改变了妊娠期喂养后代的方式,从将所有资源存入卵中,到在整个妊娠期不断提供资源。胎盘的进化是无限复杂的,有许多活动的部分,但其核心是由母体和胎儿之间的资源冲突驱动的,这种冲突引发了一场红皇后竞赛,推动了形态、细胞和遗传形式的快速多样化。即使是近亲物种的胎盘在形态和功能上也有很大差异,许多细胞过程也各不相同。如果我们能提取所有物种胎盘的全部基因组信息,包括在鱼类和爬行动物中进化出的数百种胎盘,我们就能找到它们的共同点,从而告诉我们在众多信息中哪些是真正重要的。我们没有这些信息,但我们有线索。聚合进化机制在胎盘中被反复使用,包括在强烈的选择压力下共同采用一种包膜蛋白来构建多核合胞体;在来自不同胚胎起源的胎盘中使用相同的激素和结构蛋白,这些胚胎起源相差数亿年;共同采用内源性逆转录病毒来形成囊壳,作为一种运输方式,并作为突变剂来形成新的增强子。因此,胎盘基因组是生物学中的狂野西部,可以快速变化、适应和创新。这种适应能力促进了大脑袋婴儿的进化,并将继续在不断变化的全球环境中支持后代和他们的母亲。
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来源期刊
Annual review of genetics
Annual review of genetics 生物-遗传学
CiteScore
18.30
自引率
0.90%
发文量
17
期刊介绍: The Annual Review of Genetics, published since 1967, comprehensively covers significant advancements in genetics. It encompasses various areas such as biochemical, behavioral, cell, and developmental genetics, evolutionary and population genetics, chromosome structure and transmission, gene function and expression, mutation and repair, genomics, immunogenetics, and other topics related to the genetics of viruses, bacteria, fungi, plants, animals, and humans.
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