Your search keyword '"Claudia Pacelli"' showing total 42 results

1. Special Issue: ‘Advances in Space Biology’

Author

Claudia Pacelli, Francesca Ferranti, and Marta Del Bianco

Subjects

n/a, Science

Abstract

As we enter a new era of space exploration, space biology is at the forefront of both robotic and human space programs [...]

Published

2024

2. Non-destructive real-time analysis of plant metabolite accumulation in radish microgreens under different LED light recipes

Author

Marco Garegnani, Carla Sandri, Claudia Pacelli, Francesca Ferranti, Elisabetta Bennici, Angiola Desiderio, Luca Nardi, and Maria Elena Villani

Subjects

microgreen, hydroponic, space environment, LED lights, fluorescence-based non-destructive techniques, Plant culture, SB1-1110

Abstract

IntroductionThe future of human space missions relies on the ability to provide adequate food resources for astronauts and also to reduce stress due to the environment (microgravity and cosmic radiation). In this context, microgreens have been proposed for the astronaut diet because of their fast-growing time and their high levels of bioactive compounds and nutrients (vitamins, antioxidants, minerals, etc.), which are even higher than mature plants, and are usually consumed as ready-to-eat vegetables.MethodsOur study aimed to identify the best light recipe for the soilless cultivation of two cultivars of radish microgreens (Raphanus sativus, green daikon, and rioja improved) harvested eight days after sowing that could be used for space farming. The effects on plant metabolism of three different light emitting diodes (LED) light recipes (L1—20% red, 20% green, 60% blue; L2—40% red, 20% green, 40% blue; L3—60% red, 20% green, 20% blue) were tested on radish microgreens hydroponically grown. A fluorimetric-based technique was used for a real-time non-destructive screening to characterize plant methabolism. The adopted sensors allowed us to quantitatively estimate the fluorescence of flavonols, anthocyanins, and chlorophyll via specific indices verified by standardized spectrophotometric methods. To assess plant growth, morphometric parameters (fresh and dry weight, cotyledon area and weight, hypocotyl length) were analyzed.ResultsWe observed a statistically significant positive effect on biomass accumulation and productivity for both cultivars grown under the same light recipe (40% blue, 20% green, 40% red). We further investigated how the addition of UV and/or far-red LED lights could have a positive effect on plant metabolite accumulation (anthocyanins and flavonols).DiscussionThese results can help design plant-based bioregenerative life-support systems for long-duration human space exploration, by integrating fluorescence-based non-destructive techniques to monitor the accumulation of metabolites with nutraceutical properties in soilless cultivated microgreens.

Published

2024

3. Survival, metabolic activity, and ultrastructural damages of Antarctic black fungus in perchlorates media

Author

Alessia Cassaro, Claudia Pacelli, and Silvano Onofri

Subjects

perchlorates tolerance, deliquescence, fungal growth, metabolic activity, eukaryotic organism, Microbiology, QR1-502

Abstract

Evidence from recent Mars landers identified the presence of perchlorates salts at 1 wt % in regolith and their widespread distribution on the Martian surface that has been hypothesized as a critical chemical hazard for putative life forms. However, the hypersaline environment may also potentially preserve life and its biomolecules over geological timescales. The high concentration of natural perchlorates is scarcely reported on Earth. The presence of perchlorates in soil and ice has been recorded in some extreme environments including the McMurdo Dry Valleys in Antarctica, one of the best terrestrial analogues for Mars. In the frame of “Life in space” Italian astrobiology project, the polyextremophilic black fungus Cryomyces antarcticus, a eukaryotic test organism isolated from the Antarctic cryptoendolithic communities, has been tested for its resistance, when grown on different hypersaline substrata. In addition, C. antarcticus was grown on Martian relevant perchlorate medium (0.4 wt% of Mg(ClO4)2 and 0.6 wt% of Ca(ClO4)2) to investigate the possibility for the fungus to survive in Martian environment. Here, the results indicate a good survivability and metabolic activity recovery of the black fungus when grown on four Martian relevant perchlorates. A low percentage of damaged cellular membranes have been found, confirming the ultrastructural investigation.

Published

2022

4. Metabolomic Profile of the Fungus Cryomyces antarcticus Under Simulated Martian and Space Conditions as Support for Life-Detection Missions on Mars

Author

Federica Gevi, Patrick Leo, Alessia Cassaro, Claudia Pacelli, Jean-Pierre Paul de Vera, Elke Rabbow, Anna Maria Timperio, and Silvano Onofri

Subjects

extremophilic microorganism, LC-MS, metabolites, osmolytes, stress resistance, biosignature, Microbiology, QR1-502

Abstract

The identification of traces of life beyond Earth (e.g., Mars, icy moons) is a challenging task because terrestrial chemical-based molecules may be destroyed by the harsh conditions experienced on extraterrestrial planetary surfaces. For this reason, studying the effects on biomolecules of extremophilic microorganisms through astrobiological ground-based space simulation experiments is significant to support the interpretation of the data that will be gained and collected during the ongoing and future space exploration missions. Here, the stability of the biomolecules of the cryptoendolithic black fungus Cryomyces antarcticus, grown on two Martian regolith analogues and on Antarctic sandstone, were analysed through a metabolomic approach, after its exposure to Science Verification Tests (SVTs) performed in the frame of the European Space Agency (ESA) Biology and Mars Experiment (BIOMEX) project. These tests are building a set of ground-based experiments performed before the space exposure aboard the International Space Station (ISS). The analysis aimed to investigate the effects of different mineral mixtures on fungal colonies and the stability of the biomolecules synthetised by the fungus under simulated Martian and space conditions. The identification of a specific group of molecules showing good stability after the treatments allow the creation of a molecular database that should support the analysis of future data sets that will be collected in the ongoing and next space exploration missions.

Published

2022

5. The Ground-Based BIOMEX Experiment Verification Tests for Life Detection on Mars

Author

Claudia Pacelli, Alessia Cassaro, Ilaria Catanzaro, Mickael Baqué, Alessandro Maturilli, Ute Böttger, Elke Rabbow, Jean-Pierre Paul de Vera, and Silvano Onofri

Subjects

biosignature, dark pigments, polysaccharides, polychromatic radiation, simulated conditions, Mars, Science

Abstract

The success of an astrobiological search for life campaign on Mars, or other planetary bodies in the Solar System, relies on the detectability of past or present microbial life traces, namely, biosignatures. Spectroscopic methods require little or no sample preparation, can be repeated almost endlessly, and can be performed in contact or even remotely. Such methods are therefore ideally suited to use for the detection of biosignatures, which can be confirmed with supporting instrumentation. Here, we discuss the use of Raman and Fourier Transform Infrared (FT-IR) spectroscopies for the detection and characterization of biosignatures from colonies of the fungus Cryomyces antarcticus, grown on Martian analogues and exposed to increasing doses of UV irradiation under dried conditions. The results report significant UV-induced DNA damage, but the non-exceeding of thresholds for allowing DNA amplification and detection, while the spectral properties of the fungal melanin remained unaltered, and pigment detection and identification was achieved via complementary analytical techniques. Finally, this work found that fungal cell wall compounds, likely chitin, were not degraded, and were still detectable even after high UV irradiation doses. The implications for the preservation and detection of biosignatures in extraterrestrial environments are discussed.

Published

2021

6. Fungal Biomarkers Stability in Mars Regolith Analogues after Simulated Space and Mars-like Conditions

Author

Alessia Cassaro, Claudia Pacelli, Mickael Baqué, Jean-Pierre Paul de Vera, Ute Böttger, Lorenzo Botta, Raffaele Saladino, Elke Rabbow, and Silvano Onofri

Subjects

spectroscopy, Mars exploration, life-detection, pigments, nucleic acids, Biology (General), QH301-705.5

Abstract

The discovery of life on other planets and moons in our solar system is one of the most important challenges of this era. The second ExoMars mission will look for traces of extant or extinct life on Mars. The instruments on board the rover will be able to reach samples with eventual biomarkers until 2 m of depth under the planet’s surface. This exploration capacity offers the best chance to detect biomarkers which would be mainly preserved compared to samples on the surface which are directly exposed to harmful environmental conditions. Starting with the studies of the endolithic meristematic black fungus Cryomyces antarcticus, which has proved its high resistance under extreme conditions, we analyzed the stability and the resistance of fungal biomarkers after exposure to simulated space and Mars-like conditions, with Raman and Gas Chromatography–Mass Spectrometry, two of the scientific payload instruments on board the rover.

