Your search keyword '"EXTREME ENVIRONMENTS"' showing total 31 results

1. Investigating Polyextremophilic Bacteria in Al Wahbah Crater, Saudi Arabia: A Terrestrial Model for Life on Saturn's Moon Enceladus.

Author

dos Santos, Alef, Schultz, Júnia, Almeida Trapp, Marilia, Modolon, Fluvio, Romanenko, Andrii, Kumar Jaiswal, Arun, Gomes, Lucas, Rodrigues-Filho, Edson, and Rosado, Alexandre Soares

Subjects

*ASTROBIOLOGY, *NATURAL satellites, *EXTRATERRESTRIAL life, *EXTREME environments, *LUNAR craters, *MASS spectrometry

Abstract

The study of extremophilic microorganisms has sparked interest in understanding extraterrestrial microbial life. Such organisms are fundamental for investigating life forms on Saturn's icy moons, such as Enceladus, which is characterized by potentially habitable saline and alkaline niches. Our study focused on the salt-alkaline soil of the Al Wahbah crater in Saudi Arabia, where we identified microorganisms that could be used as biological models to understand potential life on Enceladus. The search involved isolating 48 bacterial strains, sequencing the genomes of two thermo-haloalkaliphilic strains, and characterizing them for astrobiological application. A deeper understanding of the genetic composition and functional capabilities of the two novel strains of Halalkalibacterium halodurans provided valuable insights into their survival strategies and the presence of coding genes and pathways related to adaptations to environmental stressors. We also used mass spectrometry with a molecular network approach, highlighting various classes of molecules, such as phospholipids and nonproteinogenic amino acids, as potential biosignatures. These are essential features for understanding life's adaptability under extreme conditions and could be used as targets for biosignatures in upcoming missions exploring Enceladus' orbit. Furthermore, our study reinforces the need to look at new extreme environments on Earth that might contribute to the astrobiology field. [ABSTRACT FROM AUTHOR]

Published

2024

2. Chapter 6: The Breadth and Limits of Life on Earth.

Author

Thweatt, Jennifer L., Harman, C.E., Araújo, M.N., Marlow, Jeffrey J., Oliver, Gina C., Sabuda, Mary C., Sevgen, Serhat, and Wilpiszeki, Regina L.

Subjects

*SPACE environment, *EXTRATERRESTRIAL life, *ASTROBIOLOGY, *NUTRITIONAL requirements, *EXTRATERRESTRIAL beings, *BIOCHEMISTRY

Abstract

Scientific ideas about the potential existence of life elsewhere in the universe are predominantly informed by knowledge about life on Earth. Over the past ∼4 billion years, life on Earth has evolved into millions of unique species. Life now inhabits nearly every environmental niche on Earth that has been explored. Despite the wide variety of species and diverse biochemistry of modern life, many features, such as energy production mechanisms and nutrient requirements, are conserved across the Tree of Life. Such conserved features help define the operational parameters required by life and therefore help direct the exploration and evaluation of habitability in extraterrestrial environments. As new diversity in the Tree of Life continues to expand, so do the known limits of life on Earth and the range of environments considered habitable elsewhere. The metabolic processes used by organisms living on the edge of habitability provide insights into the types of environments that would be most suitable to hosting extraterrestrial life, crucial for planning and developing future astrobiology missions. This chapter will introduce readers to the breadth and limits of life on Earth and show how the study of life at the extremes can inform the broader field of astrobiology. [ABSTRACT FROM AUTHOR]

Published

2024

3. Exploring Space via Astromycology: A Report on the CIFAR Programs Earth 4D and Fungal Kingdom Inaugural Joint Meeting

Author

Case, Nicola T, Song, Min, Fulford, Avery H, Graham, Heather V, Orphan, Victoria J, Stajich, Jason E, Casadevall, Arturo, Mustard, John, Heitman, Joseph, Lollar, Barbara Sherwood, and Cowen, Leah E

Subjects

Astronomical Sciences, Physical Sciences, Canada, Earth, Planet, Exobiology, Extraterrestrial Environment, Humans, Mars, Planets, Fungi, Subsurface, Origin, Evolution, Extinction, Extreme environments, Astronomical and Space Sciences, Geochemistry, Geology, Astronomy & Astrophysics, Astronomical sciences

Abstract

"Fungi on Mars!": a popular news heading that piques public interest and makes scientists' blood boil. While such a statement is laden with misinformation and light on evidence, the search for past and present extraterrestrial life is an ongoing scientific effort. Moreover, it is one that is increasingly gaining momentum with the recent collection of martian rock cores from Jezero Crater by NASA's Perseverance rover. Despite the increasingly sophisticated approaches guiding the search for microbial life on other planets, fungi remain relatively underexplored compared to their bacterial counterparts, highlighting a gap between the astrobiological and fungal research communities. Through a meeting in April 2021, the CIFAR Earth 4D and Fungal Kingdom research programs worked to bridge this divide by uniting experts in each field. CIFAR is a Canadian-based global research organization that convenes researchers across disciplines to address important questions facing science and humanity. The CIFAR Earth 4D: Subsurface Science & Exploration and Fungal Kingdom: Threats & Opportunities research programs were launched by CIFAR in July 2019, each made up of approximately two dozen international researchers who are experts in their fields. The Earth 4D program, led by co-directors John Mustard (Brown University, USA) and Barbara Sherwood Lollar (University of Toronto, Canada), aims to understand the complex chemical, physical, and biological interactions that occur within and between Earth's surface and subsurface to explore questions on the evolution of planets and life. The Fungal Kingdom program, led by co-directors Leah Cowen (University of Toronto, Canada) and Joseph Heitman (Duke University, USA), seeks to tackle the most pressing threats fungi pose to human health, agriculture, and biodiversity and to harness their extraordinary potential. The programs met to explore areas for synergy within four major themes: (1) the origins of life; (2) the evolution and diversification of life; (3) life in diverse and extreme environments; and (4) extinction: lessons learned and threats. This report covers the research discussed during the meeting across these four themes.

