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- Title
Bacterial origins of thymidylate metabolism in Asgard archaea and Eukarya.
- Authors
Filée, Jonathan; Becker, Hubert F.; Mellottee, Lucille; Eddine, Rima Zein; Li, Zhihui; Yin, Wenlu; Lambry, Jean-Christophe; Liebl, Ursula; Myllykallio, Hannu
- Abstract
Asgard archaea include the closest known archaeal relatives of eukaryotes. Here, we investigate the evolution and function of Asgard thymidylate synthases and other folate-dependent enzymes required for the biosynthesis of DNA, RNA, amino acids and vitamins, as well as syntrophic amino acid utilization. Phylogenies of Asgard folate-dependent enzymes are consistent with their horizontal transmission from various bacterial groups. We experimentally validate the functionality of thymidylate synthase ThyX of the cultured 'Candidatus Prometheoarchaeum syntrophicum'. The enzyme efficiently uses bacterial-like folates and is inhibited by mycobacterial ThyX inhibitors, even though the majority of experimentally tested archaea are known to use carbon carriers distinct from bacterial folates. Our phylogenetic analyses suggest that the eukaryotic thymidylate synthase, required for de novo DNA synthesis, is not closely related to archaeal enzymes and might have been transferred from bacteria to protoeukaryotes during eukaryogenesis. Altogether, our study suggests that the capacity of eukaryotic cells to duplicate their genetic material is a sum of archaeal (replisome) and bacterial (thymidylate synthase) characteristics. We also propose that recent prevalent lateral gene transfer from bacteria has markedly shaped the metabolism of Asgard archaea. Asgard archaea include the closest known archaeal relatives of eukaryotes. Here, the authors provide evidence that eukaryotic and Asgard thymidylate synthases (required for DNA synthesis) may have a bacterial origin, and additional lateral transfer of bacterial genes may have shaped the metabolism of Asgard archaea.
- Subjects
HORIZONTAL gene transfer; THYMIDYLATE synthase; BACTERIAL transformation; FOLIC acid; ARCHAEBACTERIA; DNA synthesis; BACTERIAL metabolism
- Publication
Nature Communications, 2023, Vol 14, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-023-36487-z