TY - JOUR T1 - Large Freshwater Phages with the Potential to Augment Aerobic Methane Oxidation JF - bioRxiv DO - 10.1101/2020.02.13.942896 SP - 2020.02.13.942896 AU - Lin-Xing Chen AU - Raphaël Méheust AU - Alexander Crits-Christoph AU - Katherine D. McMahon AU - Tara Colenbrander Nelson AU - Lesley A. Warren AU - Jillian F. Banfield Y1 - 2020/01/01 UR - http://biorxiv.org/content/early/2020/02/14/2020.02.13.942896.abstract N2 - There is growing evidence that phages with unusually large genomes are common across various natural and human microbiomes, but little is known about their genetic inventories or potential ecosystem impacts. Here, we reconstructed large phage genomes from freshwater lakes known to contain bacteria that oxidize methane. Twenty-two manually curated genomes (18 are complete) ranging from 159 to 527 kbp in length were found to encode the pmoC gene, an enzymatically critical subunit of the particulate methane monooxygenase, the predominant methane oxidation catalyst in nature. The phage-associated PmoC show high similarity (> 90%) and affiliate phylogenetically with those of coexisting bacterial methanotrophs, and their abundance patterns correlate with the abundances of these bacteria, supporting host-phage relationships. We suggest that phage PmoC has similar functions to additional copies of PmoC encoded in bacterial genomes, thus contribute to growth on methane. Transcriptomics data from one system showed that the phage-associated pmoC genes are actively expressed in situ. Augmentation of bacterial methane oxidation by pmoC-phages during infection could modulate the efflux of this powerful greenhouse gas into the environment. ER -