Published

2021

7. Vegetation, pH and Water Content as Main Factors for Shaping Fungal Richness, Community Composition and Functional Guilds Distribution in Soils of Western Greenland

Author

Fabiana Canini, Laura Zucconi, Claudia Pacelli, Laura Selbmann, Silvano Onofri, and József Geml

Subjects

metabarcoding, functional guilds, shrub encroachment, edaphic factors, ITS1, Microbiology, QR1-502

Abstract

Fungi are the most abundant and one of the most diverse components of arctic soil ecosystems, where they are fundamental drivers of plant nutrient acquisition and recycling. Nevertheless, few studies have focused on the factors driving the diversity and functionality of fungal communities associated with these ecosystems, especially in the scope of global warming that is particularly affecting Greenland and is leading to shrub expansion, with expected profound changes of soil microbial communities. We used soil DNA metabarcoding to compare taxonomic and functional composition of fungal communities in three habitats [bare ground (BG), biological soil crusts (BSC), and vascular vegetation (VV) coverage] in Western Greenland. Fungal richness increased with the increasing complexity of the coverage, but BGs and BSCs samples showed the highest number of unique OTUs. Differences in both fungal community composition and distribution of functional guilds identified were correlated with edaphic factors (mainly pH and water content), in turn connected with the different type of coverage. These results suggest also possible losses of diversity connected to the expansion of VV and possible interactions among the members of different functional guilds, likely due to the nutrient limitation, with potential effects on elements recycling.

Published

2019

8. Insights into the Survival Capabilities of Cryomyces antarcticus Hydrated Colonies after Exposure to Fe Particle Radiation

Author

Claudia Pacelli, Alessia Cassaro, Loke M. Siong, Lorenzo Aureli, Ralf Moeller, Akira Fujimori, Igor Shuryak, and Silvano Onofri

Subjects

radiation, melanin, DNA, radioresistance, metabolically active cells, Biology (General), QH301-705.5

Abstract

The modern concept of the evolution of Mars assumes that life could potentially have originated on the planet Mars, possibly during the end of the late heavy bombardment, and could then be transferred to other planets. Since then, physical and chemical conditions on Mars changed and now strongly limit the presence of terrestrial-like life forms. These adverse conditions include scarcity of liquid water (although brine solutions may exist), low temperature and atmospheric pressure, and cosmic radiation. Ionizing radiation is very important among these life-constraining factors because it damages DNA and other cellular components, particularly in liquid conditions where radiation-induced reactive oxidants diffuse freely. Here, we investigated the impact of high doses (up to 2 kGy) of densely-ionizing (197.6 keV/µm), space-relevant iron ions (corresponding on the irradiation that reach the uppermost layer of the Mars subsurface) on the survival of an extremophilic terrestrial organism—Cryomyces antarcticus—in liquid medium and under atmospheric conditions, through different techniques. Results showed that it survived in a metabolically active state when subjected to high doses of Fe ions and was able to repair eventual DNA damages. It implies that some terrestrial life forms can withstand prolonged exposure to space-relevant ion radiation.

Published

2021

9. Advantages and Limitations of Current Microgravity Platforms for Space Biology Research

Author

Francesca Ferranti, Marta Del Bianco, and Claudia Pacelli

Subjects

microgravity, ground-based facility, international Space station, clinostat, RPM, bed rest, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Human Space exploration has created new challenges and new opportunities for science. Reaching beyond the Earth’s surface has raised the issue of the importance of gravity for the development and the physiology of biological systems, while giving scientists the tools to study the mechanisms of response and adaptation to the microgravity environment. As life has evolved under the constant influence of gravity, gravity affects biological systems at a very fundamental level. Owing to limited access to spaceflight platforms, scientists rely heavily on on-ground facilities that reproduce, to a different extent, microgravity or its effects. However, the technical constraints of counterbalancing the gravitational force on Earth add complexity to data interpretation. In-flight experiments are also not without their challenges, including additional stressors, such as cosmic radiation and lack of convection. It is thus extremely important in Space biology to design experiments in a way that maximizes the scientific return and takes into consideration all the variables of the chosen setup, both on-ground or on orbit. This review provides a critical analysis of current ground-based and spaceflight facilities. In particular, the focus was given to experimental design to offer the reader the tools to select the appropriate setup and to appropriately interpret the results.

Published

2020

10. Iron Ion Particle Radiation Resistance of Dried Colonies of Cryomyces antarcticus Embedded in Martian Regolith Analogues

Author

Lorenzo Aureli, Claudia Pacelli, Alessia Cassaro, Akira Fujimori, Ralf Moeller, and Silvano Onofri

Subjects

cosmic rays, accelerated iron ions, Mars, fungi, life on Mars, Science

Abstract

Among the celestial bodies in the Solar System, Mars currently represents the main target for the search for life beyond Earth. However, its surface is constantly exposed to high doses of cosmic rays (CRs) that may pose a threat to any biological system. For this reason, investigations into the limits of resistance of life to space relevant radiation is fundamental to speculate on the chance of finding extraterrestrial organisms on Mars. In the present work, as part of the STARLIFE project, the responses of dried colonies of the black fungus Cryomyces antarcticus Culture Collection of Fungi from Extreme Environments (CCFEE) 515 to the exposure to accelerated iron (LET: 200 keV/μm) ions, which mimic part of CRs spectrum, were investigated. Samples were exposed to the iron ions up to 1000 Gy in the presence of Martian regolith analogues. Our results showed an extraordinary resistance of the fungus in terms of survival, recovery of metabolic activity and DNA integrity. These experiments give new insights into the survival probability of possible terrestrial-like life forms on the present or past Martian surface and shallow subsurface environments.

Published

2020

11. The Responses of the Black Fungus Cryomyces Antarcticus to High Doses of Accelerated Helium Ions Radiation within Martian Regolith Simulants and Their Relevance for Mars

Author

Claudia Pacelli, Alessia Cassaro, Lorenzo Aureli, Ralf Moeller, Akira Fujimori, and Silvano Onofri

Subjects

Galactic Cosmic Rays (GCRs), Mars environment, black fungi, survival, UV-vis spectroscopy, resistance, Science

Abstract

One of the primary current astrobiological goals is to understand the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of accelerated He ions (150 MeV/n, up to 1 kGy) as a component of the galactic cosmic rays on the black fungus C. antarcticus when mixed with Antarctic sandstones—the substratum of its natural habitat—and two Martian regolith simulants, which mimics two different evolutionary stages of Mars. The high dose of 1 kGy was used to assess the effect of dose accumulation in dormant cells within minerals, under long-term irradiation estimated on a geological time scale. The data obtained suggests that viable Earth-like microorganisms can be preserved in the dormant state in the near-surface scenario for approximately 322.000 and 110.000 Earth years within Martian regolith that mimic early and present Mars environmental conditions, respectively. In addition, the results of the study indicate the possibility of maintaining traces within regolith, as demonstrated by the identification of melanin pigments through UltraViolet-visible (UV-vis) spectrophotometric approach.

Published

2020

12. Cellular Responses of the Lichen Circinaria gyrosa in Mars-Like Conditions

Author

Rosa de la Torre Noetzel, Ana Z. Miller, José M. de la Rosa, Claudia Pacelli, Silvano Onofri, Leopoldo García Sancho, Beatriz Cubero, Andreas Lorek, David Wolter, and Jean P. de Vera

Subjects

Mars environment, extremotolerance, lichens, Circinaria gyrosa, photosynthetic activity, analytical pyrolysis, Microbiology, QR1-502

Abstract

Lichens are extremely resistant organisms that colonize harsh climatic areas, some of them defined as “Mars-analog sites.” There still remain many unsolved questions as to how lichens survive under such extreme conditions. Several studies have been performed to test the resistance of various lichen species under space and in simulated Mars-like conditions. The results led to the proposal that Circinaria gyrosa (Lecanoromycetes, Ascomycota) is one of the most durable astrobiological model lichens. However, although C. gyrosa has been exposed to Mars-like environmental conditions while in a latent state, it has not been exposed in its physiologically active mode. We hypothesize that the astrobiological test system “Circinaria gyrosa,” could be able to be physiologically active and to survive under Mars-like conditions in a simulation chamber, based on previous studies performed at dessicated-dormant stage under simulated Mars-like conditions, that showed a complete recover of the PSII activity (Sánchez et al., 2012). Epifluorescence and confocal laser scanning microscopy (CLSM) showed that living algal cells were more abundant in samples exposed to niche conditions, which simulated the conditions in micro-fissures and micro-caves close to the surface that have limited scattered or time-dependent light exposure, than in samples exposed to full UV radiation. The medulla was not structurally affected, suggesting that the niche exposure conditions did not disturb the lichen thalli structure and morphology as revealed by field emission scanning electron microscopy (FESEM). In addition, changes in the lichen thalli chemical composition were determined by analytical pyrolysis. The chromatograms resulting from analytical pyrolysis at 500°C revealed that lichen samples exposed to niche conditions and full UV radiation consisted primarily of glycosidic compounds, lipids, and sterols, which are typical constituents of the cell walls. However, specific differences could be detected and used as markers of the UV-induced damage to the lichen membranes. Based on its viability responses after rehydration, our study shows that the test lichen survived the 30-day incubation in the Mars chamber particularly under niche conditions. However, the photobiont was not able to photosynthesize under the Mars-like conditions, which indicates that the surface of Mars is not a habitable place for C. gyrosa.

