Frontiers in Microbiology (Jun 2020)

Fitness of Outer Membrane Vesicles From Komagataeibacter intermedius Is Altered Under the Impact of Simulated Mars-like Stressors Outside the International Space Station

  • Olga Podolich,
  • Olga Kukharenko,
  • Iryna Zaets,
  • Iryna Orlovska,
  • Larysa Palchykovska,
  • Leonid Zaika,
  • Serhii Sysoliatin,
  • Ganna Zubova,
  • Oleg Reva,
  • Maxym Galkin,
  • Tetyana Horid’ko,
  • Halyna Kosiakova,
  • Tatiana Borisova,
  • Volodymyr Kravchenko,
  • Mykola Skoryk,
  • Maxym Kremenskoy,
  • Preetam Ghosh,
  • Debmalya Barh,
  • Aristóteles Góes-Neto,
  • Vasco Azevedo,
  • Jean-Pierre de Vera,
  • Natalia Kozyrovska

DOI
https://doi.org/10.3389/fmicb.2020.01268
Journal volume & issue
Vol. 11

Abstract

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Outer membrane vesicles (OMVs), produced by nonpathogenic Gram-negative bacteria, have potentially useful biotechnological applications in extraterrestrial extreme environments. However, their biological effects under the impact of various stressors have to be elucidated for safety reasons. In the spaceflight experiment, model biofilm kombucha microbial community (KMC) samples, in which Komagataeibacter intermedius was a dominant community-member, were exposed under simulated Martian factors (i.e., pressure, atmosphere, and UV-illumination) outside the International Space Station (ISS) for 1.5 years. In this study, we have determined that OMVs from post-flight K. intermedius displayed changes in membrane composition, depending on the location of the samples and some other factors. Membrane lipids such as sterols, fatty acids (FAs), and phospholipids (PLs) were modulated under the Mars-like stressors, and saturated FAs, as well as both short-chain saturated and trans FAs, appeared in the membranes of OMVs shed by both post-UV-illuminated and “dark” bacteria. The relative content of zwitterionic and anionic PLs changed, producing a change in surface properties of outer membranes, thereby resulting in a loss of interaction capability with polynucleotides. The changed composition of membranes promoted a bigger OMV size, which correlated with changes of OMV fitness. Biochemical characterization of the membrane-associated enzymes revealed an increase in their activity (DNAse, dehydrogenase) compared to wild type. Other functional membrane-associated capabilities of OMVs (e.g., proton accumulation, interaction with linear DNA, or synaptosomes) were also altered after exposure to the spaceflight stressors. Despite alterations in membranes, vesicles did not acquire endotoxicity, cytotoxicity, and neurotoxicity. Altogether, our results show that OMVs, originating from rationally selected nonpathogenic Gram-negative bacteria, can be considered as candidates in the design of postbiotics or edible mucosal vaccines for in situ production in extreme environment. Furthermore, these OMVs could also be used as promising delivery vectors for applications in Astromedicine.

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