Belinky Frida, Bykova Anastassia, Yurchenko Vyacheslav, Rogozin Igor B
National Center for Biotechnology Information, National Library of Medicine, National Institutes of Health, Bethesda, MD, United States.
Life Science Research Centre, Faculty of Science, University of Ostrava, Ostrava, Czech Republic.
Front Genet. 2022 Sep 9;13:991249. doi: 10.3389/fgene.2022.991249. eCollection 2022.
Nucleotide substitutions in protein-coding genes can be divided into synonymous (S) and non-synonymous (N) ones that alter amino acids (including nonsense mutations causing stop codons). The S substitutions are expected to have little effect on function. The N substitutions almost always are affected by strong purifying selection that eliminates them from evolving populations. However, additional mutations of nearby bases can modulate the deleterious effect of single N substitutions and, thus, could be subjected to the positive selection. This effect has been demonstrated for mutations in the serine codons, stop codons and double N substitutions in prokaryotes. In all abovementioned cases, a novel technique was applied that allows elucidating the effects of selection on double substitutions considering mutational biases. Here, we applied the same technique to study double N substitutions in eukaryotic lineages of primates and yeast. We identified markedly fewer cases of purifying selection relative to prokaryotes and no evidence of codon double substitutions under positive selection. This is consistent with previous studies of serine codons in primates and yeast. In general, the obtained results strongly suggest that there are major differences between studied pro- and eukaryotes; double substitutions in primates and yeasts largely reflect mutational biases and are not hallmarks of selection. This is especially important in the context of detection of positive selection in codons because it has been suggested that multiple mutations in codons cause false inferences of lineage-specific site positive selection. It is likely that this concern is applicable to previously studied prokaryotes but not to primates and yeasts where markedly fewer double substitutions are affected by positive selection.
蛋白质编码基因中的核苷酸替换可分为同义(S)替换和非同义(N)替换,后者会改变氨基酸(包括导致终止密码子的无义突变)。预计同义替换对功能影响很小。非同义替换几乎总是受到强烈的纯化选择影响,这种选择会将它们从进化群体中淘汰。然而,附近碱基的额外突变可以调节单个非同义替换的有害影响,因此可能会受到正选择。这种效应已在原核生物的丝氨酸密码子、终止密码子突变和双重非同义替换中得到证实。在上述所有情况下,都应用了一种新技术,该技术能够在考虑突变偏差的情况下阐明选择对双重替换的影响。在这里,我们应用相同的技术来研究灵长类和酵母真核谱系中的双重非同义替换。我们发现相对于原核生物,纯化选择的情况明显更少,并且没有证据表明存在正选择下的密码子双重替换。这与之前对灵长类和酵母中丝氨酸密码子的研究一致。总体而言,所得结果强烈表明,所研究的原核生物和真核生物之间存在重大差异;灵长类和酵母中的双重替换很大程度上反映了突变偏差,并非选择的标志。这在密码子正选择检测的背景下尤为重要,因为有人提出密码子中的多个突变会导致对谱系特异性位点正选择的错误推断。很可能这种担忧适用于之前研究的原核生物,但不适用于灵长类和酵母,在灵长类和酵母中,受正选择影响的双重替换明显更少。
