生物
真核生物
新功能化
内共生
水平基因转移
基因
谱系(遗传)
精胺
亚精胺
遗传学
基因复制
系统发育学
亚功能化
生物化学
功能分歧
ATP合酶
原生生物
系统发育树
绿藻
分子进化
酵母
基因家族
进化生物学
酿酒酵母
聚羟基丁酸酯
蛋白质细菌
作者
Bin Li,Jue Liang,Hamid Baniasadi,Margaret A. Phillips,Anthony J. Michael
标识
DOI:10.1016/j.jbc.2025.111028
摘要
The polyamines spermine and thermospermine are differentially distributed throughout eukaryotic phyla. It is unlikely that they were present in the Last Eukaryotic Common Ancestor, thus their biosynthetic enzymes, spermine synthase (SpmSyn) and thermospermine synthase (TspmSyn) emerged during eukaryotic evolution. Herein, we show the different evolutionary mechanisms by which functionally validated SpmSyns and TspmSyns evolved, and their phylogenetic distribution in eukaryotes. Animal lineage SpmSyn was horizontally acquired as a bacterial S-adenosylmethionine decarboxylase-SpmSyn fusion protein before the emergence of the single-celled closest relatives of animals, the Choanoflagellata. SpmSyn has been lost from comb jellies, some sponge species, and was lost from most free-living and parasitic worms. Corals encode two SpmSyn homologs, one of which has evolved into a TspmSyn. In fungi, SpmSyn evolved by gene duplication of spermidine synthase and subsequent neofunctionalization early in the budding yeast Saccharomycotina subphylum. Similarly, the plant SpmSyn evolved by gene duplication of spermidine synthase and then neofunctionalization in lycophytes, coincident with the emergence of vascularization. TspmSyn is found throughout plants and green algae, but lost from wild and domesticated barley. It was likely acquired by endosymbiotic gene transfer from the cyanobacterial ancestor of the chloroplast, although the closest homolog of plant TspmSyn is from the Chloroflexota. TspmSyn homologs evolved into SpmSyns in red algae and into spermidine synthase in glaucophyte algae. Chloroflexota-type TspmSyns are found in many protist phyla, often correlated with secondary endosymbiosis of red or green algae, but were acquired by horizontal gene transfer in phyla that have not possessed algal plastids.
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