The loach haplotype-resolved genome and the identification of Mex3a involved in fish air breathing.

IF 11.1 Q1 CELL BIOLOGY Cell genomics Pub Date : 2024-10-09 DOI:10.1016/j.xgen.2024.100670
Bing Sun, Qingshan Li, Xinxin Xiao, Jianwei Zhang, Ying Zhou, Yuwei Huang, Jian Gao, Xiaojuan Cao
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Abstract

Fish air breathing is crucial for the transition of vertebrates from water to land. So far, the genes involved in fish air breathing have not been well identified. Here, we performed gene enrichment analysis of positively selected genes (PSGs) in loach (Misgurnus anguillicaudatus, an air-breathing fish) in comparison to Triplophysa tibetana (a non-air-breathing fish), haplotype-resolved genome assembly of the loach, and gene evolutionary analysis of air-breathing and non-air-breathing fishes and found that the PSG mex3a originated from ancient air-breathing fish species. Deletion of Mex3a impaired loach air-breathing capacity by inhibiting angiogenesis through its interaction with T-box transcription factor 20. Mex3a overexpression significantly promoted angiogenesis. Structural analysis and point mutation revealed the critical role of the 201st amino acid in loach Mex3a for angiogenesis. Our findings innovatively indicate that the ancient mex3a is a fish air-breathing gene, which holds significance for understanding fish air breathing and provides a valuable resource for cultivating hypoxia-tolerant fish varieties.

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泥鳅单倍型基因组和参与鱼类空气呼吸的 Mex3a 的鉴定。
鱼类的空气呼吸对于脊椎动物从水中过渡到陆地至关重要。迄今为止,参与鱼类空气呼吸的基因尚未得到很好的鉴定。在此,我们对泥鳅(Misgurnus anguillicaudatus,一种呼吸空气的鱼类)与非呼吸空气的鱼类西藏鳅(Triplophysa tibetana)进行了正选基因(PSGs)富集分析、泥鳅单倍型解析基因组组装以及呼吸空气和非呼吸空气鱼类的基因进化分析,发现PSG mex3a起源于古代呼吸空气的鱼类物种。缺失Mex3a会通过与T-box转录因子20的相互作用抑制血管生成,从而削弱泥鳅的呼吸空气能力。过表达 Mex3a 则会显著促进血管生成。结构分析和点突变揭示了泥鳅Mex3a中第201个氨基酸对血管生成的关键作用。我们的研究结果创新性地表明,古老的mex3a是一种鱼类呼吸空气的基因,这对理解鱼类呼吸空气具有重要意义,并为培育耐缺氧鱼类品种提供了宝贵的资源。
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