Published

2022

4. Information Transmission via Molecular Communication in Astrobiological Environments.

Author

Lingam, Manasvi

Subjects

*HYDROTHERMAL vents, *TELECOMMUNICATION systems, *CELL communication, *COMMUNICATION models, *EXTREME environments, *GEOTHERMAL ecology, *OCEAN

Abstract

The ubiquity of information transmission via molecular communication between cells is comprehensively documented on Earth; this phenomenon might even have played a vital role in the origin(s) and early evolution of life. Motivated by these considerations, a simple model for molecular communication entailing the diffusion of signaling molecules from transmitter to receiver is elucidated. The channel capacity C (maximal rate of information transmission) and an optimistic heuristic estimate of the actual information transmission rate ℐ are derived for this communication system; the two quantities, especially the latter, are demonstrated to be broadly consistent with laboratory experiments and more sophisticated theoretical models. The channel capacity exhibits a potentially weak dependence on environmental parameters, whereas the actual information transmission rate may scale with the intercellular distance d as ℐ ∝ d−4 and could vary substantially across settings. These two variables are roughly calculated for diverse astrobiological environments, ranging from Earth's upper oceans (C ∼ 3.1 × 10 bits/s; ℐ ∼ 4.7 × 10−2 bits/s) and deep sea hydrothermal vents (C ∼ 4.2 × 10 bits/s; ℐ ∼ 1.2 × 10−1 bits/s) to the hydrocarbon lakes and seas of Titan (C ∼ 3.8 × 10 bits/s; ℐ ∼ 2.6 × 10−1 bits/s). [ABSTRACT FROM AUTHOR]

Published

2024

5. Jack Dwayne Farmer: April 18, 1947–February 22, 2023.

Author

Des Marais, David J., Farmer, Maria C., Anbar, Ariel D., Zaloumis, Jonathan, Shkolyar, Svetlana, Estrada, Charlene, and Cady, Sherry L.

Subjects

*FARMERS, *SPACE sciences, *MARTIAN exploration, *EXTREME environments, *LIFE on Mars, *PHYSICAL geology

Abstract

Jack later became a world leader in the burgeoning field of astrobiology (an expansion of NASA's earlier Exobiology program). While at NASA's Ames Research Center in the 1990s, Jack pursued field studies in environments on Earth that resembled those on early Mars. After joining Arizona State University (ASU) in 1998, Jack continued his research in geobiology and involved his students in projects relevant to the geological and astrobiological exploration of Mars. Jack contributed to the revision of NASA's 2004 Astrobiology Roadmap and substantially influenced the astrobiology strategy for Mars exploration. [Extracted from the article]

Published

2023

6. An Overview of Lipid Biomarkers in Terrestrial Extreme Environments with Relevance for Mars Exploration.

Author

Finkel, Pablo L., Carrizo, Daniel, Parro, Victor, and Sánchez-García, Laura

Subjects

*MARTIAN exploration, *EXTREME environments, *STABLE isotope analysis, *BIOLOGICAL membranes, *LIFE on Mars, *LIPIDS

Abstract

Lipid molecules are organic compounds, insoluble in water, and based on carbon-carbon chains that form an integral part of biological cell membranes. As such, lipids are ubiquitous in life on Earth, which is why they are considered useful biomarkers for life detection in terrestrial environments. These molecules display effective membrane-forming properties even under geochemically hostile conditions that challenge most of microbial life, which grants lipids a universal biomarker character suitable for life detection beyond Earth, where a putative biological membrane would also be required. What discriminates lipids from nucleic acids or proteins is their capacity to retain diagnostic information about their biological source in their recalcitrant hydrocarbon skeletons for thousands of millions of years, which is indispensable in the field of astrobiology given the time span that the geological ages of planetary bodies encompass. This work gathers studies that have employed lipid biomarker approaches for paleoenvironmental surveys and life detection purposes in terrestrial environments with extreme conditions: hydrothermal, hyperarid, hypersaline, and highly acidic, among others; all of which are analogous to current or past conditions on Mars. Although some of the compounds discussed in this review may be abiotically synthesized, we focus on those with a biological origin, namely lipid biomarkers. Therefore, along with appropriate complementary techniques such as bulk and compound-specific stable carbon isotope analysis, this work recapitulates and reevaluates the potential of lipid biomarkers as an additional, powerful tool to interrogate whether there is life on Mars, or if there ever was. [ABSTRACT FROM AUTHOR]

Published

2023

7. Microbial Motility at the Bottom of North America: Digital Holographic Microscopy and Genomic Motility Signatures in Badwater Spring, Death Valley National Park.

Author

Snyder, Carl, Centlivre, Jakob P., Bhute, Shrikant, Shipman, Gözde, Friel, Ariel D., Viver, Tomeu, Palmer, Marike, Konstantinidis, Konstantinos T., Sun, Henry J., Rossello-Mora, Ramon, Nadeau, Jay, and Hedlund, Brian P.

Subjects

*MOTILITY of microorganisms, *DIGITAL holographic microscopy, *SHOTGUN sequencing, *NATIONAL parks & reserves, *EXTRATERRESTRIAL life, *MICROSCOPY, *EXTREME environments, DEATH Valley National Park (Calif. & Nev.)

Abstract

Motility is widely distributed across the tree of life and can be recognized by microscopy regardless of phylogenetic affiliation, biochemical composition, or mechanism. Microscopy has thus been proposed as a potential tool for detection of biosignatures for extraterrestrial life; however, traditional light microscopy is poorly suited for this purpose, as it requires sample preparation, involves fragile moving parts, and has a limited volume of view. In this study, we deployed a field-portable digital holographic microscope (DHM) to explore microbial motility in Badwater Spring, a saline spring in Death Valley National Park, and complemented DHM imaging with 16S rRNA gene amplicon sequencing and shotgun metagenomics. The DHM identified diverse morphologies and distinguished run-reverse-flick and run-reverse types of flagellar motility. PICRUSt2- and literature-based predictions based on 16S rRNA gene amplicons were used to predict motility genotypes/phenotypes for 36.0–60.1% of identified taxa, with the predicted motile taxa being dominated by members of Burkholderiaceae and Spirochaetota. A shotgun metagenome confirmed the abundance of genes encoding flagellar motility, and a Ralstonia metagenome-assembled genome encoded a full flagellar gene cluster. This study demonstrates the potential of DHM for planetary life detection, presents the first microbial census of Badwater Spring and brine pool, and confirms the abundance of mobile microbial taxa in an extreme environment. [ABSTRACT FROM AUTHOR]

Published

2023

8. Extreme Exoworlds and the Extremophile Paradox.

Author

von Hegner, Ian

Subjects

*EXTREME environments, *EXTRATERRESTRIAL life, *SOLAR system, *PARADOX, *ASTROBIOLOGY

Abstract

Extremophiles have gained prominence by providing an experimental approach to astrobiology. Extremophiles gain equal value by being part of a framework for high-level characterization of the evolutionary mechanisms that must necessarily restrict or promote their emergence and presence on solar system bodies. Thus, extremophiles exist in extreme environments, and therein lies the paradox: extremophiles can only live in extreme environments but are not able to originate in such environments. Therefore, even though the range of extremophile capabilities in extreme environments is wider than that in mesophiles, the range of their emergence possibilities is still equally restricted. Therefore, even if one locates an extreme exoworld where terrestrial extremophiles could live here-and-now, it can be predicted that no extremophile analogs are present anyway. Furthermore, it is possible for a world to be uninhabited, yet be habitable, and therein arises the extreme environment paradox: an extreme environment can sustain chemical evolution as well as arriving non-native life, yet native life cannot be built up in that very environment. Thus, life may exist on an extraterrestrial extreme world (if imported there), and chemical evolution may be present on that world. However, it can be predicted that there is no native life anyway. This situation can be predicted to function as a chemosignature and eventually as a biosignature. However, the fact that a non-native extremopile in principle can exist in extreme environments may demonstrate that the intermediate step between chemical evolution and extremophiles can still occur in the form of a statistical deviation. In summary, the use of extremophiles as analogs to extraterrestrial life has limitations due to the very conditions evolution operates under, although analysis of these conditions provides conceptual tools for the search for life elsewhere in the Solar System and beyond. [ABSTRACT FROM AUTHOR]