Published

2018

13. Cryptoendolithic Antarctic Black Fungus Cryomyces antarcticus Irradiated with Accelerated Helium Ions: Survival and Metabolic Activity, DNA and Ultrastructural Damage

Author

Claudia Pacelli, Laura Selbmann, Ralf Moeller, Laura Zucconi, Akira Fujimori, and Silvano Onofri

Subjects

cosmic rays, extremophiles, extremotolerance, fungi, HZE particles, He2+ ions, Microbiology, QR1-502

Abstract

Space represents an extremely harmful environment for life and survival of terrestrial organisms. In the last decades, a considerable deal of attention was paid to characterize the effects of spaceflight relevant radiation on various model organisms. The aim of this study was to test the survival capacity of the cryptoendolithic black fungus Cryomyces antarcticus CCFEE 515 to space relevant radiation, to outline its endurance to space conditions. In the frame of an international radiation campaign, dried fungal colonies were irradiated with accelerated Helium ion (150 MeV/n, LET 2.2 keV/μm), up to a final dose of 1,000 Gy, as one of the space-relevant ionizing radiation. Results showed that the fungus maintained high survival and metabolic activity with no detectable DNA and ultrastructural damage, even after the highest dose irradiation. These data give clues on the resistance of life toward space ionizing radiation in general and on the resistance and responses of eukaryotic cells in particular.

Published

2017

14. Integrity of the DNA and Cellular Ultrastructure of Cryptoendolithic Fungi in Space or Mars Conditions: A 1.5-Year Study at the International Space Station

Author

Silvano Onofri, Laura Selbmann, Claudia Pacelli, Jean Pierre de Vera, Gerda Horneck, John E. Hallsworth, and Laura Zucconi

Subjects

cryptoendolithic black fungi, DNA and cellular damage, EXPOSE-E, LIFE experiment, space exposure and Mars conditions, ionizing- and ultra-violet radiation, Science

Abstract

The black fungi Cryomyces antarcticus and Cryomyces minteri are highly melanized and are resilient to cold, ultra-violet, ionizing radiation and other extreme conditions. These microorganisms were isolated from cryptoendolithic microbial communities in the McMurdo Dry Valleys (Antarctica) and studied in Low Earth Orbit (LEO), using the EXPOSE-E facility on the International Space Station (ISS). Previously, it was demonstrated that C. antarcticus and C. minteri survive the hostile conditions of space (vacuum, temperature fluctuations, and the full spectrum of extraterrestrial solar electromagnetic radiation), as well as Mars conditions that were simulated in space for a 1.5-year period. Here, we qualitatively and quantitatively characterize damage to DNA and cellular ultrastructure in desiccated cells of these two species, within the frame of the same experiment. The DNA and cells of C. antarcticus exhibited a higher resistance than those of C. minteri. This is presumably attributable to the thicker (melanized) cell wall of the former. Generally, DNA was readily detected (by PCR) regardless of exposure conditions or fungal species, but the C. minteri DNA had been more-extensively mutated. We discuss the implications for using DNA, when properly shielded, as a biosignature of recently extinct or extant life.

Published

2018

15. A preliminary survey of the cellular responses of the black fungus Cryomyces antarcticus to long and short‐term dehydration.

Author

Alessia, Cassaro, Federica, D' Alò, Claudia, Pacelli, Barbara, Cavalazzi, Laura, Zucconi, and Silvano, Onofri

Subjects

WATER supply, CONDITIONED response, ASTROBIOLOGY, DEHYDRATION, VALLEYS

Abstract

The McMurdo Dry Valleys in Southern Victoria Land, Antarctica, are known for their extreme aridity, cold, and nutrient‐poor conditions. These valleys provide a valuable comparison to environments on Mars. The survival of microorganisms in these areas hinges on their ability to withstand dehydration due to the limited availability of liquid water. Some microorganisms have adapted to survive extended periods of metabolic inactivity and dehydration, a physiological response to the harsh conditions in which they exist. This adaptation is significant for astrobiology studies as it allows for testing the resilience of microorganisms under extraterrestrial conditions, exploring the boundaries and potential for life beyond Earth. In this study, we examined the survivability, metabolic activity, cellular membrane integrity, and ultrastructural damage of Cryomyces antarcticus, a eukaryotic organism used for astrobiological studies, following two dehydration processes. We conducted a fast dehydration process, simulating what happens on the surface of Antarctic rocks under typical environmental conditions, and a slow dehydration process, which is commonly used in astrobiological experiments. Our findings revealed a higher percentage of damaged cells following slow dehydration treatments, confirming that rapid dehydration reflects the adaptability of microorganisms to respond to sudden and drastic changes in the Antarctic environment. [ABSTRACT FROM AUTHOR]

Published

2024

16. The Amazing Journey ofCryomyces antarcticusfrom Antarctica to Space

Author

Silvano Onofri, Laura Zucconi, Claudia Pacelli, and Laura Selbmann

Subjects

Cryomyces antarcticus, medicine.drug_formulation_ingredient, International Space Station, medicine, Mars Exploration Program, Space (mathematics), Geology, Astrobiology

Published

2020

17. The Amyloid Aggregation Study on Board the International Space Station, an Update

Author

Francesca A. Scaramuzzo, Cristina Casalone, Michele Trichilo, Giovanni Valentini, Marino Crisconio, Marialuisa Casella, Simona Sennato, Stefano Sirigu, Chiara Piacenza, Franco Cardone, Marco Crescenzi, Gianni Truscelli, Alessandro Crisafi, Marco Sbriccoli, Dario Castagnolo, Claudia Pacelli, Cristiano Corona, Serena Camerini, Sara Piccirillo, Flavia Porreca, Gabriele Mascetti, Elena Berrone, Maurizio Pocchiari, and Alessandra Favole

Subjects

On board, Aeronautics, business.industry, Computer science, Payload, Amyloid aggregation, International Space Station, Stowage, Pharmacology (medical), Aerospace, business, Space exploration

Abstract

“Amyloid Aggregation” is an Italian Space Agency (ASI)-granted project designed to investigate if and how beta amyloid peptides aggregation is affected by microgravity, in the light of a possible professional risk in astronauts on long-lasting space missions. Researchers of the Istituto Zooprofilattico Sperimentale del Piemonte Liguria e Valle d'Aosta (IZSPLV) and the Istituto Superiore di Sanita (Ist.Sup.San) conceived the project while the Aerospace Logistics Technology Engineering Company (ALTEC) developed the payload. ARGOTEC/Telespazio (UTISS Team) supported safety evaluation, payload manifesting and qualification processes for a safe and efficient delivery, utilization, and integration on board the International Space Station (ISS), and finally recovery of the experimental hardware once returned to Earth. The hardware consisted of 48 special jars containing 6 different time period experimental groups and 2 control groups. In August 2019, during the “BEYOND” mission on board the ISS, astronaut Luca Parmitano activated individual jars according to a defined protocol. At the end of each Incubation Time Periods (ITPs), the samples were transferred in the cold stowage system to stop the aggregation reaction until the analysis after re-entry. Forty-eight identical samples have been prepared and activated in November 2019 on Earth. ALTEC developed jars and packaging for space transportation, qualified and delivered the flight hardware, according to requirements. We here provide an update on the optimization of analytical techniques described in the project specifically intended to warrant an up-to-date, robust and reliable examination of samples that we plan to accomplish in the next months within the proposed timeframe of the project.

