The International Space Station selects for microorganisms adapted to the extreme environment, but does not induce genomic and physiological changes relevant for human health

Mora, Maximilian; Wink, Lisa; I, Kögler; Mahnert, Alexander; Rettberg, Petra; Schwendner, Petra; Demets, R.; Cockell, Charles S.; Alekhova, T. A.; Klingl, Andreas; Alexandrova, A.V.; Moissl-Eichinger, Christine

doi:10.1101/533752

Cited by 4 publications

(9 citation statements)

References 71 publications

(79 reference statements)

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“…From a microbiological point of view, the risk of infection or transfer of antimicrobial resistant pathogens to crew members was found to be extraordinarily low and is thus in agreement with recent information from the ISS [24]. However, although the risk was deemed to be low, the need for monitoring microbial dynamics inside isolated and confined habitats became obvious, in order to understand the impact of special events like the contamination caused by the composting toilet.…”

Section: Discussionsupporting

confidence: 82%

“…Moreover, baselines of the microbiome inside the habitat, its crew and post sampling events would greatly improve evaluations of the impact of confinement on the crew and habitat surfaces. Most comparable studies, either ground-based like Mars500 [41,105] or in space aboard the ISS [24,89,106], showed a similar picture of longitudinal homogenization, composition and diversity of microbiomes.…”

Section: Discussionmentioning

confidence: 78%

“…However, the potential to form biofilms showed a constant maximum in samples retrieved from the kitchen floor (global median 0.18, maximum 0.27, cumulative average decrease/increase -0.25/0. 24) and anaerobes were increasing on the toilet bowl (minimum 0.06, maximum 0.21) while decreasing on human skin (0.02 to 0.01). Interestingly, potential pathogens showed an anticyclic pattern of samples from the built environment versus samples from the crew (Fig.…”

mentioning

confidence: 93%

“…Technophiles were found onboard the Mir station [22,23] and onboard the ISS [13,19,24], leading to damage of various systems [25,26]. Second, microbial contaminants could interfere with biological life-support systems [27] which could greatly contribute to the feasibility of long-term missions on the Moon or Mars [28][29][30] by harming the system-relevant organisms through competition and/or toxicity or by making food products unsuitable for crew consumption.…”

Section: Introductionmentioning

confidence: 99%

“…In any case, microbial communities will be critical components of future space endeavors, with a potentially large influence on mission success [35]. Their importance is reflected in space agencies' efforts to characterize them onboard the ISS [13,19,24,[36][37][38][39][40].…”

Section: Introductionmentioning

confidence: 99%

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Microbiome dynamics during the HI-SEAS IV mission, and implications for future crewed missions beyond Earth

Mahnert

Verseux

Schwendner

et al. 2020

Preprint

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BackgroundHuman health is closely interconnected with its microbiome. Stable microbiomes in, on and around the human body will be key for safe and successful long-term space travel. However, longitudinal dynamics of microbiomes inside confined built environments are still poorly understood. Herein we used the Hawaii Space Exploration Analog and Simulation IV (HI-SEAS IV) mission, a one year-long isolation study, to investigate microbial transfer between crew and habitat, in order to understand adverse developments which might occur in an outpost on the Moon or Mars in the future.ResultsLongitudinal profiles of the 16S rRNA gene revealed significant differences in microbial diversity and composition between samples of the built environment and its crew. While microbial profiles from individual crew members were highly dynamic, the microbiome on built environment surfaces remained more stable. Especially within the first 200 days, archaeal signatures of Methanobrevibacter were regularly transferred between crew members, but did not impact the microbiome on habitat surfaces. In contrast to a rather stable microbial diversity recovered from surfaces of the habitat, microbial diversity from the crew’s skin increased over time. Quantitative observations based on qPCR supported observations of dissimilarity between the built environment and its crew and was also used to track the propagation of antimicrobial resistances in the habitat. Together with functional and phenotypic predictions, quantitative and qualitative data both supported the observation of a delayed longitudinal homogenization between the crew and their habitat, that was mainly caused by the hygiene infrastructure.ConclusionsThe study highlights main routes of microbial transfer, interaction of its crew and origins of microbial dynamics in an isolated set-up. We identified key targets of microbial monitoring, and emphasize the need for defined baselines of microbiome diversity and abundance on surfaces and skin. Targeted manipulation to counteract adverse developments of the microbiome will be a highly important strategy to ensure safety during future space endeavors.

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Section: Discussionsupporting

confidence: 82%

Section: Discussionmentioning

confidence: 78%

mentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Microbiome dynamics during the HI-SEAS IV mission, and implications for future crewed missions beyond Earth

Mahnert

Verseux

Schwendner

et al. 2020

Preprint

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Initial attempt: Design and application of microorganism-material interaction test on On-orbit space microgravity conditions

Zhang,

Chen,

Yuan

et al. 2025

Acta Astronautica

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Multi-faceted metagenomic analysis of spacecraft associated surfaces reveal planetary protection relevant microbial composition

et al. 2023

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The National Aeronautics and Space Administration (NASA) has been monitoring the microbial burden of spacecraft since the 1970’s Viking missions. Originally culture-based and then focused 16S sequencing techniques were used, but we have now applied whole metagenomic sequencing to a variety of cleanroom samples at the Jet Propulsion Lab (JPL), including the Spacecraft Assembly Facility (SAF) with the goals of taxonomic identification and for functional assignment. Our samples included facility pre-filters, cleanroom vacuum debris, and surface wipes. The taxonomic composition was carried out by three different analysis tools to contrast marker, k-mer, and true alignment approaches. Hierarchical clustering analysis of the data separated vacuum particles from other SAF DNA samples. Vacuum particle samples were the most diverse while DNA samples from the ISO (International Standards Organization) compliant facilities and the SAF were the least diverse; all three were dominated by Proteobacteria. Wipe samples had higher diversity and were predominated by Actinobacteria, including human commensals Cutibacterium acnes and Corynebacterium spp. Taxa identified by the three methods were not identical, supporting the use of multiple methods for metagenome characterization. Likewise, functional annotation was performed using multiple methods. Vacuum particles and SAF samples contained strong signals of the tricarboxylic acid cycle and of amino acid biosynthesis, suggesting that many of the identified microorganisms have the ability to grow in nutrient-limited environments. In total, 18 samples generated high quality metagenome assembled genomes (MAG), which were dominated by Moraxella osloensis or Malassezia restricta. One M. osloensis MAG was assembled into a single circular scaffold and gene annotated. This study includes a rigorous quantitative determination of microbial loads and a qualitative dissection of microbial composition. Assembly of multiple specimens led to greater confidence for the identification of particular species and their predicted functional roles.

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The International Space Station selects for microorganisms adapted to the extreme environment, but does not induce genomic and physiological changes relevant for human health

Cited by 4 publications

References 71 publications

Microbiome dynamics during the HI-SEAS IV mission, and implications for future crewed missions beyond Earth

Microbiome dynamics during the HI-SEAS IV mission, and implications for future crewed missions beyond Earth

Initial attempt: Design and application of microorganism-material interaction test on On-orbit space microgravity conditions

Multi-faceted metagenomic analysis of spacecraft associated surfaces reveal planetary protection relevant microbial composition

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