Published

2022

9. Venus, an Astrobiology Target.

Author

Limaye, Sanjay S., Mogul, Rakesh, Baines, Kevin H., Bullock, Mark A., Cockell, Charles, Cutts, James A., Gentry, Diana M., Grinspoon, David H., Head, James W., Jessup, Kandis-Lea, Kompanichenko, Vladimir, Lee, Yeon Joo, Mathies, Richard, Milojevic, Tetyana, Pertzborn, Rosalyn A., Rothschild, Lynn, Sasaki, Satoshi, Schulze-Makuch, Dirk, Smith, David J., and Way, Michael J.

Subjects

*ASTROBIOLOGY, *VENUS (Planet), *ATMOSPHERIC circulation, *RADIATION, *ORIGIN of life, *AIR microbiology

Abstract

We present a case for the exploration of Venus as an astrobiology target—(1) investigations focused on the likelihood that liquid water existed on the surface in the past, leading to the potential for the origin and evolution of life, (2) investigations into the potential for habitable zones within Venus' present-day clouds and Venus-like exo atmospheres, (3) theoretical investigations into how active aerobiology may impact the radiative energy balance of Venus' clouds and Venus-like atmospheres, and (4) application of these investigative approaches toward better understanding the atmospheric dynamics and habitability of exoplanets. The proximity of Venus to Earth, guidance for exoplanet habitability investigations, and access to the potential cloud habitable layer and surface for prolonged in situ extended measurements together make the planet a very attractive target for near term astrobiological exploration. [ABSTRACT FROM AUTHOR]

Published

2021

10. Exobiology of the Venusian Clouds: New Insights into Habitability through Terrestrial Models and Methods of Detection.

Author

Kotsyurbenko, Oleg R., Cordova Jr., Jaime A., Belov, Andrey A., Cheptsov, Vladimir S., Kölbl, Denise, Khrunyk, Yuliya Y., Kryuchkova, Margarita O., Milojevic, Tetyana, Mogul, Rakesh, Sasaki, Satoshi, Słowik, Grzegorz P., Snytnikov, Valery, and Vorobyova, Elena A.

Subjects

*ASTROBIOLOGY, *EUROPA (Satellite), *VENUS (Planet), *WATER currents, *EXTREME environments, *ECOSYSTEMS, *MICROBIAL diversity

Abstract

The search for life beyond Earth has focused on Mars and the icy moons Europa and Enceladus, all of which are considered a safe haven for life due to evidence of current or past water. The surface of Venus, on the other hand, has extreme conditions that make it a nonhabitable environment to life as we know it. This is in contrast, however, to its cloud layer, which, while still an extreme environment, may prove to be a safe haven for some extreme forms of life similar to extremophiles on Earth. We consider the venusian clouds a habitable environment based on the presence of (1) a solvent for biochemical reactions, (2) appropriate physicochemical conditions, (3) available energy, and (4) biologically relevant elements. The diversity of extreme microbial ecosystems on Earth has allowed us to identify terrestrial chemolithoautotrophic microorganisms that may be analogs to putative venusian organisms. Here, we hypothesize and describe biological processes that may be performed by such organisms in the venusian clouds. To detect putative venusian organisms, we describe potential biosignature detection methods, which include metal-microbial interactions and optical methods. Finally, we describe currently available technology that can potentially be used for modeling and simulation experiments. [ABSTRACT FROM AUTHOR]

Published

2021

11. Acid Mine Drainage as Energizing Microbial Niches for the Formation of Iron Stromatolites: The Tintillo River in Southwest Spain.

Author

Chacon-Baca, Elizabeth, Santos, Ana, Sarmiento, Aguasanta Miguel, Luís, Ana Teresa, Santisteban, Maria, Fortes, Juan Carlos, Dávila, José Miguel, Diaz-Curiel, Jesus M., and Grande, Jose Antonio

Subjects

*ACID mine drainage, *STROMATOLITES, *EXTREME environments, *IRON, *MOLECULAR evolution, *ASTROBIOLOGY

Abstract

The Iberian Pyrite Belt in southwest Spain hosts some of the largest and diverse extreme acidic environments with textural variation across rapidly changing biogeochemical gradients at multiple scales. After almost three decades of studies, mostly focused on molecular evolution and metagenomics, there is an increasing awareness of the multidisciplinary potential of these types of settings, especially for astrobiology. Since modern automatized exploration on extraterrestrial surfaces is essentially based on the morphological recognition of biosignatures, a macroscopic characterization of such sedimentary extreme environments and how they look is crucial to identify life properties, but it is a perspective that most molecular approaches frequently miss. Although acid mine drainage (AMD) systems are toxic and contaminated, they offer at the same time the bioengineering tools for natural remediation strategies. This work presents a biosedimentological characterization of the clastic iron stromatolites in the Tintillo river. They occur as laminated terraced iron formations that are the most distinctive sedimentary facies at the Tintillo river, which is polluted by AMD. Iron stromatolites originate from fluvial abiotic factors that interact with biological zonation. The authigenic precipitation of schwertmannite and jarosite results from microbial–mineral interactions between mineral and organic matrices. The Tintillo iron stromatolites are composed of bacterial filaments and diatoms as Nitzschia aurariae, Pinnularia aljustrelica, Stauroneis kriegeri, and Fragilaria sp. Furthermore, the active biosorption and bioleaching of sulfur are suggested by the black and white coloration of microbial filaments inside stromatolites. AMD systems are hazardous due to physical, chemical, and biological agents, but they also provide biogeochemical sources with which to infer past geochemical conditions on Earth and inform exploration efforts on extraterrestrial surfaces in the future. [ABSTRACT FROM AUTHOR]

Published

2021

12. An Alternative Approach for Assessing Biogenicity.

Author

Rouillard, Joti, van Zuilen, Mark, Pisapia, Céline, and Garcia-Ruiz, Juan-Manuel

Subjects

*SPACE colonies, *EXTREME environments, *FOSSIL microorganisms, *SOUND recordings, *STEREOISOMERS