Published

2020

18. Advantages and Limitations of Current Microgravity Platforms for Space Biology Research

Author

Claudia Pacelli, Francesca Ferranti, and Marta Del Bianco

Subjects

Gravity (chemistry), RPM, ground-based facility, bed rest, Space (commercial competition), Spaceflight, 01 natural sciences, lcsh:Technology, law.invention, lcsh:Chemistry, 03 medical and health sciences, clinostat, law, 0103 physical sciences, International Space Station, General Materials Science, CubeSat, Adaptation (computer science), 010303 astronomy & astrophysics, Instrumentation, lcsh:QH301-705.5, 030304 developmental biology, Fluid Flow and Transfer Processes, 0303 health sciences, international Space station, lcsh:T, Process Chemistry and Technology, General Engineering, microgravity, lcsh:QC1-999, Computer Science Applications, Current (stream), lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Systems engineering, Orbit (dynamics), lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Human Space exploration has created new challenges and new opportunities for science. Reaching beyond the Earth’s surface has raised the issue of the importance of gravity for the development and the physiology of biological systems, while giving scientists the tools to study the mechanisms of response and adaptation to the microgravity environment. As life has evolved under the constant influence of gravity, gravity affects biological systems at a very fundamental level. Owing to limited access to spaceflight platforms, scientists rely heavily on on-ground facilities that reproduce, to a different extent, microgravity or its effects. However, the technical constraints of counterbalancing the gravitational force on Earth add complexity to data interpretation. In-flight experiments are also not without their challenges, including additional stressors, such as cosmic radiation and lack of convection. It is thus extremely important in Space biology to design experiments in a way that maximizes the scientific return and takes into consideration all the variables of the chosen setup, both on-ground or on orbit. This review provides a critical analysis of current ground-based and spaceflight facilities. In particular, the focus was given to experimental design to offer the reader the tools to select the appropriate setup and to appropriately interpret the results.

Published

2021

19. Fungal biomarkers are detectable in Martian rock-analogues after space exposure: implications for the search of life on Mars

Author

Laura Zucconi, Mickael Baqué, Lorenzo Botta, Alessia Cassaro, Jean-Pierre de Vera, Alessandro Maturilli, Raffaele Saladino, Silvano Onofri, Laura Selbmann, Elke Rabbow, Ute Böttger, René Demets, and Claudia Pacelli

Subjects

Martian, spectroscopy, 010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), pigments, Mars, Context (language use), Mars Exploration Program, Mars surface, Life on Mars, Exploration of Mars, exploration missions, 01 natural sciences, Astrobiology, Prebiotic chemistry, Low earth orbit, life detection, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), 010303 astronomy & astrophysics, Ecology, Evolution, Behavior and Systematics, Biomarkers, 0105 earth and related environmental sciences

Abstract

Mars is a primary target of astrobiological interest: its past environmental conditions may have been favourable to the emergence of a prebiotic chemistry and, potentially, biological activity. In situ exploration is currently underway at the Mars surface, and the subsurface (2 m depth) will be explored in the future ESA ExoMars mission. In this context, BIOlogy and Mars EXperiment was performed to evaluate the stability and detectability of organic biomarkers under space and Mars-like conditions. Our data suggested that some target molecules, namely melanin, azelaic acid and nucleic acids, can be detected even after 16 months exposure to Low Earth Orbit conditions by multidisciplinary approaches. We used the same techniques as onboard the ExoMars rover, as Raman and infrared spectroscopies and gas chromatograph-mass spectrometer, and polymerase chain reaction even if this is not planned for the imminent mission to Mars. These results should be taken into account for future Mars exploration.

Published

2021

20. The Italian National Project of Astrobiology—Life in Space—Origin, Presence, Persistence of Life in Space, from Molecules to Extremophiles

Author

Onofri, Silvano, Balucani, Nadia, Barone, Vincenzo, Benedetti, Pietro, Billi, Daniela, Balbi, Amedeo, Brucato, John Robert, Cobucci-Ponzano, Beatrice, Costanzo, Giovanna, La Rocca, Nicoletta, Moracci, Marco, Saladino, Raffaele, Vladilo, Giovanni, Niccolò, Albertini, Mariano, Battistuzzi, Julien, Bloino, Lorenzo, Botta, Piergiorgio, Casavecchia, Alessia, Cassaro, Riccardo, Claudi, Lorenzo, Cocola, Alberto, Coduti, Paola Di Donato, Ernesto Di Mauro, Luca, Dore, Stefano, Falcinelli, Marco, Fulle, Stavro, Ivanovski, Andrea, Lombardi, Giordano, Mancini, Michele, Maris, Luisa, Maurelli, Giuseppe, Murante, Rodolfo, Negri, Claudia, Pacelli, Isabella, Pagano, Davide, Piccinino, Luca, Poletto, Giorgio, Prantera, Cristina, Puzzarini, Sergio, Rampino, Caterina, Ripa, Marzio, Rosi, Monica, Sanna, Laura, Selbmann, Laura, Silva, Dimitrios, Skouteris, Andrea, Strazzulli, Nicola, Tasinato, Anna Maria Timperio, Andrea, Tozzi, Gian Paolo Tozzi, Trainotti, Livio, Piero, Ugliengo, Luigi, Vaccaro, and Laura Zucconi, Onofri, S., Balucani, N., Barone, V., Benedetti, P., Billi, D., Balbi, A., Brucato, J. R., Cobucci-Ponzano, B., Costanzo, G., Rocca, N. L., Moracci, M., Saladino, R., Vladilo, G., Albertini, N., Battistuzzi, M., Bloino, J., Botta, L., Casavecchia, P., Cassaro, A., Claudi, R., Cocola, L., Coduti, A., Di Donato, P., Di Mauro, E., Dore, L., Falcinelli, S., Fulle, M., Ivanovski, S., Lombardi, A., Mancini, G., Maris, M., Maurelli, L., Murante, G., Negri, R., Pacelli, C., Pagano, I., Piccinino, D., Poletto, L., Prantera, G., Puzzarini, C., Rampino, S., Ripa, C., Rosi, M., Sanna, M., Selbmann, L., Silva, L., Skouteris, D., Strazzulli, A., Tasinato, N., Timperio, A. M., Tozzi, A., Tozzi, G. P., Trainotti, L., Ugliengo, P., Vaccaro, L., Zucconi, L., Onofri S., Balucani N., Barone V., Benedetti P., Billi D., Balbi A., Brucato J.R., Cobucci-Ponzano B., Costanzo G., Rocca N.L., Moracci M., Saladino R., Vladilo G., Albertini N., Battistuzzi M., Bloino J., Botta L., Casavecchia P., Cassaro A., Claudi R., Cocola L., Coduti A., Di Donato P., Di Mauro E., Dore L., Falcinelli S., Fulle M., Ivanovski S., Lombardi A., Mancini G., Maris M., Maurelli L., Murante G., Negri R., Pacelli C., Pagano I., Piccinino D., Poletto L., Prantera G., Puzzarini C., Rampino S., Ripa C., Rosi M., Sanna M., Selbmann L., Silva L., Skouteris D., Strazzulli A., Tasinato N., Timperio A.M., Tozzi A., Tozzi G.P., Trainotti L., Ugliengo P., Vaccaro L., and Zucconi L.

Subjects

Persistence (psychology), Extremophiles, Exobiology, Extraterrestrial Environment, Origin of Life, Origin of Life in Space, Space (commercial competition), Astrobiology, Life in Space, From Molecules to Extremophiles, Astrobiology, Abiogenesis, From Molecules to Extremophiles, Extremophile, Life in Space, Origin of life, space, exobiology, News and Views, extremophiles, Settore CHIM/12 - Chimica dell'Ambiente e dei Beni Culturali, Settore FIS/05, Chemistry, space, Agricultural and Biological Sciences (miscellaneous), Space and Planetary Science, astrobiology, from Molecules to Extremophiles in space

Abstract

THE ''LIfe in Space'' project was funded in the wake of the Italian Space Agency's proposal for the development of a network of institutions and laboratories conceived to implement Italian participation in space astrobiology experiments. Of primary concern for this project is the study of the origin of life in the Universe, a focus that will promote investigation into prebiotic chemistry in various possible scenarios, whether in polar or nonpolar solvents (e.g., Titan's environment). Such results will link with study of the effects of simulated space conditions on possible chemical bio- signatures. The limits of life as we know it will be investigated in ground-based experiments with microorganisms that have already demonstrated their resistance to extreme environments on Earth and to real or simulated space conditions. The potential survival of microorganisms will also be examined with up-to-date molecular methods. The ability of some microorganisms to produce atmospheric and surface biosignatures when exposed to simulated conditions will be tested and compared with the possible existence of bio- signatures on potentially habitable exoplanets. Furthermore, the search for potentially habitable exoplanets, with space- based observational methods, will be optimized by way of dedicated climate models with the capacity to predict the detectability of atmospheric biosignatures for a broad range of planetary conditions. The project embraces the four most important topics in astrobiological research, as listed below, along with relevant contributions from the participating Italian institutions. Origins and evolution of organic compounds of biological significance in space (comets, asteroids, rocky planets, and moons); Prebiotic syntheses, origin of life, and early life; The limits of life and biological habitability: origin, evolution and adaptation of life in extreme environments on Earth and in space; Biomarkers for life detection in the Solar System and on exoplanets.

