Extremeophiles and Extreme Environments

The Genetic Determinants of Extreme UV Radiation and Desiccation Tolerance in a Bacterium Recovered from the Stratosphere

By Keith Cowing

Status Report

Microorganisms

June 15, 2026

Filed under Actinobacteria, catalase, Curtobacterium aetherium, dessication, DNA, genomics, helicase, Microorganisms, Microorganisms via PubMed, photolyase, radiation, stratosphere, ultraviolet radiation, UVR resistance

The Genetic Determinants of Extreme UV Radiation and Desiccation Tolerance in a Bacterium Recovered from the Stratosphere — The DNA repair and ROS detoxification genes in the Curtobacterium aetherium L6-1 genome not found in strain DSM 20129.The genomes were compared using the BLAST Ring Image Generator (BRIG) with the blastp algorithm. The rings represent the following (from innermost to outermost): ① GC content, ② GC skew of the L6-1 genome, ③ percent identity to L6-1 of the protein orthologs found in strain DSM 20129, and ④ DNA repair (black) and ROS detoxification (gray) genes. The genes present in L6-1 but absent in DSM 20129 are indicated in red. — Microorganisms

Microbes that survive transport to and in the stratosphere endure extremes of low temperature, atmospheric pressure, and relative humidity, as well as high fluxes in ultraviolet radiation (UVR).

The high atmosphere thus provides an ideal environment to explore the genetic and physiological determinants conveying high tolerance to desiccation and UVR. In this study, we examined Curtobacterium aetherium L6-1, an actinobacterium obtained from stratospheric aerosol sampling that displays high resistance to desiccation and UVR. We found that its phylogenetic relatives are resistant to desiccation, but only C. aetherium displayed a high tolerance to UVR.

Comparative genome analysis and directed evolution experiments implicated genes encoding photolyase, DNA nucleases and helicases, and catalases as responsible for UVR resistance in C. aetherium. Differential gene expression analysis revealed the upregulation of DNA repair and stress response mechanisms when cells were exposed to UVR, while genes encoding sugar transporters, sugar metabolism enzymes, and antioxidants were induced upon desiccation.

Based on changes in gene expression as a function of water content, C. aetherium can modulate its metabolism through transcriptional regulation at very low moisture levels (Xw < 0.25 g H₂O per gram dry weight). Uncovering the genetic underpinnings of desiccation and UVR resistance in C. aetherium provides new insights into how bacterial DNA repair and antioxidant mechanisms function to exhibit traits at the extreme ends of phenotypic distributions.

The Genetic Determinants of Extreme UV Radiation and Desiccation Tolerance in a Bacterium Recovered from the Stratosphere, Microorganisms (open access)

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Keith Cowing

Biologist, Explorers Club Fellow, ex-NASA Space Biologist and Payload integrator, Editor of NASAWatch.com and Astrobiology.com, Lapsed climber, Explorer, Synaesthete, Former Challenger Center board member 🖖🏻

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