Your search keyword '"Lisa Wink"' showing total 7 results

1. Taxonomic and functional analyses of intact microbial communities thriving in extreme, astrobiology-relevant, anoxic sites

Author

Jens Strauss, Mustapha Malki, Ricardo Amils, Pascale Ehrenfreund, Armin Erlacher, Viggó Þór Marteinsson, Alexander Mahnert, Frances Westall, Christine Moissl-Eichinger, E. Monaghan, George Tanski, F. Gaboyer, Lisa Wink, Alexandra Kristin Bashir, Elke Rabbow, Mina Bashir, L. Garcia-Descalzo, Andreas Riedo, Pauline Vannier, Stefanie Duller, Kristina Beblo-Vranesevic, Petra Schwendner, Charles S. Cockell, Petra Rettberg, Nicolas Walter, Maria Bohmeier, Patricia Cabezas, Felipe Gómez, UAM. Departamento de Biología Molecular, European Commission, Swiss National Science Foundation, Moissi Eichinger, C. [0000-0001-6755-6263], European Commission (EC), and Swiss National Science Foundation (SNSF)

Subjects

Microbiology (medical), Microbiology, lcsh:Microbial ecology, Strahlenbiologie, Extremophiles, 03 medical and health sciences, Microbial ecology, Spaceanalogue, Exobiology, Extreme environment, Extremophile, Extraterrestrial life, Microbiome, Anaerobiosis, 030304 developmental biology, 0303 health sciences, biology, Bacteria, 030306 microbiology, Ecology, Research, Microbiota, Microbiomes, Space-analogue, Extreme environments, 15. Life on land, biology.organism_classification, Biología y Biomedicina / Biología, Astrobiology, Anoxic waters, Archaea, Propidium monoazide, Microbial population biology, 13. Climate action, Metagenomics, Space Analogue, Metagenome, lcsh:QR100-130

Abstract

Artículo escrito por un elevado número de autores, solo se referencian el que aparece en primer lugar, el nombre del grupo de colaboración, si le hubiere, y los autores pertenecientes a la UAM, Background: Extreme terrestrial, analogue environments are widely used models to study the limits of life and to infer habitability of extraterrestrial settings. In contrast to Earth’s ecosystems, potential extraterrestrial biotopes are usually characterized by a lack of oxygen. Methods: In the MASE project (Mars Analogues for Space Exploration), we selected representative anoxic analogue environments (permafrost, salt-mine, acidic lake and river, sulfur springs) for the comprehensive analysis of their microbial communities. We assessed the microbiome profile of intact cells by propidium monoazide-based amplicon and shotgun metagenome sequencing, supplemented with an extensive cultivation effort. Results: The information retrieved from microbiome analyses on the intact microbial community thriving in the MASE sites, together with the isolation of 31 model microorganisms and successful binning of 15 high-quality genomes allowed us to observe principle pathways, which pinpoint specific microbial functions in the MASE sites compared to moderate environments. The microorganisms were characterized by an impressive machinery to withstand physical and chemical pressures. All levels of our analyses revealed the strong and omnipresent dependency of the microbial communities on complex organic matter. Moreover, we identified an extremotolerant cosmopolitan group of 34 poly-extremophiles thriving in all sites. Conclusions: Our results reveal the presence of a core microbiome and microbial taxonomic similarities between saline and acidic anoxic environments. Our work further emphasizes the importance of the environmental, terrestrial parameters for the functionality of a microbial community, but also reveals a high proportion of living microorganisms in extreme environments with a high adaptation potential within habitability borders. Keywords: Extreme environments, Microbiomes, Archaea, Bacteria, Propidium monoazide, Astrobiology, Spaceanalogue, Extremophiles, Extraterrestrial life, Metagenomics

Published

2021

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

Author

Christina Kumpitsch, Lisa Wink, Theodora Goessler, Marcus Blohs, Kaisa Koskinen, Cyprien Verseux, Daniela Billi, Petra Schwendner, Christine Moissl-Eichinger, Alexander Mahnert, and Daniela Brunner

Subjects

Microbiology (medical), Adult, Male, Extraterrestrial Environment, Settore BIO/01, Crew, Biology, Microbiology, lcsh:Microbial ecology, Space exploration, Hawaii, Isolation, 03 medical and health sciences, Microbial ecology, Abundance (ecology), RNA, Ribosomal, 16S, Humans, Microbiome, Built Environment, Spacecraft, Built environment, 030304 developmental biology, Skin, Indoor microbiome, 0303 health sciences, HI-SEAS, 030306 microbiology, Ecology, Research, Phenotype predictions, Microbiota, technology, industry, and agriculture, 16S rRNA gene amplicons, Space Flight, Antimicrobial resistances, qPCR, Habitat, Confined built environments, 13. Climate action, Indicator species, Skin microbiome, Longitudinal, lcsh:QR100-130, Astronauts, Female