Published

2020

21. Metabolomic Profile of the Fungus

Author

Federica, Gevi, Patrick, Leo, Alessia, Cassaro, Claudia, Pacelli, Jean-Pierre Paul, de Vera, Elke, Rabbow, Anna Maria, Timperio, and Silvano, Onofri

Abstract

The identification of traces of life beyond Earth (e.g., Mars, icy moons) is a challenging task because terrestrial chemical-based molecules may be destroyed by the harsh conditions experienced on extraterrestrial planetary surfaces. For this reason, studying the effects on biomolecules of extremophilic microorganisms through astrobiological ground-based space simulation experiments is significant to support the interpretation of the data that will be gained and collected during the ongoing and future space exploration missions. Here, the stability of the biomolecules of the cryptoendolithic black fungus

Published

2021

22. AstroBio CubeSat: operational design of a CubeSat for astrobiological purposes in radiative environment

Author

John Robert Brucato, Augusto Nascetti, Donato Calabria, Mara Mirasoli, Luigi Schirone, Ilaria Trozzi, D. Paglialunga, Michele Balsamo, Stefano Carletta, Lorenzo Iannascoli, G. Impresario, Liyana Popova, Laura Anfossi, Simone Pirrotta, Antonio Bardi, A. Meneghin, Giovanni Poggiali, and Claudia Pacelli

Subjects

Operational design, business.industry, Radiative transfer, Environmental science, CubeSat, Aerospace engineering, business

Abstract

Introduction Astrobiology is an interdisciplinary field covered by only a few CubeSat missions so far. Moreover, no CubeSat mission has ever mounted miniaturized technology for the purpose of searching for molecular evidences of life in space. AstroBio CubeSat (ABCS) is a 3U CubeSat selected by the European Space Agency (ESA) to be launched in spring 2022 with the Vega C maiden flight, as piggy back passenger of the ASI LARES2 mission. ABCS will host a payload assembly based on Lab-on-Chip (LoC) technology for biomarkers detection and will be deployed along a circular orbit with altitude of about 5900 km and inclination of 7°, therefore crossing the inner Van Allen belt where the radiation flux is close to its maximum. Due to the harsh environment, ABCS payload and subsystems will be likely exposed to damages and degradations of electronics and performances, thus the payload assembly and the operational architecture were designed to be as much dependable as possible. This approach should constitute the first step to implement a mature technology with the aim to check the stability of chemicals and biomolecules involved in space experiments. This work reports an overview of ABCS architecture and the approach chosen for its operational design. ABCS Architecture ABCS objective is to test in space an automatic in-situ multiparameter LoC [1], which exploits luminol injection and enzymatic bio-mimicking assays on a functionalized 3D wax-printed origami. Luminol will be transported by capillarity to reaction sites with immobilized biomolecules targets where the reactions will trigger chemiluminescence, detected by means of hydrogenated amorphous silicon (a-Si:H) photodiodes deposited on a borosilicate glass substrate and connected to a photocurrent readout board [2]. The described payload consists in an experiment board hosting the LoC and a support board containing peristaltic pumps for luminol injection, drivers for pumps, radiation field effect transistors (RADFETs) and pressure/temperature sensors. The LoC architecture allows to repeat the experiment up to six times. In addition to RADFETs, ABCS mounts an ancillary radiation dose sensor (ARDS), developed by Thales Alenia Space, with the aim to assess the radiation effects. The ARDS is able to measure different amounts of current, until its failure, depending on the dose acquired. To mitigate the effects of the expected very high flux of charged particles, an extra tungsten layer shielding was mounted on each side panel and all the main subsystems (experiment and support board, batteries and EPS board, on-board computer (OBC), telemetry, tracking and control board), were placed inside a 5 mm thick aluminium box. At the same time, to keep the temperature range (from 4°C to 20°C) and operative pressure (about 1 atm) required to allow the LoC capillarity effect and to prevent reagents degradation, the box was sealed and a thermal control system, composed by a multi-layer insulation and an active heather mounted inside the box, was implemented. ABCS Mission Design ABCS will be deployed in an approximately circular orbit at about 5900 km altitude and 70° of inclination, spending a significant amount of the orbital period within the inner Van Allen belt, very close to its radiation peak point. ABCS ground operations will be mainly performed from the School of Aerospace Engineering (SIA) Ground Station. Simulations show that SIA will have access to ABCS 4 times a day, with an average duration of about 65 minutes. For this reason, a network of radioamateurs and third part ground stations will be involved for supporting the collection of the telemetry and science data packages and possibly uplink commands. ABCS Operations The assumption we made is that ABCS should be able to perform the payload operations in a completely autonomous manner. As we know, radiation flux will most likely induce several errors on electronics and performances, causing potential mission failure due to the fact that payload operations may not start because the OBC fails to send the command to start the experiment. A possible way to reduce failure is to perform ABCS experiments where the proton flux is lower. Simulations shows that this happens when ABCS is at polar latitudes, namely outside the range [-60°; 60°]. For this reason, the payload operations, based on redundant checks and triggers, were implemented accordingly. The purpose is to automatically determine if ABCS is at a latitude useful to perform the experiments and verifying this condition by means of multiple triggers, time or position based. Each trigger is used for scheduling purposes only if the ones with higher priority are unreliable. If all the triggers are not reliable, payload operations are forced to begin, as it is better to perform eventually degraded payload operations rather than performing no payload operations at all. Conclusions ABCS is required to operate in an extremely harsh environment where radiation fluxes are likely to degrade the electronic devices. Operations should be scheduled in order to reduce the time needed to perform all the experiments. The chosen approach will lead ABCS to complete the payload operations in three orbital periods, reducing the total ionizing dose absorbed and guaranteeing the higher system reliability. Acknowledgments ABCS AstroBio-CubeSat is supported by ASI - Italian Space Agency ASI/INAF Agreement n. 2019-30-HH.0. References [1] Iannascoli, L. et al. 2020, "Astrobio cubesat: Enabling technologies for astrobiology research in space", Proceedings of the International Astronautical Congress, IAC. [2] Mirasoli M, et al. 2014. Multiwell cartridge with integrated array of amorphous silicon photosensors for chemiluminescence detection: development, characterization and comparison with cooled-CCD luminograph. Anal Bioanal Chem. Sep;406(23):5645-56.

Published

2021

23. Antarctica as a reservoir of planetary analogue environments

Author

Ilaria Catanzaro, Lorenzo Aureli, Patrick Leo, Alessia Cassaro, Silvano Onofri, and Claudia Pacelli

Subjects

Katabatic wind, Solar System, Extraterrestrial Environment, Habitability, Antarctic Regions, Mars, Planets, Context (language use), General Medicine, Mars Exploration Program, Icy moon, Microbiology, Space exploration, Astrobiology, Exobiology, Molecular Medicine, Geology, Extreme Environments

Abstract

One of the main objectives of astrobiological research is the investigation of the habitability of other planetary bodies. Since space exploration missions are expensive and require long-term organization, the preliminary study of terrestrial environments is an essential step to prepare and support exploration missions. The Earth hosts a multitude of extreme environments whose characteristics resemble celestial bodies in our Solar System. In these environments, the physico-chemical properties partly match extraterrestrial environments and could clarify limits and adaptation mechanisms of life, the mineralogical or geochemical context, and support and interpret data sent back from planetary bodies. One of the best terrestrial analogues is Antarctica, whose conditions lie on the edge of habitability. It is characterized by a cold and dry climate (Onofri et al., Nova Hedwigia 68:175–182, 1999), low water availability, strong katabatic winds, salt concentration, desiccation, and high radiation. Thanks to the harsh conditions like those in other celestial bodies, Antarctica offers good terrestrial analogues for celestial body (Mars or icy moons; Leveille, CR Palevol 8:637–648, https://doi.org/10.1016/j.crpv.2009.03.005 , 2009). The continent could be distinguished into several habitats, each with characteristics similar to those existing on other bodies. Here, we reported a description of each simulated parameter within the habitats, in relation to each of the simulated extraterrestrial environments.