Abstract

The search for signs of life in the ancient rock record, extreme terrestrial environments, and other planetary bodies requires a well-established, universal, and unambiguous test of biogenicity. This is notably true for cellular remnants of microbial life, since their relatively simple morphologies resemble various abiogenic microstructures that occur in nature. Although lists of qualitative biogenicity criteria have been devised, debates regarding the biogenicity of many ancient microfossils persist to this day. We propose here an alternative quantitative approach for assessing the biogenicity of putative microfossils. In this theoretical approach, different hypotheses—involving biology or not and depending on the geologic setting—are put forward to explain the observed objects. These hypotheses correspond to specific types of microstructures/systems. Using test samples, the morphology and/or chemistry of these systems are then characterized at the scale of populations. Morphologic parameters include, for example, circularity, aspect ratio, and solidity, while chemical parameters could include elementary ratios (e.g., N/C ratio), isotopic enrichments (e.g., δ13C), or chirality (e.g., molar proportion of stereoisomers), among others. Statistic trends distinguishing the different systems are then searched for empirically. The trends found are translated into "decision spaces" where the different systems are quantitatively discriminated and where the potential microfossil population can be located as a single point. This approach, which is formulated here on a theoretical level, will solve several problems associated with the classical qualitative criteria of biogenicity. Most importantly, it could be applied to reveal the existence of cellular life on other planets, for which characteristics of morphology and chemical composition are difficult to predict. [ABSTRACT FROM AUTHOR]

Published

2021

13. AMADEE-18: Vision-Based Unmanned Aerial Vehicle Navigation for Analog Mars Mission (AVI-NAV).

Author

Allak, Eren, Brommer, Christian, Dallenbach, Diego, and Weiss, Stephan

Subjects

*MARTIAN exploration, *AERONAUTICAL navigation, *MARS (Planet), *GLOBAL Positioning System, *DRONE aircraft, *SURFACE structure, *PLANETARY exploration

Abstract

As a part of the AMADEE-18 analog Mars mission, designed to study challenges associated with human-based exploration of the Red Planet, we focused our team efforts on testing means to localize an unmanned aerial vehicle (UAV) on Mars. Robot helicopters, such as the one selected for a technology demonstration as a part of NASA's Mars 2020 mission, are small and their performance is computationally limited. An essential aspect of navigation and path planning of an autonomous helicopter is accurate localization of the robot. In the absence of a global positioning system, a computationally efficient localization technology that can be applied on Mars is visual-inertial odometry (VIO). The AMADEE-18 mission provided an opportunity to test the feasibility of a state-of-the-art VIO algorithm and the camera in a Mars-like analog environment. The flight datasets included different terrain structures that challenged the functionality of VIO algorithms. The experiment has yielded valuable insights into the desired surface structure, texture, and mission times for surface relative navigation of UAV on Mars. [ABSTRACT FROM AUTHOR]

Published

2020

14. Mars Extant Life: What's Next? Conference Report.

Author

Carrier, B.L., Beaty, D.W., Meyer, M.A., Blank, J.G., Chou, L., DasSarma, S., Des Marais, D.J., Eigenbrode, J.L., Grefenstette, N., Lanza, N.L., Schuerger, A.C., Schwendner, P., Smith, H.D., Stoker, C.R., Tarnas, J.D., Webster, K.D., Bakermans, C., Baxter, B.K., Bell, M.S., and Benner, S.A.

Subjects

*LIFE on Mars, *CONFERENCES & conventions, *ASTROBIOLOGY, *MICROORGANISMS, *EXTREME environments

Abstract

On November 5–8, 2019, the "Mars Extant Life: What's Next?" conference was convened in Carlsbad, New Mexico. The conference gathered a community of actively publishing experts in disciplines related to habitability and astrobiology. Primary conclusions are as follows: A significant subset of conference attendees concluded that there is a realistic possibility that Mars hosts indigenous microbial life. A powerful theme that permeated the conference is that the key to the search for martian extant life lies in identifying and exploring refugia ("oases"), where conditions are either permanently or episodically significantly more hospitable than average. Based on our existing knowledge of Mars, conference participants highlighted four potential martian refugium (not listed in priority order): Caves, Deep Subsurface, Ices, and Salts. The conference group did not attempt to reach a consensus prioritization of these candidate environments, but instead felt that a defensible prioritization would require a future competitive process. Within the context of these candidate environments, we identified a variety of geological search strategies that could narrow the search space. Additionally, we summarized a number of measurement techniques that could be used to detect evidence of extant life (if present). Again, it was not within the scope of the conference to prioritize these measurement techniques—that is best left for the competitive process. We specifically note that the number and sensitivity of detection methods that could be implemented if samples were returned to Earth greatly exceed the methodologies that could be used at Mars. Finally, important lessons to guide extant life search processes can be derived both from experiments carried out in terrestrial laboratories and analog field sites and from theoretical modeling. [ABSTRACT FROM AUTHOR]

Published

2020

15. Biosignature Analysis of Mars Soil Analogs from the Atacama Desert: Challenges and Implications for Future Missions to Mars.

Author

Aerts, Joost W., Riedo, Andreas, Melton, Daniel J., Martini, Simone, Flahaut, Jessica, Meierhenrich, Uwe J., Meinert, Cornelia, Myrgorodska, Iuliia, Lindner, Robert, and Ehrenfreund, Pascale

Subjects

*EXTREME environments, *SOIL testing, *MASS spectrometry, *AMINO acid analysis, *MULTIDIMENSIONAL chromatography, *MARS (Planet)

Abstract

The detection of biosignatures on Mars is of outstanding interest in the current field of astrobiology and drives various fields of research, ranging from new sample collection strategies to the development of more sensitive detection techniques. Detailed analysis of the organic content in Mars analog materials collected from extreme environments on Earth improves the current understanding of biosignature preservation and detection under conditions similar to those of Mars. In this article, we examined the biological fingerprint of several locations in the Atacama Desert (Chile), which include different wet and dry, and intermediate to high elevation salt flats (also named salars). Liquid chromatography and multidimensional gas chromatography mass spectrometry measurement techniques were used for the detection and analysis of amino acids extracted from the salt crusts and sediments by using sophisticated extraction procedures. Illumina 16S amplicon sequencing was used for the identification of microbial communities associated with the different sample locations. Although amino acid load and organic carbon and nitrogen quantities were generally low, it was found that most of the samples harbored complex and versatile microbial communities, which were dominated by (extremely) halophilic microorganisms (most notably by species of the Archaeal family Halobacteriaceae). The dominance of salts (i.e., halites and sulfates) in the investigated samples leaves its mark on the composition of the microbial communities but does not appear to hinder the potential of life to flourish since it can clearly adapt to the higher concentrations. Although the Atacama Desert is one of the driest and harshest environments on Earth, it is shown that there are still sub-locations where life is able to maintain a foothold, and, as such, salt flats could be considered as interesting targets for future life exploration missions on Mars. [ABSTRACT FROM AUTHOR]

Published

2020

16. Persistence of Habitable, but Uninhabited, Aqueous Solutions and the Application to Extraterrestrial Environments.

Author

Cockell, Charles S.