Abstract

Background Human health is closely interconnected with its microbiome. Resilient 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 1 year-long isolation study, to investigate microbial transfer between crew and habitat, in order to understand adverse developments which may occur in a future outpost on the Moon or Mars. Results Longitudinal 16S rRNA gene profiles, as well as quantitative observations, revealed significant differences in microbial diversity, abundance, and composition between samples of the built environment and its crew. The microbiome composition and diversity associated with abiotic surfaces was found to be rather stable, whereas the microbial skin profiles of individual crew members were highly dynamic, resulting in an increased microbiome diversity at the end of the isolation period. The skin microbiome dynamics were especially pronounced by a regular transfer of the indicator species Methanobrevibacter between crew members within the first 200 days. Quantitative information was used to track the propagation of antimicrobial resistance in the habitat. Together with functional and phenotypic predictions, quantitative and qualitative data supported the observation of a delayed longitudinal microbial homogenization between crew and habitat surfaces which was mainly caused by a malfunctioning sanitary facility. Conclusions This study highlights main routes of microbial transfer, interaction of the crew, and origins of microbial dynamics in an isolated environment. We identify key targets of microbial monitoring, and emphasize the need for defined baselines of microbiome diversity and abundance on surfaces and crew skin. Targeted manipulation to counteract adverse developments of the microbiome could be a highly important strategy to ensure safety during future space endeavors.

Published

2021

3. Microbial biodiversity assessment of the European Space Agency’s ExoMars 2016 mission

Author

Rüdiger Pukall, Anna K. Auerbach, A. Perras, Lisa Wink, Kaisa Koskinen, Alexander Mahnert, Petra Rettberg, Diana Beatriz Margheritis, Gerhard Kminek, Christine Moissl-Eichinger, and Simon Barczyk

Subjects

0301 basic medicine, Microbiology (medical), Planetary protection, Microbial diversity, 030106 microbiology, Microbial contamination, Biology, Real-Time Polymerase Chain Reaction, Microbiology, lcsh:Microbial ecology, Bioburden, 03 medical and health sciences, Strahlenbiologie, Microbiological contamination, Cleanroom, RNA, Ribosomal, 16S, Exobiology, Humans, Cleanroom microbiota, Spacecraft, Life detection, Bacteria, Ecology, Microbiota, Research, Life-detection, High-Throughput Nucleotide Sequencing, Biodiversity, Space Flight, Environment, Controlled, Astrobiology, Archaea, ExoMars, Europe, 030104 developmental biology, Microbial biodiversity, Italy, Systems engineering, Equipment Contamination, lcsh:QR100-130, Transcriptome

Abstract

Background The ExoMars 2016 mission, consisting of the Trace Gas Orbiter and the Schiaparelli lander, was launched on March 14 2016 from Baikonur, Kazakhstan and reached its destination in October 2016. The Schiaparelli lander was subject to strict requirements for microbial cleanliness according to the obligatory planetary protection policy. To reach the required cleanliness, the ExoMars 2016 flight hardware was assembled in a newly built, biocontrolled cleanroom complex at Thales Alenia Space in Turin, Italy. In this study, we performed microbiological surveys of the cleanroom facilities and the spacecraft hardware before and during the assembly, integration and testing (AIT) activities. Methods Besides the European Space Agency (ESA) standard bioburden assay, that served as a proxy for the microbiological contamination in general, we performed various alternative cultivation assays and utilised molecular techniques, including quantitative PCR and next generation sequencing, to assess the absolute and relative abundance and broadest diversity of microorganisms and their signatures in the cleanroom and on the spacecraft hardware. Results Our results show that the bioburden, detected microbial contamination and microbial diversity decreased continuously after the cleanroom was decontaminated with more effective cleaning agents and during the ongoing AIT. The studied cleanrooms and change room were occupied by very distinct microbial communities: Overall, the change room harboured a higher number and diversity of microorganisms, including Propionibacterium, which was found to be significantly increased in the change room. In particular, the so called alternative cultivation assays proved important in detecting a broader cultivable diversity than covered by the standard bioburden assay and thus completed the picture on the cleanroom microbiota. Conclusion During the whole project, the bioburden stayed at acceptable level and did not raise any concern for the ExoMars 2016 mission. The cleanroom complex at Thales Alenia Space in Turin is an excellent example of how efficient microbiological control is performed. Electronic supplementary material The online version of this article (10.1186/s40168-017-0358-3) contains supplementary material, which is available to authorized users.