Published

2021

24. Insights into the Survival Capabilities of Cryomyces antarcticus Hydrated Colonies after Exposure to Fe Particle Radiation

Author

Onofri Silvano, Akira Fujimori, Shuryak Igor, Loke M. Siong, Ralf Moeller, Claudia Pacelli, Cassaro Alessia, and Aureli Lorenzo

Subjects

Microbiology (medical), 010504 meteorology & atmospheric sciences, QH301-705.5, Cosmic ray, Plant Science, 01 natural sciences, Article, Astrobiology, Ionizing radiation, ddc:570, 0103 physical sciences, medicine, Irradiation, Biology (General), Particle radiation, ddc:579, 010303 astronomy & astrophysics, Late Heavy Bombardment, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Cryomyces antarcticus, metabolically active cells, Atmospheric pressure, Chemistry, Mars Exploration Program, DNA, melanin, radiation, radioresistance, medicine.drug_formulation_ingredient

Abstract

The modern concept of the evolution of Mars assumes that life could potentially have originated on the planet Mars, possibly during the end of the late heavy bombardment, and could then be transferred to other planets. Since then, physical and chemical conditions on Mars changed and now strongly limit the presence of terrestrial-like life forms. These adverse conditions include scarcity of liquid water (although brine solutions may exist), low temperature and atmospheric pressure, and cosmic radiation. Ionizing radiation is very important among these life-constraining factors because it damages DNA and other cellular components, particularly in liquid conditions where radiation-induced reactive oxidants diffuse freely. Here, we investigated the impact of high doses (up to 2 kGy) of densely-ionizing (197.6 keV/µm), space-relevant iron ions (corresponding on the irradiation that reach the uppermost layer of the Mars subsurface) on the survival of an extremophilic terrestrial organism—Cryomyces antarcticus—in liquid medium and under atmospheric conditions, through different techniques. Results showed that it survived in a metabolically active state when subjected to high doses of Fe ions and was able to repair eventual DNA damages. It implies that some terrestrial life forms can withstand prolonged exposure to space-relevant ion radiation.

Published

2021

25. Iron Ion Particle Radiation Resistance of Dried Colonies of Cryomyces antarcticus Embedded in Martian Regolith Analogues

Author

Akira Fujimori, Lorenzo Aureli, Alessia Cassaro, Silvano Onofri, Ralf Moeller, and Claudia Pacelli

Subjects

0301 basic medicine, accelerated iron ions, cosmic rays, Mars, fungi, life on Mars, Cosmic ray, Life on Mars, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Astrobiology, 03 medical and health sciences, Strahlenbiologie, Martian surface, ddc:570, 0103 physical sciences, medicine, lcsh:Science, 010303 astronomy & astrophysics, Ecology, Evolution, Behavior and Systematics, Martian, Cryomyces antarcticus, Chemistry, Paleontology, Mars Exploration Program, Regolith, medicine.drug_formulation_ingredient, 030104 developmental biology, Space and Planetary Science, Extraterrestrial life, lcsh:Q

Abstract

Among the celestial bodies in the Solar System, Mars currently represents the main target for the search for life beyond Earth. However, its surface is constantly exposed to high doses of cosmic rays (CRs) that may pose a threat to any biological system. For this reason, investigations into the limits of resistance of life to space relevant radiation is fundamental to speculate on the chance of finding extraterrestrial organisms on Mars. In the present work, as part of the STARLIFE project, the responses of dried colonies of the black fungus Cryomyces antarcticus Culture Collection of Fungi from Extreme Environments (CCFEE) 515 to the exposure to accelerated iron (LET: 200 keV/μm) ions, which mimic part of CRs spectrum, were investigated. Samples were exposed to the iron ions up to 1000 Gy in the presence of Martian regolith analogues. Our results showed an extraordinary resistance of the fungus in terms of survival, recovery of metabolic activity and DNA integrity. These experiments give new insights into the survival probability of possible terrestrial-like life forms on the present or past Martian surface and shallow subsurface environments.

Published

2020

26. AstroBio CubeSat: a nanosatellite for space astrobiology experiments

Author

John Robert Brucato, Liyana Popova, Augusto Nascetti, A. Meneghin, Simone Pirrotta, Antonio Bardi, Stefano Carletta, Alessia Sabatini, Alessandro Donati, Giovanni Poggiali, D. Paglialunga, Laura Anfossi, Lorenzo Iannascoli, Claudia Pacelli, Mara Mirasoli, Luigi Schirone, G. Impresario, and Michele Balsamo

Subjects

Physics, CubeSat, Space (mathematics), Astrobiology

Abstract

IntroductionAstroBio CubeSat (ABCS) is an Italian Space Agency (ASI) 3U CubeSat (100x100x340 mm) selected by European Space Agency (ESA) to be launched with the Vega C qualification maiden flight, as piggy back of the ASI LARES2 main satellite, by the end of 2020. ABCS will be deployed in an approximately circular orbit, with about 5900 km altitude and 70° of inclination. It implies that ABCS will spend a significant part of the orbital period within the internal Van Allen belt, close to its maximum. The radiation environment is characterized by a very high flux of charged particles, which have a significant effect on electronic components in terms of permanent damages due to accumulated dose effects and single events. Considering the extremely harsh space conditions, the estimated mission lifetime useful to perform the payload experiments should be defined in 3 months.ABCS Project is funded and managed by ASI in cooperation with INAF-Astrophysical Observatory of Arcetri, that will coordinate the scientific and engineering team. Partners of the projects are the School of Aerospace Engineering of Sapienza University of Rome, the University of Bologna, the University of Torino, and Kayser Italia.ABCS PayloadABCS will host a mini laboratory payload based on an innovative lab-on chip technology suitable for research in astrobiology. The objective is to test in space environments an automatic laboratory able to provide a highly integrated in-situ multiparameter platform that uses immunoassay tests exploiting chemiluminescence detection by means of on-chip a-Si:H photodiodes. The experiment will consist in a set of lateral flow immunoassays (LFIA) on nitrocellulose support where target biomolecules are immobilized in specific test areas. Reagents are deposited in a non-permanent fashion and in a dry form in the initial part (starting area) of the microfluidic path. When the reagents-delivery-system provides a volume of liquid reagent to the starting pad, capillary forces will guide the reagents through the LFIA microfluidic pathway. During the flow, liquid reagents will solubilize and transport along the path the deposited reagents, triggering specific reactions and allowing the chemiluminescence detection by the photodiodes.ABCS also mounts an ancillary radiation dose payload, to investigate the degradation of of electronic components exposed to the space environment. The device has twin components protected by established radiation screens, kindly provided by Thales Alenia Space Italia and by CESI, so that the degradation can be assessed on the basis of the difference between the observed currents.ABCS architecture and payload are based on the strong heritage gained by the research team with the ground validation of the PLEIADES (Planetary Life Explorer with Integrated Analytical Detection and Embedded Sensors) instrument, an R&D ASI project recently concluded.Enviromental challengesThe main challenges of the project are to mitigate the effects of the expected very high flux of charged particles, keeping the correct temperature (4°C/25°C) and pressure (about 1 atm) range for the payload to prevent reagents degradation. This invoked a series of technological solution to protect the payload. The pressurized environment is ensured by an inner aluminium box, hosting both the experiment and the main subsystems (batteries, on-board data handling, telemetry, tracking and control) hermetically sealed and providing shielding from radiation and charged particles. A thermal control system, including a passive control multi-layer insulation and an active heather mounted inside the pressurized box, maintain the temperature in the desired range.ConclusionABCS mission aims at evaluating the overall system functionality (delivery of reagents, mixing of chemicals, LoC characterization, detection of emitted photons, readout noise, etc.) such as the chemicals and biomolecules stability (reagents and antibodies employed in the experiment) in the extremely harsh environment.The in-orbit validation of the proposed technology would represent a significant breakthrough for autonomous execution of bio-analytical experiments in space with potential application in search for signs of life in planetary exploration missions, space biolabs without human support, health monitoring in manned missions.