Subjects

*SPACE environment, *AQUEOUS solutions, *ELECTRON donors, *BODIES of water, *EXTREME environments, *PHOSPHORUS cycle (Biogeochemistry)

Abstract

In most environments on Earth, habitable environments contain life. Experiments were conducted to investigate the decoupling of the presence of habitable conditions and life. A set of microcosms habitable for known groups of organisms, but uninhabited (i.e., uninhabited habitats), was exposed to external environmental conditions to test the hypothesis that extreme habitable environments can remain uninhabited for sustained time periods. These microcosms were made of tubes containing liquid water and inorganic N, P, and S. Organics (used as electron donors and as a C source) were provided as L and D amino acids. One set of uninhabited habitats contained no additional salts, one set contained saturated NaCl, and one set contained saturated MgSO4. A ddH2O control and a complex medium for Halobacterium were used as controls. The presence of organisms was tested by enumeration of colonists and sequencing of extracted DNA. At each time point, inoculation into fresh medium was used to test for growth of organisms. After 1 week, the "no salt" and saturated MgSO4 solutions were colonized. After 6 months, both the NaCl-saturated and Halobacterium solutions remained uninhabited, but all other samples were colonized. These experiments demonstrate that certain types of habitable liquid water environments exposed to microbial atmospheric inoculation, even on Earth, can remain devoid of reproducing life for many months. On other planetary bodies, such as Mars, these data imply the possibility of preserved transient water bodies that would record habitable conditions, but no evidence of life, even if life existed elsewhere on the planet. [ABSTRACT FROM AUTHOR]

Published

2020

17. Extreme Exoworlds and the Extremophile Paradox

Author

Ian von Hegner

Subjects

Extremophiles, Biological Physics (physics.bio-ph), Space and Planetary Science, FOS: Biological sciences, Exobiology, Populations and Evolution (q-bio.PE), FOS: Physical sciences, Physics - Biological Physics, Quantitative Biology - Populations and Evolution, Agricultural and Biological Sciences (miscellaneous), Extreme Environments

Abstract

Extremophiles have gained prominence by providing an experimental approach to astrobiology. Extremophiles gain equal value by being part of a framework for high-level characterisation of the evolutionary mechanisms that must necessarily restrict or promote their emergence and presence on solar system bodies. Thus, extremophiles exist in extreme environments, and therein lies the paradox: extremophiles can only live in extreme environments but yet are not able to originate in such environments. Therefore, even though the range of extremophile capabilities in extreme environments is wider than that in mesophiles, the range of their emergence possibilities is still equally restricted. Therefore, even if one locates an extreme exoworld where terrestrial extremophiles could live here-and-now, it can be predicted that no extremophile analogues are present anyway. Furthermore, it is possible for a world to be uninhabited, yet be habitable, and therein arises the extreme environment paradox: an extreme environment can sustain chemical evolution as well as arriving non-native life, yet native life cannot be built up in that very environment. Thus, life may exist on an extraterrestrial extreme world (if imported there), and chemical evolution may be present on that world. However, it can be predicted that there is no native life anyway. This situation can be predicted to function as a chemosignature and eventually as a biosignature. However, the fact that a non-native extremopile in principle can exist in extreme environments may demonstrate that the intermediate step between chemical evolution and extremophiles can still occur in the form of a statistical deviation., Comment: 14 pages

Published

2022

18. The Dallol Geothermal Area, Northern Afar (Ethiopia)—An Exceptional Planetary Field Analog on Earth.

Author

Cavalazzi, B., Barbieri, R., Gómez, F., Capaccioni, B., Olsson-Francis, K., Pondrelli, M., Rossi, A.P., Hickman-Lewis, K., Agangi, A., Gasparotto, G., Glamoclija, M., Ori, G.G., Rodriguez, N., and Hagos, M.

Subjects

*GEOTHERMAL ecology, *MINES & mineral resources, *HYDROTHERMAL alteration, *EARTH (Planet), *HOT springs, *POLITICAL stability

Abstract

The Dallol volcano and its associated hydrothermal field are located in a remote area of the northern Danakil Depression in Ethiopia, a region only recently appraised after decades of inaccessibility due to severe political instability and the absence of infrastructure. The region is notable for hosting environments at the very edge of natural physical-chemical extremities. It is surrounded by a wide, hyperarid salt plain and is one of the hottest (average annual temperatureDallol: 36–38°C) and most acidic natural systems (pHDallol ≈0) on Earth. Spectacular geomorphologies and mineral deposits produced by supersaturated hydrothermal waters and brines are the result of complex interactions between active and inactive hydrothermal alteration of the bedrock, sulfuric hot springs and pools, fumaroles and geysers, and recrystallization processes driven by hydrothermal waters, degassing, and rapid evaporation. The study of planetary field analog environments plays a crucial role in characterizing the physical and chemical boundaries within which life can exist on Earth and other planets. It is essential for the definition and assessment of the conditions of habitability on other planets, including the possibility for biosignature preservation and in situ testing of technologies for life detection. The Dallol area represents an excellent Mars analog environment given that the active volcanic environment, the associated diffuse hydrothermalism and hydrothermal alteration, and the vast acidic sulfate deposits are reminiscent of past hydrothermal activity on Mars. The work presented in this paper is an overview of the Dallol volcanic area and its hydrothermal field that integrates previous literature with observations and results obtained from field surveys and monitoring coupled with sample characterization. In so doing, we highlight its exceptional potential as a planetary field analog as well as a site for future astrobiological and exploration programs. [ABSTRACT FROM AUTHOR]

Published

2019

19. Using Science-Driven Analog Research to Investigate Extravehicular Activity Science Operations Concepts and Capabilities for Human Planetary Exploration.

Author

Beaton, Kara H., Chappell, Steven P., Abercromby, Andrew F.J., Miller, Matthew J., Kobs Nawotniak, Shannon E., Brady, Allyson L., Stevens, Adam H., Payler, Samuel J., Hughes, Scott S., and Lim, Darlene S.S.

Subjects

*EXTRAVEHICULAR activity (Human space flight), *PLANETARY exploration, *STRATEGIC planning, *SPACE flight, *EXTREME environments

Abstract

Biologic Analog Science Associated with Lava Terrains (BASALT) is a science-driven exploration program seeking to determine the best tools, techniques, training requirements, and execution strategies for conducting Mars-relevant field science under spaceflight mission conditions. BASALT encompasses Science, Science Operations, and Technology objectives. This article outlines the BASALT Science Operations background, strategic research questions, study design, and a portion of the results from the second field test. BASALT field tests are used to iteratively develop, integrate, test, evaluate, and refine new concepts of operations (ConOps) and capabilities that enable efficient and productive science. This article highlights the ConOps investigated during BASALT in light of future planetary extravehicular activity (EVA), which will focus on scientific exploration and discovery, and serves as an introduction to integrating exploration flexibility with operational rigor, the value of tactical and strategic science planning and execution, and capabilities that enable and enhance future science EVA operations. [ABSTRACT FROM AUTHOR]

Published

2019

20. A Desert Cyanobacterium under Simulated Mars-like Conditions in Low Earth Orbit: Implications for the Habitability of Mars.

