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[1]
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Into the unknown: Microbial communities in caves, their role, and potential use
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Kwaśnicka, P Golec, W Jaroszewicz… - Microorganisms,
2022 |
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[2]
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Bridging the gap between microbial limits and extremes in space: space microbial biotechnology in the next 15 years
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Microbial Biotechnology,
2022 |
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[3]
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Lithic cyanobacterial communities in the polyextreme Sahara Desert: Implications for the search for the limits of life
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Environmental …,
2022 |
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[4]
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Absence of increased genomic variants in the cyanobacterium Chroococcidiopsis exposed to Mars-like conditions outside the space station
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Scientific Reports,
2022 |
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[5]
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Super-Earths, M Dwarfs, and Photosynthetic Organisms: Habitability in the Lab
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2021 |
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[6]
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Survival of desert algae Chlorella exposed to Mars-like near space environment
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2021 |
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[7]
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Biofilms in caves: easy method for the assessment of dominant phototrophic groups/taxa in situ
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2020 |
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[8]
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Mimicking the Martian Hydrological Cycle: A Set-Up to Introduce Liquid Water in Vacuum
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2020 |
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[9]
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A new remote sensing-based system for the monitoring and analysis of growth and gas exchange rates of photosynthetic microorganisms under simulated …
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2020 |
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[10]
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Two new ene-reductases from photosynthetic extremophiles enlarge the panel of old yellow enzymes: CtOYE and GsOYE
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2020 |
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[11]
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Loss of Filamentous Multicellularity in Cyanobacteria: the Extremophile Gloeocapsopsis sp. Strain UTEX B3054 Retained Multicellular Features at the Genomic and …
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2020 |
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[12]
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A New Remote Sensing-Based System for the Monitoring and Analysis of Growth and Gas Exchange Rates of Photosynthetic Microorganisms Under …
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2020 |
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[13]
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Szimulált Mars-analóg környezeti tényezők hatása az intakt, extremofil kriptobiotikus kérgek fotoszintézisére és túlélésére
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2020 |
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[14]
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Phyllosilicates as protective habitats of filamentous cyanobacteria Leptolyngbya against ultraviolet radiation
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2019 |
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[15]
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Microbial ecology of the Namib Desert
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2019 |
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[16]
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Biotechnology and Bioengineering in Astrobiology: Towards a New Habitat for Us
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Omics Technologies and …,
2018 |
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[17]
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EXTREMOPHILE MIKROORGANISMEN: von der anpassung zur anwendung
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2018 |
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[18]
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Identification of some Cyanobacterial Isolates of Khabr National Park of Kerman using Classic and Molecular Methods
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2018 |
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[19]
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Diverzitet aerofitskih cijanobakterija i algi u biofilmu odabranih pećina u Srbiji
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2018 |
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[20]
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Resistance of cyanobacteria to space and Mars environments, in the frame of the EXPOSE-R2 space mission and beyond
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Thesis,
2018 |
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[21]
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7.2 BIOTECHNOLOGICAL APPROACHES IN DETECTING LIFE IN SPACE
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OMICS TECHNOLOGIES AND BIO-ENGINEERING Towards Improving Quality of Life,
2018 |
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[22]
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Vorkommen kalter Lebensräume–42 Psychrophile Mikroorganismen–45
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2018 |
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[23]
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Entrevivendo em suspensão
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2018 |
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[24]
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Life in suspension
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2018 |
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[25]
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Desert cyanobacteria under space and planetary simulations: a tool for searching for life beyond Earth and supporting human space exploration
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International Journal of Astrobiology,
2018 |
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[26]
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Extremophile Mikroorganismen
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Springer Spektrum, Berlin, Heidelberg,
2017 |
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[27]
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Weitere Kapitel dieses Buchs durch Wischen aufrufen
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Extremophile Mikroorganismen,
2017 |
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[28]
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Extremophile Organismen und Astrobiologie
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Extremophile Mikroorganismen,
2017 |
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[29]
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Psychrophile
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Extremophile Mikroorganismen,
2017 |
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[30]
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Evaluation of the resistance of Chroococcidiopsis spp. to sparsely and densely ionizing irradiation
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2017 |
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[31]
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Photosynthetic polyol production
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UvA-DARE (Digital Academic Repository),
2017 |
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[32]
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Desert Cyanobacteria: Potential for Space and Earth Applications
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Adaption of Microbial Life to Environmental Extremes,
2017 |
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[33]
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Biological colonization on stone monuments: A new low impact cleaning method
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Journal of Cultural Heritage,
2017 |
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[34]
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Bacterial ion effects and their relation to salt tolerance
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2017 |
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[35]
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Piezophile
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Extremophile Mikroorganismen,
2017 |
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[36]
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Nitrogen fixing cyanobacteria: their diversity, ecology and utilisation with special reference to rice cultivation
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Journal of the National Science Foundation of Sri Lanka,
2016 |
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[37]
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An ESA roadmap for geobiology in space exploration
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Acta Astronautica,
2016 |
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[38]
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Pressurized Martian-like pure CO 2 atmosphere supports strong growth of cyanobacteria, and causes significant changes in their metabolism
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2016 |
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[39]
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Polyextremophiles
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Life under multiple,
2015 |
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[40]
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RNA‐based molecular survey of biodiversity of limestone tombstone microbiota in response to atmospheric sulphur pollution
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Letters in applied microbiology,
2015 |
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[41]
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Sustainable life support on Mars–the potential roles of cyanobacteria
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International Journal of Astrobiology,
2015 |
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[42]
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Pressurized Martian-like pure CO2 atmosphere supports strong growth of cyanobacteria, and causes significant changes in their metabolism
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Origins of Life and Evolution of Biospheres,
2015 |
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[43]
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Provision of water by halite deliquescence for Nostoc commune biofilms under Mars relevant surface conditions
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International Journal of Astrobiology,
2015 |
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[44]
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Development of a laboratory model of a phototroph-heterotroph mixed-species biofilm at the stone/air interface
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Frontiers in microbiology,
2015 |
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[45]
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Preservation of Biomarkers from Cyanobacteria Mixed with MarsLike Regolith Under Simulated Martian Atmosphere and UV Flux
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Origins of Life and Evolution of Biospheres,
2015 |
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[46]
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BIOMEX on EXPOSE-R2: Preservation of cyanobacterial biomarkers after Martian ground-based simulation exposure
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2015 |
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[47]
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Structures/textures of living/fossil microbialites and their implications in biogenicity: An astrobiological point of view
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2015 |
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[48]
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Comparative analysis of cyanobacteria inhabiting rocks with different light transmittance in the Mojave Desert: a Mars terrestrial analogue
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International Journal of Astrobiology,
2014 |
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[49]
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Synchronous in-field application of life-detection techniques in planetary analog missions
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Planetary and Space Science,
2014 |
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[50]
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Thermophilic microbes in environmental and industrial biotechnology
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2013 |
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[51]
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Survival of Chroococcidiopsis cubana and Nostoc sp. NHVL1 under simulated Martian conditions
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