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Microbial adaptation to spaceflight is correlated with bacteriophage-encoded functions

Iris Irby, Jared T. Broddrick

2024Nature Communications15 citationsDOIOpen Access PDF

Abstract

Evidence from the International Space Station suggests microbial populations are rapidly adapting to the spacecraft environment; however, the mechanism of this adaptation is not understood. Bacteriophages are prolific mediators of bacterial adaptation on Earth. Here we survey 245 genomes sequenced from bacterial strains isolated on the International Space Station for dormant (lysogenic) bacteriophages. Our analysis indicates phage-associated genes are significantly different between spaceflight strains and their terrestrial counterparts. In addition, we identify 283 complete prophages, those that could initiate bacterial lysis and infect additional hosts, of which 21% are novel. These prophage regions encode functions that correlate with increased persistence in extreme environments, such as spaceflight, to include antimicrobial resistance and virulence, DNA damage repair, and dormancy. Our results correlate microbial adaptation in spaceflight to bacteriophage-encoded functions that may impact human health in spaceflight.

Topics & Concepts

Lysogenic cycleProphageSpaceflightBacteriophageBiologyAdaptation (eye)GenomeGeneticsVirulenceGeneMicrobiologyEscherichia coliEngineeringAerospace engineeringNeuroscienceBacteriophages and microbial interactionsMicrobial Community Ecology and PhysiologyPolar Research and Ecology