Published

2017

4. Space Station conditions are selective but do not alter microbial characteristics relevant to human health

Author

T. A. Alekhova, Charles S. Cockell, Lisa Wink, Anna Zolotariof, Robert Krause, Petra Schwendner, Petra Rettberg, Alexander Mahnert, Andreas Klingl, Maximilian Mora, Christine Moissl-Eichinger, Ines Kögler, René Demets, and Alina Alexandrova

Subjects

0301 basic medicine, Science, health care facilities, manpower, and services, Microbial diversity, education, Biodiversity, microbial communities, General Physics and Astronomy, 02 engineering and technology, Biology, human health, Article, General Biochemistry, Genetics and Molecular Biology, Strahlenbiologie, Extremophiles, 03 medical and health sciences, Human health, RNA, Ribosomal, 16S, Humans, Extremophile, Microbiome, lcsh:Science, Phylogeny, Multidisciplinary, Bacteria, Host Microbial Interactions, Environmental microbiology, Resistance (ecology), ISS, Ecology, Microbiota, Fungi, General Chemistry, Space Flight, 021001 nanoscience & nanotechnology, Archaea, 030104 developmental biology, Health, 13. Climate action, Metagenomics, Biofilms, lcsh:Q, 0210 nano-technology, human activities

Abstract

The International Space Station (ISS) is a unique habitat for humans and microorganisms. Here, we report the results of the ISS experiment EXTREMOPHILES, including the analysis of microbial communities from several areas aboard at three time points. We assess microbial diversity, distribution, functional capacity and resistance profile using a combination of cultivation-independent analyses (amplicon and shot-gun sequencing) and cultivation-dependent analyses (physiological and genetic characterization of microbial isolates, antibiotic resistance tests, co-incubation experiments). We show that the ISS microbial communities are highly similar to those present in ground-based confined indoor environments and are subject to fluctuations, although a core microbiome persists over time and locations. The genomic and physiological features selected by ISS conditions do not appear to be directly relevant to human health, although adaptations towards biofilm formation and surface interactions were observed. Our results do not raise direct reason for concern with respect to crew health, but indicate a potential threat towards material integrity in moist areas., The International Space Station is a unique habitat for humans and microbes. Here, Mora et al. analyze microbial communities from several areas aboard, finding similarities with those of ground-based indoor environments, as well as adaptations towards biofilm formation but not necessarily relevant to human health.

Published

2019

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

Author

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

Subjects

Human health, Ecology, Metagenomics, health services administration, health care facilities, manpower, and services, Microorganism, International Space Station, Biofilm, Extreme environment, Extremophile, Microbiome, Biology, human activities

Abstract

The International Space Station (ISS) is a unique, completely confined habitat for the human crew and co-inhabiting microorganisms. Here, we report on the results of the ISS experiment “EXTREMOPHILES”. We aimed to exploit the microbial information obtained from three surface and air sampling events aboard the International Space Station during increments 51 and 52 (2017) with respect to: i) microbial sources, diversity and distribution within the ISS, ii) functional capacity of microbiome and microbial isolates, iii) extremotolerance and antibiotics-resistance (compared to ground controls), and iv) microbial behavior towards ISS-relevant materials such as biofilm formation, or potential for degradation. We used wipe samples and analyzed them by amplicon and metagenomics sequencing, cultivation, comparative physiological studies, antibiotic resistance tests, genome analysis of isolates and co-incubation experiments with ISS-relevant materials. The major findings were: i) the ISS microbiome profile is highly similar to ground-based confined indoor environments, ii) the ISS microbiome is subject to fluctuations and indicative for the (functional) location, although a core microbiome was present over time and independent from location, iii) the ISS selects for microorganisms adapted to the extreme environment, but does not necessarily induce genomic and physiological changes which might be relevant for human health, iv) cleanrooms and cargo seems to be a minor source of microbial contamination aboard, and v) microorganisms can attach to and grow on ISS-relevant materials. Biofilm formation might be a threat for spacecraft materials with the potential to induce instrument malfunctioning with consequences for mission success. We conclude that our data do not raise direct reason for concern with respect to crew health, but indicate a potential threat towards biofilm formation and material integrity in moist areas.

