A New Niche for Life at Low G

[BillTre]

Microgravity reshapes bacteriophage–host coevolution aboard the International Space Station

Abstract:

Bacteriophage–host interactions play a fundamental role in shaping microbial ecosystems. While extensively studied on Earth, their behavior in microgravity remains largely unexplored. Here, we report the dynamics between T7 bacteriophage and Escherichia coli in microgravity aboard the International Space Station (ISS). Phage activity was initially delayed in microgravity but ultimately successful. We identified de novo mutations in both phage and bacteria that enhanced fitness in microgravity. Deep mutational scanning of the phage receptor binding domain revealed striking differences in the number, position, and mutational preferences between terrestrial and microgravity conditions, reflecting underlying differences in bacterial adaptation. Combinatorial libraries informed by microgravity selections yielded T7 variants capable of productively infecting uropathogenic E. coli resistant to wild-type T7 under terrestrial conditions. These findings help lay the foundation for future research on the impact of microgravity on phage–host interactions and microbial communities and the terrestrial benefits of this research.

This uses well developed research organisms (E. coli and the T7 phage). Many molecular details are known about their functions. Entire genetic sequences are already known for these guys (with small genomes), so figuring out molecular changes is simplified. Changes were found in the T7 phage (virus)) a receptor that binds an E. coli surface protein. This is the first step in successfully infecting a cell.

A possible scenario might be:
Things are different out there in space. Different traits will be selected for.
They will be better adapted to that environment over time and will therefore thrive there. This depends upon a long continuous existence of their particular low G environment.