Author

Billi, Daniela, Verseux, Cyprien, Fagliarone, Claudia, Napoli, Alessandro, Baqué, Mickael, and de Vera, Jean-Pierre

Subjects

*CYANOBACTERIA, *LIFE on Mars, *EFFECT of ultraviolet radiation on bacteria, *ECOLOGICAL niche

Abstract

In the ESA space experiment BIOMEX (BIOlogy and Mars EXperiment), dried Chroococcidiopsis cells were exposed to Mars-like conditions during the EXPOSE-R2 mission on the International Space Station. The samples were exposed to UV radiation for 469 days and to a Mars-like atmosphere for 722 days, approaching the conditions that could be faced on the surface of Mars. Once back on Earth, cell survival was tested by growth-dependent assays, while confocal laser scanning microscopy and PCR-based assay were used to analyze the accumulated damage in photosynthetic pigments (chlorophyll a and phycobiliproteins) and genomic DNA, respectively. Survival occurred only for dried cells (4–5 cell layers thick) mixed with the martian soil simulants P-MRS (phyllosilicatic martian regolith simulant) and S-MRS (sulfatic martian regolith simulant), and viability was only maintained for a few hours after space exposure to a total UV (wavelength from 200 to 400 nm) radiation dose of 492 MJ/m2 (attenuated by 0.1% neutral density filters) and 0.5 Gy of ionizing radiation. These results have implications for the hypothesis that, during Mars's climatic history, desiccation- and radiation-tolerant life-forms could have survived in habitable niches and protected niches while transported. [ABSTRACT FROM AUTHOR]

Published

2019

21. The UK Centre for Astrobiology: A Virtual Astrobiology Centre. Accomplishments and Lessons Learned, 2011-2016.

Author

Cockell, Charles S., Biller, Beth, Bryce, Casey, Cousins, Claire, Direito, Susana, Forgan, Duncan, Fox-Powell, Mark, Harrison, Jesse, Landenmark, Hanna, Nixon, Sophie, Payler, Samuel J., Rice, Ken, Samuels, Toby, Schwendner, Petra, Stevens, Adam, Nicholson, Natasha, and Wadsworth, Jennifer

Subjects

*ASTROBIOLOGY, *EXTREME environments, *EXTRATERRESTRIAL life, *ASTRONOMY, *EARTH sciences

Abstract

The UK Centre for Astrobiology (UKCA) was set up in 2011 as a virtual center to contribute to astrobiology research, education, and outreach. After 5 years, we describe this center and its work in each of these areas. Its research has focused on studying life in extreme environments, the limits of life on Earth, and implications for habitability elsewhere. Among its research infrastructure projects, UKCA has assembled an underground astrobiology laboratory that has hosted a deep subsurface planetary analog program, and it has developed new flow-through systems to study extraterrestrial aqueous environments. UKCA has used this research backdrop to develop education programs in astrobiology, including a massive open online course in astrobiology that has attracted over 120,000 students, a teacher training program, and an initiative to take astrobiology into prisons. In this paper, we review these activities and others with a particular focus on providing lessons to others who may consider setting up an astrobiology center, institute, or science facility. We discuss experience in integrating astrobiology research into teaching and education activities. Key Words: Astrobiology-Centre-Education-Subsurface-Analog research. Astrobiology 18, 224-243. [ABSTRACT FROM AUTHOR]

Published

2018

22. G-Equivalent Acceleration Tolerance in the Eutardigrade Species Hypsibius dujardini.

Author

Vasanthan, Tarushika, Alejaldre, Lorea, Hider, Jessica, Patel, Shreya, Husain, Nabiha, Umapathisivam, Bavithra, and Stone, Jonathon

Subjects

*TARDIGRADA, *EXTREME environments, *PHYSIOLOGICAL effects of acceleration, *HYDROSTATIC pressure, *SURVIVAL analysis (Biometry)

Abstract

Tardigrades are microscopic organisms renowned for their ability to survive extreme environmental conditions. Tardigrade extreme-tolerance research has centered on the ability to withstand desiccation, low and high temperatures, and high hydrostatic pressure and radiation levels. Tardigrade tolerance to hypergravity, however, has yet to be described. We used the eutardigrade species Hypsibius dujardini to investigate short-term tolerance to g-equivalent accelerations ( i.e., mimicking g-forces). Data obtained from specimens centrifuged between 3421 g and 16,060 g for 1 min inclusively reveal tolerance in an acceleration-dependent relation, with lower survivorship and egg production at higher accelerations. This is the first study to demonstrate tardigrade potential for tolerance to hypergravity and describe expected effects on tardigrade survival and reproduction. These findings will prove to be useful in lithopanspermia research ( i.e., viable spread in meteoritic rocks). Key Words: Astrobiology-Extreme tolerance-Hypergravity-Tardigrade. Astrobiology 17, 55-60. [ABSTRACT FROM AUTHOR]

Published

2017

23. Protein Stability in Titan's Subsurface Water Ocean

Author

Kyle P. Martin, Jason W. Barnes, Shannon MacKenzie, and F. Marty Ytreberg

Subjects

Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Earth, Planet, Oceans and Seas, Molecular Dynamics Simulation, 01 natural sciences, Protein Structure, Secondary, Astrobiology, symbols.namesake, Protein stability, Ammonia, Exobiology, 0103 physical sciences, Pressure, Subsurface flow, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Evolution, Chemical, Protein Stability, Temperature, Proteins, Water, Agricultural and Biological Sciences (miscellaneous), Saturn, Space and Planetary Science, symbols, Environmental science, Titan (rocket family), Extreme Environments

Abstract

Models of Titan predict that there is a subsurface ocean of water and ammonia under a layer of ice. Such an ocean would be important in the search for extraterrestrial life since it provides a potentially habitable environment. To evaluate how Earth-based proteins would behave in Titan's subsurface ocean environment, we used molecular dynamics simulations to calculate the properties of proteins with the most common secondary structure types (alpha helix and beta sheet) in both Earth and Titan-like conditions. The Titan environment was simulated by using a temperature of 300 K, a pressure of 1000 bar, and a eutectic mixture of water and ammonia. We analyzed protein compactness, flexibility, and backbone dihedral distributions to identify differences between the two environments. Secondary structures in the Titan environment were found to be less long-lasting, less flexible, and had small differences in backbone dihedral preferences (e.g., in one instance a pi helix formed). These environment-driven differences could lead to changes in how these proteins interact with other biomolecules and therefore changes in how evolution would potentially shape proteins to function in subsurface ocean environments.