Published

2020

27. The Responses of the Black Fungus Cryomyces Antarcticus to High Doses of Accelerated Helium Ions Radiation within Martian Regolith Simulants and Their Relevance for Mars

Author

Lorenzo Aureli, Silvano Onofri, Claudia Pacelli, Akira Fujimori, Alessia Cassaro, and Ralf Moeller

Subjects

Galactic Cosmic Rays (GCRs), UV-vis spectroscopy, 010504 meteorology & atmospheric sciences, Cosmic ray, 01 natural sciences, survival, Article, General Biochemistry, Genetics and Molecular Biology, Astrobiology, Ionizing radiation, resistance, Strahlenbiologie, ddc:570, 0103 physical sciences, medicine, Irradiation, ddc:610, lcsh:Science, 010303 astronomy & astrophysics, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Martian, Cryomyces antarcticus, Paleontology, Mars Exploration Program, Regolith, melanin, medicine.drug_formulation_ingredient, Space and Planetary Science, Extraterrestrial life, Environmental science, lcsh:Q, black fungi, Mars environment

Abstract

One of the primary current astrobiological goals is to understand the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of accelerated He ions (150 MeV/n, up to 1 kGy) as a component of the galactic cosmic rays on the black fungus C. antarcticus when mixed with Antarctic sandstones&mdash, the substratum of its natural habitat&mdash, and two Martian regolith simulants, which mimics two different evolutionary stages of Mars. The high dose of 1 kGy was used to assess the effect of dose accumulation in dormant cells within minerals, under long-term irradiation estimated on a geological time scale. The data obtained suggests that viable Earth-like microorganisms can be preserved in the dormant state in the near-surface scenario for approximately 322,000 and 110,000 Earth years within Martian regolith that mimic early and present Mars environmental conditions, respectively. In addition, the results of the study indicate the possibility of maintaining traces within regolith, as demonstrated by the identification of melanin pigments through UltraViolet-visible (UV-vis) spectrophotometric approach.

Published

2020

28. Survival, DNA, and Ultrastructural Integrity of a Cryptoendolithic Antarctic Fungus in Mars and Lunar Rock Analogs Exposed Outside the International Space Station

Author

Elke Rabbow, Laura Zucconi, Laura Selbmann, Jean-Pierre de Vera, Claudia Pacelli, and Silvano Onofri

Subjects

Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Planetary protection, Ultraviolet Rays, Habitability, Mars, 01 natural sciences, Astrobiology, Ascomycota, Cryomyces antarcticus, Exobiology, 0103 physical sciences, International Space Station, medicine, Moon, 010303 astronomy & astrophysics, EXPOSE-R2, 0105 earth and related environmental sciences, Martian, Mars conditions, Mars Exploration Program, Agricultural and Biological Sciences (miscellaneous), Regolith, medicine.drug_formulation_ingredient, Space and Planetary Science, Extraterrestrial life, Space conditions, DNA Damage

Abstract

The search for life beyond Earth involves investigation into the responses of model organisms to the deleterious effects of space. In the frame of the BIOlogy and Mars Experiment, as part of the European Space Agency (ESA) space mission EXPOSE-R2 in low Earth orbit (LEO), dried colonies of the Antarctic cryptoendolithic black fungus Cryomyces antarcticus CCFEE 515 were grown on martian and lunar analog regolith pellets, and exposed for 16 months to LEO space and simulated Mars-like conditions on the International Space Station. The results demonstrate that C. antarcticus was able to tolerate the combined stress of different extraterrestrial substrates, space, and simulated Mars-like conditions in terms of survival, DNA, and ultrastructural stability. Results offer insights into the habitability of Mars for future exploration missions on Mars. Implications for the detection of biosignatures in extraterrestrial conditions and planetary protection are discussed.

Published

2019

29. Responses of the Black Fungus Cryomyces antarcticus to Simulated Mars and Space Conditions on Rock Analogs

Author

Claudia Coleine, Ekaterina Dadachova, Elke Rabbow, Ute Böttger, Laura Zucconi, Jean-Pierre de Vera, Claudia Pacelli, Laura Selbmann, and Silvano Onofri

Subjects

Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Radiation resistance, Ultraviolet Rays, Mars, Spectrum Analysis, Raman, Space (mathematics), 01 natural sciences, Astrobiology, Ascomycota, Low earth orbit, 0103 physical sciences, medicine, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Extremophilic microorganisms, Melanins, Cryomyces antarcticus, Mars Exploration Program, Agricultural and Biological Sciences (miscellaneous), medicine.drug_formulation_ingredient, Space and Planetary Science, Raman spectroscopy, Biosignatures, DNA Damage

Abstract

The BIOMEX (BIOlogy and Mars Experiment) is part of the European Space Agency (ESA) space mission EXPOSE-R2 in Low-Earth Orbit, devoted to exposing microorganisms for 1.5 years to space and simulated Mars conditions on the International Space Station. In preparing this mission, dried colonies of the Antarctic cryptoendolithic black fungus Cryomyces antarcticus CCFEE 515, grown on martian and lunar analog regolith pellets, were subjected to several ground-based preflight tests, Experiment Verification Tests, and Science Verification Tests (SVTs) that were performed to verify (i) the resistance of our model organism to space stressors when grown on extraterrestrial rock analogs and (ii) the possibility of detecting biomolecules as potential biosignatures. Here, the results of the SVTs, the last set of experiments, which were performed in ultraviolet radiation combined with simulated space vacuum or simulated martian conditions, are reported. The results demonstrate that C. antarcticus was able to tolerate the conditions of the SVT experiment, regardless of the substratum in which it was grown. DNA maintained high integrity after treatments and was confirmed as a possible biosignature; melanin, which was chosen to be a target for biosignature detection, was unambiguously detected by Raman spectroscopy.

Published

2019

30. Survival and redox activity of Friedmanniomyces endolithicus, an Antarctic endemic black meristematic fungus, after gamma rays exposure

Author

Ekaterina Dadachova, Ruth A. Bryan, Laura Zucconi, Laura Selbmann, Igor Shuryak, Silvano Onofri, and Claudia Pacelli

Subjects

0301 basic medicine, Microbial Viability, Gamma ray, Antarctic Regions, Context (language use), Pigments, Biological, Fungus, 030108 mycology & parasitology, Meristem, Biology, biology.organism_classification, Friedmanniomyces endolithicus, Ionizing radiation, Microbiology, Melanin, 03 medical and health sciences, Metabolism, 030104 developmental biology, Infectious Diseases, Ascomycota, Gamma Rays, Genetics, Oxidation-Reduction, Ecology, Evolution, Behavior and Systematics, Radiation resistance

Abstract

Despite living organisms are not exposed to acute ionizing radiation under natural conditions, some exhibit a high radiation resistance. Understanding this phenomenon is important for assessing the impact of radiation-related accidents, occupational exposures and space missions. In this context, in this study we analyzed the effect of gamma rays on the Antarctic cryptoendolithic melanized fungus Friedmanniomyces endolithicus CCFEE 5208 and demonstrated its resistance to acute doses of gamma radiation (up to 400 Gy), accompanied by increase in metabolic activity.

Published

2018

31. Multidisciplinary characterization of melanin pigments from the black fungus Cryomyces antarcticus

Author

Claudia, Pacelli, Alessia, Cassaro, Alessandro, Maturilli, Anna Maria, Timperio, Federica, Gevi, Barbara, Cavalazzi, Mariana, Stefan, Daniela, Ghica, and Silvano, Onofri

Subjects

Levodopa, Melanins, Ascomycota, Spectrum Analysis, Antarctic Regions, Naphthols, Chromatography, High Pressure Liquid, Mass Spectrometry

Abstract

Melanin is a natural pigment present in almost all biological groups, and is composed of indolic polymers and characterized by black-brown colorization. Furthermore, it is one of the pigments produced by extremophiles including those living in the Antarctic desert, and is mainly involved in their protection from high UV radiation, desiccation, salinity and oxidation. Previous studies have shown that melanized species have an increased capability to survive high level of radiation compared with the non-melanized counterpart. Understanding the molecular composition of fungal melanin could help to understand this peculiar capability. Here, we aimed to characterize the melanin pigment extracted from the Antarctic black fungus Cryomyces antarcticus, which is a good test model for radioprotection researches, by studying its chemical properties and spectral data. Our results demonstrated that, in spite of having a specific type of melanin as the majority of fungi, the fungus possesses the ability to produce both 1,8-dihydroxynaphthalene (DHN) and L 3-4 dihydroxyphenylalanine (L-DOPA) melanins, opening interesting scenarios for the protection role against radiation. Researches on fungal melanin have a huge application in different fields, including radioprotection, bioremediation, and biomedical applications. KEY POINTS: • Isolation and characterization by multidisciplinary approaches of fungal melanins. • Discovery that pathways for producing DOPA and DHN are both active even in its extreme habitat. • Hypothesis supporting the possibility of using melanin pigment for radioprotection.

