Gianluca Merello Oyarzún, Montserrat Olivares-Costa, Lorenzo Basile, Tammy P Pástor, Pablo Mendoza-Soto, Luis Padilla-Santiago, Gonzalo A Mardones, Claudia Binda, Juan C Opazo
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摘要
单胺氧化酶(MAO)基因家族编码执行单胺氧化脱氨的酶,这是降解去甲肾上腺素、血清素、多巴胺和其他胺类所需的过程。虽然哺乳动物的 MAO 酶(MAO A 和 MAO B)已被广泛研究,但其他家族成员的分子特性仅被部分揭示。本研究旨在探索单胺氧化酶的进化,重点是了解脊椎动物的 MAO 基因库。我们的分析表明,产生 MAO A 和 MAO B 的复制发生在距今 4.08 亿年至 3.52 亿年前的四足类动物祖先时期。非四足类有颌脊椎动物拥有 MAO A/B 的祖先前复制条件。我们的研究结果还在非四足有颌脊椎动物中发现了一个新的家族成员--MAO F。因此,大多数有颌脊椎动物都拥有两个 MAO 基因,即四足类中的 MAO A 和 MAO B,以及非四足类有颌脊椎动物中的 MAO A/B 和 MAO F,它们代表了不同的 MAO 基因谱系。无颌脊椎动物拥有单拷贝基因 MAO A/B/F。对印度-太平洋鲢鱼的MAO重组酶进行的酶学测定显示,MAO A/B和MAO F这两种蛋白质的酶学和分子特性与人类MAO A更为相似,前者的活性率明显高于所有其他MAO酶。我们的分析强调了扫描生命树寻找新基因系的重要性,以了解表型的多样性并详细了解它们的功能。
Evolutionary and Functional Analysis of Monoamine Oxidase F (MAO F): A Novel Member of the MAO Gene Family.
The monoamine oxidase (MAO) gene family encodes for enzymes that perform the oxidative deamination of monoamines, a process required to degrade norepinephrine, serotonin, dopamine, and other amines. While mammalian MAO enzymes, MAO A and MAO B, have been extensively studied, the molecular properties of the other family members are only partly uncovered. This study aims to explore the evolution of monoamine oxidases, emphasizing understanding the MAO gene repertoire among vertebrates. Our analyses show that the duplication that gave rise to MAO A and MAO B occurred in the ancestor of tetrapods, between 408 and 352 million years ago. Non-tetrapod jawed vertebrates possess the ancestral preduplicative condition of MAO A/B. Our results also identified a new family member, MAO F, in non-tetrapod jawed vertebrates. Thus, most jawed vertebrates possess a repertoire of two MAO genes, MAO A and MAO B in tetrapods and MAO A/B and MAO F in non-tetrapod jawed vertebrates, representing different MAO gene lineages. Jawless vertebrates possess the ancestral condition of a single copy gene, MAO A/B/F. Enzymatic assays conducted on the MAO recombinant enzymes of the Indo-Pacific tarpon show that both proteins, MAO A/B and MAO F, have enzymatic and molecular properties more similar to human MAO A, with the former featuring a strikingly higher activity rate when compared to all other MAO enzymes. Our analyses underscore the importance of scanning the tree of life for new gene lineages to understand phenotypic diversity and gain detailed insights into their function.
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About the journal
Genome Biology and Evolution (GBE) publishes leading original research at the interface between evolutionary biology and genomics. Papers considered for publication report novel evolutionary findings that concern natural genome diversity, population genomics, the structure, function, organisation and expression of genomes, comparative genomics, proteomics, and environmental genomic interactions. Major evolutionary insights from the fields of computational biology, structural biology, developmental biology, and cell biology are also considered, as are theoretical advances in the field of genome evolution. GBE’s scope embraces genome-wide evolutionary investigations at all taxonomic levels and for all forms of life — within populations or across domains. Its aims are to further the understanding of genomes in their evolutionary context and further the understanding of evolution from a genome-wide perspective.
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