Published

2020

24. AstRoMap European Astrobiology Roadmap.

Author

Horneck, Gerda, Walter, Nicolas, Westall, Frances, Grenfell, John Lee, Martin, William F., Gomez, Felipe, Leuko, Stefan, Lee, Natuschka, Onofri, Silvano, Tsiganis, Kleomenis, Saladino, Raffaele, Pilat-Lohinger, Elke, Palomba, Ernesto, Harrison, Jesse, Rull, Fernando, Muller, Christian, Strazzulla, Giovanni, Brucato, John R., Rettberg, Petra, and Capria, Maria Teresa

Subjects

*SPACE biology, *SOLAR system, *EXTREME environments, *ORIGIN of life

Abstract

The European AstRoMap project (supported by the European Commission Seventh Framework Programme) surveyed the state of the art of astrobiology in Europe and beyond and produced the first European roadmap for astrobiology research. In the context of this roadmap, astrobiology is understood as the study of the origin, evolution, and distribution of life in the context of cosmic evolution; this includes habitability in the Solar System and beyond. The AstRoMap Roadmap identifies five research topics, specifies several key scientific objectives for each topic, and suggests ways to achieve all the objectives. The five AstRoMap Research Topics are It is strongly recommended that steps be taken towards the definition and implementation of a European Astrobiology Platform (or Institute) to streamline and optimize the scientific return by using a coordinated infrastructure and funding system. Key Words: Astrobiology roadmap-Europe-Origin and evolution of life-Habitability-Life detection-Life in extreme environments. Astrobiology 16, 201-243. Table of Contents [ABSTRACT FROM AUTHOR]

Published

2016

25. Using Science-Driven Analog Research to Investigate Extravehicular Activity Science Operations Concepts and Capabilities for Human Planetary Exploration

Author

Allyson L. Brady, Scott S. Hughes, Steven P. Chappell, Matthew J. Miller, Adam R. H. Stevens, Kara H. Beaton, Darlene S. S. Lim, Shannon E. Kobs Nawotniak, Samuel J. Payler, and Andrew F. J. Abercromby

Subjects

010504 meteorology & atmospheric sciences, Lava, Mars, Terrain, Efficiency, 01 natural sciences, Training (civil), GeneralLiterature_MISCELLANEOUS, Hawaii, Science operations, 0103 physical sciences, Exobiology, Humans, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Basalt, Human spaceflight analog, Extreme environments, Concepts of operations, Agricultural and Biological Sciences (miscellaneous), Extravehicular activity, Space and Planetary Science, Physical Fitness, Research Design, Systems engineering, Astronauts, Geology, Space Simulation, Planetary exploration

Abstract

Biologic Analog Science Associated with Lava Terrains (BASALT) is a science-driven exploration program seeking to determine the best tools, techniques, training requirements, and execution strategies for conducting Mars-relevant field science under spaceflight mission conditions. BASALT encompasses Science, Science Operations, and Technology objectives. This article outlines the BASALT Science Operations background, strategic research questions, study design, and a portion of the results from the second field test. BASALT field tests are used to iteratively develop, integrate, test, evaluate, and refine new concepts of operations (ConOps) and capabilities that enable efficient and productive science. This article highlights the ConOps investigated during BASALT in light of future planetary extravehicular activity (EVA), which will focus on scientific exploration and discovery, and serves as an introduction to integrating exploration flexibility with operational rigor, the value of tactical and strategic science planning and execution, and capabilities that enable and enhance future science EVA operations.

Published

2019

26. Ethical Considerations for Planetary Protection in Space Exploration: A Workshop.

Author

Rummel, J.D., Race, M.S., and Horneck, and the Princeton Workshop Participants, G.

Subjects

*EXTRATERRESTRIAL life, *POLLUTION, *MARS (Planet), *EXTREME environments

Abstract

With the recognition of an increasing potential for discovery of extraterrestrial life, a diverse set of researchers have noted a need to examine the foundational ethical principles that should frame our collective space activities as we explore outer space. A COSPAR Workshop on Ethical Considerations for Planetary Protection in Space Exploration was convened at Princeton University on June 8-10, 2010, to examine whether planetary protection measures and practices should be extended to protect planetary environments within an ethical framework that goes beyond 'science protection' per se. The workshop had been in development prior to a 2006 NRC report on preventing the forward contamination of Mars, although it responded directly to one of the recommendations of that report and to several peer-reviewed papers as well. The workshop focused on the implications and responsibilities engendered when exploring outer space while avoiding harmful impacts on planetary bodies. Over 3 days, workshop participants developed a set of recommendations addressing the need for a revised policy framework to address 'harmful contamination' beyond biological contamination, noting that it is important to maintain the current COSPAR planetary protection policy for scientific exploration and activities. The attendees agreed that there is need for further study of the ethical considerations used on Earth and the examination of management options and governmental mechanisms useful for establishing an environmental stewardship framework that incorporates both scientific input and enforcement. Scientists need to undertake public dialogue to communicate widely about these future policy deliberations and to ensure public involvement in decision making. A number of incremental steps have been taken since the workshop to implement some of these recommendations. Key Words: Planetary protection-Extraterrestrial life-Life in extreme environments-Environment-Habitability. Astrobiology 12, 1017-1023. [ABSTRACT FROM AUTHOR]

Published

2012

27. Establishment of a Rearing System of the Extremotolerant Tardigrade Ramazzottius varieornatus: A New Model Animal for Astrobiology.

Author

Daiki D. Horikawa, Takekazu Kunieda, Wataru Abe, Masahiko Watanabe, Yuichi Nakahara, Fumiko Yukuhiro, Tetsuya Sakashita, Nobuyuki Hamada, Seiichi Wada, Tomoo Funayama, Chihiro Katagiri, Yasuhiko Kobayashi, Seigo Higashi, and Takashi Okuda

Subjects

*SPACE biology, *EXTREME environments, *ASTROBIOLOGY, *ECOLOGY

Abstract

AbstractStudies on the ability of multicellular organisms to tolerate specific environmental extremes are relatively rare compared to those of unicellular microorganisms in extreme environments. Tardigrades are extremotolerant animals that can enter an ametabolic dry state called anhydrobiosis and have high tolerance to a variety of extreme environmental conditions, particularly while in anhydrobiosis. Although tardigrades have been expected to be a potential model animal for astrobiological studies due to their excellent anhydrobiotic and extremotolerant abilities, few studies of tolerance with cultured tardigrades have been reported, possibly due to the absence of a model species that can be easily maintained under rearing conditions. We report the successful rearing of the herbivorous tardigrade, Ramazzottius varieornatus, by supplying the green alga Chlorella vulgarisas food. The life span was 35 ± 16.4 d, deposited eggs required 5.7 ± 1.1 d to hatch, and animals began to deposit eggs 9 d after hatching. The reared individuals of this species had an anhydrobiotic capacity throughout their life cycle in egg, juvenile, and adult stages. Furthermore, the reared adults in an anhydrobiotic state were tolerant of temperatures of 90°C and −196°C, and exposure to 99.8 acetonitrile or irradiation with 4000 Gy 4He ions. Based on their life history traits and tolerance to extreme stresses, R. varieornatusmay be a suitable model for astrobiological studies of multicellular organisms. Astrobiology 8, 549–556. [ABSTRACT FROM AUTHOR]

