Abstract
Phosphorothioate (PT) modification by the dnd gene cluster is the first identified DNA backbone modification and constitute an epigenetic system with multiple functions, including antioxidant ability, restriction modification, and virus resistance. Despite these advantages for hosting dnd systems, they are surprisingly distributed sporadically among contemporary prokaryotic genomes. To address this ecological paradox, we systematically investigate the occurrence and phylogeny of dnd systems, and they are suggested to have originated in ancient Cyanobacteria after the Great Oxygenation Event. Interestingly, the occurrence of dnd systems and prophages is significantly negatively correlated. Further, we experimentally confirm that PT modification activates the filamentous phage SW1 by altering the binding affinity of repressor and the transcription level of its encoding gene. Competition assays, concurrent epigenomic and transcriptomic sequencing subsequently show that PT modification affects the expression of a variety of metabolic genes, which reduces the competitive fitness of the marine bacterium Shewanella piezotolerans WP3. Our findings strongly suggest that a series of negative effects on microorganisms caused by dnd systems limit horizontal gene transfer, thus leading to their sporadic distribution. Overall, our study reveals putative evolutionary scenario of the dnd system and provides novel insights into the physiological and ecological influences of PT modification.
Highlights
Phosphorothioate (PT) modification by the dnd gene cluster is the first identified DNA backbone modification and constitute an epigenetic system with multiple functions, including antioxidant ability, restriction modification, and virus resistance
A survey of 230 diverse bacterial and archaeal genomes revealed DNA methylation in 93% of the genomes and identified 1,459 candidate MTase genes, indicating widespread distribution of DNA methylation in prokaryotes[27]. These results revealed an ecological paradox involving this novel DNA modification system: PT modifications confer benefits to microbes, why are dnd systems only sporadically distributed in a limited number of microorganisms? In actuality, this phenomenon was noticed early, and possible explanations have been proposed in that, despite extensive horizontal gene transfer (HGT), the lability of PT-modified DNA under oxidative stress and its susceptibility to PTdependent endonucleases has led to widespread but sporadic distribution of PT modifications in bacteria[9]
The origins of Cyanobacteria can be dated back to 2.7 billion years ago[37], and these organisms have been considered the key players in the Great Oxygenation Event (GOE) on Earth ~2.33 billion years ago[38]
Summary
Phosphorothioate (PT) modification by the dnd gene cluster is the first identified DNA backbone modification and constitute an epigenetic system with multiple functions, including antioxidant ability, restriction modification, and virus resistance. Despite these advantages for hosting dnd systems, they are surprisingly distributed sporadically among contemporary prokaryotic genomes. The dndA, dndC, dndD, dndE genes are essential for PT modification[5]. DndA acts as a cysteine desulfurase and assembles DndC, which is an iron-sulfur cluster protein that has ATP pyrophosphatase activity and is predicted to have PAPS reductase activity[6,7]. Revealed by a co-purification experiment, IscS, DndC, DndD and DndE form a protein complex with the same stoichiometry, and the four proteins assemble into a pipeline according to their gene organization[13]
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