Published

2019

6. Dead or Alive? Molecular life-dead distinction in human stool samples reveals significantly different composition of the microbial community

Author

Michael Beck, Kaisa Koskinen, Maximilian Mora, Christine Moissl-Eichinger, A. Perras, and Lisa Wink

Subjects

Microbial population biology, biology, Propidium monoazide, Microorganism, Akkermansia, Microbiome, Amplicon, Bacteroides, 16S ribosomal RNA, biology.organism_classification, Microbiology

Abstract

The gut microbiome is strongly interwoven with human health. Conventional gut microbiome analysis generally involves 16S rRNA gene targeting next generation sequencing (NGS) of stool microbial communities, and correlation of results with clinical parameters. However, some microorganisms may not be alive at the time of sampling, and thus their impact on the human health is potentially less significant. As conventional NGS methods do not differentiate between viable and dead microbial components, retrieved results provide only limited information.Propidium monoazide (PMA) is frequently used in food safety monitoring and other disciplines to discriminate living from dead cells. PMA binds to free DNA and masks it for subsequent procedures. In this article we show the impact of PMA on the results of 16S rRNA gene-targeting NGS from human stool samples and validate the optimal applicable concentration to achieve a reliable detection of the living microbial communities.Fresh stool samples were treated with a concentration series of zero to 300 μM PMA, and were subsequently subjected to amplicon-based NGS. The results indicate that a substantial proportion of the human microbial community is not intact at the time of sampling. PMA treatment significantly reduced the diversity and richness of the sample depending on the concentration and impacted the relative abundance of certain important microorganisms (e.g. Akkermansia, Bacteroides). Overall, we found that a concentration of 100 μM PMA was sufficient to quench signals from disrupted microbial cells.The optimized protocol proposed here can be easily implemented in classical microbiome analyses, and helps to retrieve an improved and less blurry picture of the microbial community composition by excluding signals from background DNA.

Published

2018

7. Resilient microorganisms in dust samples of the International Space Station-survival of the adaptation specialists

Author

T. A. Alekhova, Lisa Wink, Maximilian Mora, Tatiana Novozhilova, Christine Moissl-Eichinger, Alina Aleksandrova, Robert Krause, and A. Perras

Subjects

0301 basic medicine, Microbiology (medical), Microorganism, Acclimatization, Microbial Sensitivity Tests, Extremotolerant, Microbiology, International Space Station, Confined habitat, 03 medical and health sciences, Extremophiles, Microbial ecology, RNA, Ribosomal, 16S, Extremophile, Humans, Microbiome, Desiccation, Spacecraft, biology, Bacteria, Weightlessness, Microbiota, Research, High-Throughput Nucleotide Sequencing, Dust, Space Flight, 16S ribosomal RNA, biology.organism_classification, Archaea, 030104 developmental biology, Microbial population biology, Extreme Environments

Abstract

Background The International Space Station (ISS) represents a unique biotope for the human crew but also for introduced microorganisms. Microbes experience selective pressures such as microgravity, desiccation, poor nutrient-availability due to cleaning, and an increased radiation level. We hypothesized that the microbial community inside the ISS is modified by adapting to these stresses. For this reason, we analyzed 8–12 years old dust samples from Russian ISS modules with major focus on the long-time surviving portion of the microbial community. We consequently assessed the cultivable microbiota of these samples in order to analyze their extremotolerant potential against desiccation, heat-shock, and clinically relevant antibiotics. In addition, we studied the bacterial and archaeal communities from the stored Russian dust samples via molecular methods (next-generation sequencing, NGS) and compared our new data with previously derived information from the US American ISS dust microbiome. Results We cultivated and identified in total 85 bacterial, non-pathogenic isolates (17 different species) and 1 fungal isolate from the 8–12 year old dust samples collected in the Russian segment of the ISS. Most of these isolates exhibited robust resistance against heat-shock and clinically relevant antibiotics. Microbial 16S rRNA gene and archaeal 16S rRNA gene targeting Next Generation Sequencing showed signatures of human-associated microorganisms (Corynebacterium, Staphylococcus, Coprococcus etc.), but also specifically adapted extremotolerant microorganisms. Besides bacteria, the detection of archaeal signatures in higher abundance was striking. Conclusions Our findings reveal (i) the occurrence of living, hardy microorganisms in archived Russian ISS dust samples, (ii) a profound resistance capacity of ISS microorganisms against environmental stresses, and (iii) the presence of archaeal signatures on board. In addition, we found indications that the microbial community in the Russian segment dust samples was different to recently reported US American ISS microbiota. Electronic supplementary material The online version of this article (doi:10.1186/s40168-016-0217-7) contains supplementary material, which is available to authorized users.

Published

2016