Published

2008

28. Quantitative Habitability.

Author

Everett L. Shock and Melanie E. Holland

Subjects

*POWER resources, *EXTREME environments, *BIOCHEMISTRY, *HALOPHILIC microorganisms

Abstract

A framework is proposed for a quantitative approach to studying habitability. Considerations of environmental supply and organismal demand of energy lead to the conclusions that power units are most appropriate and that the units for habitability become watts per organism. Extreme and plush environments are revealed to be on a habitability continuum, and extreme environments can be quantified as those where power supply only barely exceeds demand. Strategies for laboratory and field experiments are outlined that would quantify power supplies, power demands, and habitability. An example involving a comparison of various metabolisms pursued by halophiles is shown to be well on the way to a quantitative habitability analysis. [ABSTRACT FROM AUTHOR]

Published

2007

29. Protein Stability in Titan's Subsurface Water Ocean.

Author

Martin KP, MacKenzie SM, Barnes JW, and Ytreberg FM

Subjects

Ammonia chemistry, Earth, Planet, Evolution, Chemical, Extraterrestrial Environment, Extreme Environments, Molecular Dynamics Simulation, Oceans and Seas, Pressure, Protein Stability, Proteins chemistry, Temperature, Water chemistry, Exobiology methods, Protein Structure, Secondary, Proteins metabolism, Saturn

Abstract

Models of Titan predict that there is a subsurface ocean of water and ammonia under a layer of ice. Such an ocean would be important in the search for extraterrestrial life since it provides a potentially habitable environment. To evaluate how Earth-based proteins would behave in Titan's subsurface ocean environment, we used molecular dynamics simulations to calculate the properties of proteins with the most common secondary structure types (alpha helix and beta sheet) in both Earth and Titan-like conditions. The Titan environment was simulated by using a temperature of 300 K, a pressure of 1000 bar, and a eutectic mixture of water and ammonia. We analyzed protein compactness, flexibility, and backbone dihedral distributions to identify differences between the two environments. Secondary structures in the Titan environment were found to be less long-lasting, less flexible, and had small differences in backbone dihedral preferences ( e.g., in one instance a pi helix formed). These environment-driven differences could lead to changes in how these proteins interact with other biomolecules and therefore changes in how evolution would potentially shape proteins to function in subsurface ocean environments.

Published

2020

30. Bacterial Growth in Chloride and Perchlorate Brines: Halotolerances and Salt Stress Responses of Planococcus halocryophilus .

Author

Heinz J, Waajen AC, Airo A, Alibrandi A, Schirmack J, and Schulze-Makuch D

Subjects

Chlorides adverse effects, Cold Temperature adverse effects, Extreme Environments, Mars, Osmolar Concentration, Perchlorates adverse effects, Salts adverse effects, Salts chemistry, Cold-Shock Response physiology, Extraterrestrial Environment chemistry, Extremophiles physiology, Planococcaceae physiology, Salt Stress physiology

Abstract

Extraterrestrial environments encompass physicochemical conditions and habitats that are unknown on Earth, such as perchlorate-rich brines that can be at least temporarily stable on the martian surface. To better understand the potential for life in these cold briny environments, we determined the maximum salt concentrations suitable for growth (MSCg) of six different chloride and perchlorate salts at 25°C and 4°C for the extremotolerant cold- and salt-adapted bacterial strain Planococcus halocryophilus . Growth was measured through colony-forming unit (CFU) counts, while cellular and colonial phenotypic stress responses were observed through visible light, fluorescence, and scanning electron microscopy. Our data show the following: (1) The tolerance to high salt concentrations can be increased through a stepwise inoculation toward higher concentrations. (2) Ion-specific factors are more relevant for the growth limitation of P. halocryophilus in saline solutions than single physicochemical parameters like ionic strength or water activity. (3) P. halocryophilus shows the highest microbial sodium perchlorate tolerance described so far. However, (4) MSCg values are higher for all chlorides compared to perchlorates. (5) The MSCg for calcium chloride was increased by lowering the temperature from 25°C to 4°C, while sodium- and magnesium-containing salts can be tolerated at 25°C to higher concentrations than at 4°C. (6) Depending on salt type and concentration, P. halocryophilus cells show distinct phenotypic stress responses such as novel types of colony morphology on agar plates and biofilm-like cell clustering, encrustation, and development of intercellular nanofilaments. This study, taken in context with previous work on the survival of extremophiles in Mars-like environments, suggests that high-concentrated perchlorate brines on Mars might not be habitable to any present organism on Earth, but extremophilic microorganisms might be able to evolve thriving in such environments.

Published

2019

31. Microbial Populations in Antarctic Permafrost Biodiversity, State, Age, and Implication for Astrobiology.

Author

D.A. Gilichinsky, G.S. Wilson, E.I. Friedmann, C.P. McKay, R.S. Sletten, E.M. Rivkina, T.A. Vishnivetskaya, L.G. Erokhina, N.E. Ivanushkina, G.A. Kochkina, V.A. Shcherbakova, V.S. Soina, E.V. Spirina, E.A. Vorobyova, D.G. Fyodorov-Davydov, B. Hallet, S.M. Ozerskaya, V.A. Sorokovikov, K.S. Laurinavichyus, and A.V. Shatilovich

Subjects

*FROZEN ground, *ICE caps, *EXTREME environments, *HABITATS

Abstract

Antarctic permafrost soils have not received as much geocryological and biological study as has been devoted to the ice sheet, though the permafrost is more stable and older and inhabited by more microbes. This makes these soils potentially more informative and a more significant microbial repository than ice sheets. Due to the stability of the subsurface physicochemical regime, Antarctic permafrost is not an extreme environment but a balanced natural one. Up to 104viable cellsg, whose age presumably corresponds to the longevity of the permanently frozen state of the sediments, have been isolated from Antarctic permafrost. Along with the microbes, metabolic by-products are preserved. This presumed natural cryopreservation makes it possible to observe what may be the oldest microbial communities on Earth. Here, we describe the Antarctic permafrost habitat and biodiversity and provide a model for martian ecosystems. [ABSTRACT FROM AUTHOR]

Published

2007