Molecular evolution of the hemoglobin gene family across vertebrates.

IF 1.3 4区 生物学 Q4 GENETICS & HEREDITY Genetica Pub Date : 2023-06-01 DOI:10.1007/s10709-023-00187-9
Yang Mao, Taotao Peng, Feng Shao, Qingyuan Zhao, Zuogang Peng
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Abstract

Adaptation to various altitudes and oxygen levels is a major aspect of vertebrate evolution. Hemoglobin is an erythrocyte protein belonging to the globin superfamily, and the α-, β-globin genes of jawed vertebrates encode tetrameric ((α2β2) hemoglobin, which contributes to aerobic metabolism by delivering oxygen from the respiratory exchange surfaces into cells. However, there are various gaps in knowledge regarding hemoglobin gene evolution, including patterns in cartilaginous fish and the roles of gene conversion in various taxa. Hence, we evaluated the evolutionary history of the vertebrate hemoglobin gene family by analyses of 97 species representing all classes of vertebrates. By genome-wide analyses, we extracted 879 hemoglobin sequences. Members of the hemoglobin gene family were conserved in birds and reptiles but variable in mammals, amphibians, and teleosts. Gene motifs, structures, and synteny were relatively well-conserved among vertebrates. Our results revealed that purifying selection contributed substantially to the evolution of all vertebrate hemoglobin genes, with mean dN/dS (ω) values ranging from 0.057 in teleosts to 0.359 in reptiles. In general, after the fish-specific genome duplication, the teleost hemoglobin genes showed variation in rates of evolution, and the β-globin genes showed relatively high ω values after a gene transposition event in amniotes. We also observed that the frequency of gene conversion was high in amniotes, with fewer hemoglobin genes and higher rates of evolution. Collectively, our findings provide detail insight into complex evolutionary processes shaping the vertebrate hemoglobin gene family, involving gene duplication, gene loss, purifying selection, and gene conversion.

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脊椎动物血红蛋白基因家族的分子进化。
适应不同的海拔和氧气水平是脊椎动物进化的一个主要方面。血红蛋白是一种红细胞蛋白,属于珠蛋白超家族,颌骨脊椎动物的α-、β-珠蛋白基因编码四聚体((α2 - β2)血红蛋白,该蛋白通过将氧气从呼吸交换表面输送到细胞中,有助于有氧代谢。然而,关于血红蛋白基因进化的知识存在各种空白,包括软骨鱼类的模式和基因转换在各种分类群中的作用。因此,我们通过分析代表所有类别的97种脊椎动物来评估脊椎动物血红蛋白基因家族的进化史。通过全基因组分析,我们提取了879个血红蛋白序列。血红蛋白基因家族的成员在鸟类和爬行动物中是保守的,但在哺乳动物、两栖动物和硬骨鱼中是可变的。基因基序、结构和共生性在脊椎动物中相对保守。结果表明,纯化选择对所有脊椎动物血红蛋白基因的进化都有重要贡献,其平均dN/dS (ω)值从硬骨鱼的0.057到爬行动物的0.359不等。总的来说,经过鱼类特异性基因组复制后,硬骨鱼血红蛋白基因的进化速度发生了变化,而在羊膜中发生基因转位事件后,β-珠蛋白基因的ω值相对较高。我们还观察到,基因转换的频率在羊膜中很高,血红蛋白基因较少,进化率较高。总的来说,我们的发现为形成脊椎动物血红蛋白基因家族的复杂进化过程提供了详细的见解,包括基因复制、基因丢失、净化选择和基因转换。
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来源期刊
Genetica
Genetica 生物-遗传学
CiteScore
2.70
自引率
0.00%
发文量
32
审稿时长
>12 weeks
期刊介绍: Genetica publishes papers dealing with genetics, genomics, and evolution. Our journal covers novel advances in the fields of genomics, conservation genetics, genotype-phenotype interactions, evo-devo, population and quantitative genetics, and biodiversity. Genetica publishes original research articles addressing novel conceptual, experimental, and theoretical issues in these areas, whatever the taxon considered. Biomedical papers and papers on breeding animal and plant genetics are not within the scope of Genetica, unless framed in an evolutionary context. Recent advances in genetics, genomics and evolution are also published in thematic issues and synthesis papers published by experts in the field.
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