Multiple losses of aKRAB from PRDM9 coincide with a teleost-specific intron size distribution.

IF 4.4 1区生物学 Q1 BIOLOGY BMC Biology Pub Date : 2024-11-27 DOI:10.1186/s12915-024-02059-w

Ann-Christin Zinner, Lars Martin Jakt

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Abstract

Background: Primary transcripts are largely comprised of intronic sequences that are excised and discarded shortly after synthesis. In vertebrates, the shape of the intron size distribution is largely constant; however, most teleost fish have a diverged log-bimodal 'teleost distribution' (TD) that is seen only in teleosts. How the TD evolved and to what extent this was affected by adaptative or non-adaptive mechanisms is unknown.

Results: Here, we show that the TD has evolved independently at least six times and that its appearance is linked to the loss of the aKRAB domain from PRDM9. We determined intron size distributions and identified PRDM9 orthologues from annotated genomes in addition to scanning 1193 teleost assemblies for the aKRAB domain. We show that a diverged form of PRDM9 ( $β$ ) is predominant in teleosts whereas the $α$ version is absent from most species. Only a subset of PRDM9- $α$ proteins contain aKRAB, and hence, it is present only in a small number of teleost lineages. Almost all lineages lacking aKRAB (but no species with) had TDs.

Conclusions: In mammals, PRDM9 defines the sites of meiotic recombination through a mechanism that increases structural variance and depends on aKRAB. The loss of aKRAB is likely to have shifted the locations of both recombination and structural variance hotspots. Our observations suggest that the TD evolved as a side-effect of these changes and link recombination to the evolution of intron size illustrating how genome architectures can evolve in the absence of selection.

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PRDM9 中 aKRAB 的多次缺失与远足鱼特有的内含子大小分布相吻合。

背景：初级转录本主要由内含子序列组成，这些序列在合成后不久就会被切除和丢弃。在脊椎动物中，内含子大小分布的形状基本上是恒定的；然而，大多数远洋鱼类具有仅见于远洋鱼类的对数双峰分布（TD）。TD是如何进化的，在多大程度上受到适应性或非适应性机制的影响，这些都是未知的：结果：在此，我们发现 TD 已独立进化了至少六次，其出现与 PRDM9 中 aKRAB 结构域的缺失有关。我们确定了内含子的大小分布，并从已注释的基因组中确定了 PRDM9 的同源物，此外还扫描了 1193 个远缘动物基因组以寻找 aKRAB 结构域。我们发现，PRDM9的分化形式（β）在远足类动物中占主导地位，而α版本在大多数物种中都不存在。只有一小部分 PRDM9-α 蛋白含有 aKRAB，因此它只存在于少数远足类动物中。几乎所有缺乏 aKRAB 的物种（但没有物种含有 aKRAB）都有 TDs：结论：在哺乳动物中，PRDM9通过一种增加结构变异并依赖于aKRAB的机制确定减数分裂重组的位点。aKRAB的缺失很可能改变了重组和结构变异热点的位置。我们的观察结果表明，TD的进化是这些变化的副作用，并将重组与内含子大小的进化联系起来，说明了基因组结构是如何在没有选择的情况下进化的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Biology 生物-生物学

CiteScore

7.80

自引率

1.90%

发文量

260

审稿时长

3 months

期刊介绍： BMC Biology is a broad scope journal covering all areas of biology. Our content includes research articles, new methods and tools. BMC Biology also publishes reviews, Q&A, and commentaries.