Published

2020

32. Multidisciplinary characterization of melanin pigments from the black fungus Cryomyces antarcticus

Author

Barbara Cavalazzi, Mariana Stefan, Anna Maria Timperio, Alessia Cassaro, Federica Gevi, Claudia Pacelli, D. Ghica, Silvano Onofri, Alessandro Maturilli, and Pacelli C., Cassaro A., Maturilli A., Timperio A.M., Gevi F., Cavalazzi B., Stefan M., Ghica D, Onofri S.

Subjects

Fungus, Applied Microbiology and Biotechnology, Melanin, 03 medical and health sciences, Pigment, medicine, Extremophile, Extremophiles, melanin, Antarctica, Raman, infrared spectroscopy, radiation, electron paramagnetic resonance, Spectral data, 030304 developmental biology, Cryomyces antarcticus, 0303 health sciences, biology, integumentary system, 030306 microbiology, Chemistry, General Medicine, biology.organism_classification, medicine.drug_formulation_ingredient, Biochemistry, visual_art, visual_art.visual_art_medium, sense organs, Melanin pigment, Desiccation, Biotechnology

Abstract

Melanin is a natural pigment present in almost all biological groups, and is composed of indolic polymers and characterized by black-brown colorization. Furthermore, it is one of the pigments produced by extremophiles including those living in the Antarctic desert, and is mainly involved in their protection from high UV radiation, desiccation, salinity and oxidation. Previous studies have shown that melanized species have an increased capability to survive high level of radiation compared with the non-melanized counterpart. Understanding the molecular composition of fungal melanin could help to understand this peculiar capability. Here, we aimed to characterize the melanin pigment extracted from the Antarctic black fungus Cryomyces antarcticus, which is a good test model for radioprotection researches, by studying its chemical properties and spectral data. Our results demonstrated that, in spite of having a specific type of melanin as the majority of fungi, the fungus possesses the ability to produce both 1,8-dihydroxynaphthalene (DHN) and L 3-4 dihydroxyphenylalanine (L-DOPA) melanins, opening interesting scenarios for the protection role against radiation. Researches on fungal melanin have a huge application in different fields, including radioprotection, bioremediation, and biomedical applications. KEY POINTS: • Isolation and characterization by multidisciplinary approaches of fungal melanins. • Discovery that pathways for producing DOPA and DHN are both active even in its extreme habitat. • Hypothesis supporting the possibility of using melanin pigment for radioprotection.

Published

2020

33. Astrobio cubesat: Enabling technologies for astrobiology research in space

Author

Iannascoli, Lorenzo, Nascetti, Augusto, Carletta, Stefano, Schirone, Luigi, Andrea, Meneghin, John Robert Brucato, Paglialunga, Daniele, Giovanni, Poggiali, Simone, Pirrotta, Gabriele, Impresario, Alessia, Sabatini, and Claudia, Pacelli

Subjects

lab-on-chip, nano-satellite, space missions

Published

2020

34. Melanin is effective in protecting fast and slow growing fungi from various types of ionizing radiation

Author

Silvano Onofri, Ruth A. Bryan, Laura Selbmann, Ekaterina Dadachova, Claudia Pacelli, and Igor Shuryak

Subjects

Melanins, 0301 basic medicine, Cryptococcus neoformans, biology, X-Rays, 030106 microbiology, Radiation-Protective Agents, biology.organism_classification, Microbiology, Ionizing radiation, Melanin, 03 medical and health sciences, Pigment, 030104 developmental biology, Biochemistry, visual_art, visual_art.visual_art_medium, High doses, Metabolic activity, Ecology, Evolution, Behavior and Systematics

Abstract

Summary Melanin is a ubiquitous pigment with unique physicochemical properties. The resistance of melanized fungi to cosmic and terrestrial ionizing radiation suggests that melanin also plays a pivotal role in radioprotection. In this study, we compared the effects of densely-ionizing deuterons and sparsely-ionizing X-rays on two microscopic fungi capable of melanogenesis. We utilized the fast-growing pathogenic basiodiomycete forming an induced DOPA-melanin, Cryptococcus neoformans (CN); and the slow-growing environmental rock-inhabiting ascomycete synthesizing a constitutive DHN-melanin, Cryomyces antarcticus (CA); melanized and non-melanized counterparts were compared. CA was more resistant to deuterons than CN, and similar resistance was observed for X-rays. Melanin afforded protection against high-dose (1.5 kGy) deuterons for both CN and CA (p-values

Published

2017

35. Survival, DNA Integrity, and Ultrastructural Damage in Antarctic Cryptoendolithic Eukaryotic Microorganisms Exposed to Ionizing Radiation

Author

Laura Zucconi, Marina Raguse, Laura Selbmann, Silvano Onofri, Claudia Pacelli, Igor Shuryak, and Ralf Moeller

Subjects

0301 basic medicine, DNA damage, Microorganism, Fungus, Biology, Eukaryotic microorganisms, 01 natural sciences, Microbiology, Ionizing radiation, 03 medical and health sciences, chemistry.chemical_compound, 0103 physical sciences, Botany, medicine, Fingerprinting, Clonogenic assay, 010303 astronomy & astrophysics, Cryomyces antarcticus, Mars exploration, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), medicine.drug_formulation_ingredient, Special Collection: STARLIFE—Intercomparison Study of Astrobiological Model Systems in Their Response to Major Components of Galactic Cosmic RadiationGuest Editors: Ralf Moeller and Gerda HorneckResearch Articles, 030104 developmental biology, chemistry, Space and Planetary Science, Ionizing Radiation, DNA integrity, Ultrastructure, Biosignatures, DNA

Abstract

Life dispersal between planets, planetary protection, and the search for biosignatures are main topics in astrobiology. Under the umbrella of the STARLIFE project, three Antarctic endolithic microorganisms, the melanized fungus Cryomyces antarcticus CCFEE 515, a hyaline strain of Umbilicaria sp. (CCFEE 6113, lichenized fungus), and a Stichococcus sp. strain (C45A, green alga), were exposed to high doses of space-relevant gamma radiation (60Co), up to 117.07 kGy. After irradiation survival, DNA integrity and ultrastructural damage were tested. The first was assessed by clonogenic test; viability and dose responses were reasonably described by the linear-quadratic formalism. DNA integrity was evaluated by PCR, and ultrastructural damage was observed by transmission electron microscopy. The most resistant among the tested organisms was C. antarcticus both in terms of colony formation and DNA preservation. Besides, results clearly demonstrate that DNA was well detectable in all the tested organisms even when microorganisms were dead. This high resistance provides support for the use of DNA as a possible biosignature during the next exploration campaigns. Implication in planetary protection and contamination during long-term space travel are put forward. Key Words: Biosignatures—Ionizing radiation—DNA integrity—Eukaryotic microorganisms—Fingerprinting—Mars exploration. Astrobiology 17, 126–135.

Published

2017

36. Cellular Responses of the Lichen Circinaria gyrosa in Mars-Like Conditions

Author

Claudia Pacelli, Silvano Onofri, Andreas Lorek, Rosa de la Torre Noetzel, Ana Z. Miller, Jean Pierre Paul de Vera, Leopoldo G. Sancho, David Wolter, Beatriz Cubero, José María De la Rosa, and Ministerio de Economía, Industria y Competitividad (España)

Subjects

0301 basic medicine, Microbiology (medical), Circinaria gyrosa, analytical pyrolysis, Niche, lcsh:QR1-502, 01 natural sciences, Microbiology, lcsh:Microbiology, Cell wall, 03 medical and health sciences, extremotolerance, 0103 physical sciences, Botany, lichens, Lichen, 010303 astronomy & astrophysics, Original Research, Lecanoromycetes, Ascomycota, biology, Chemistry, Mars Exploration Program, photosynthetic activity, biology.organism_classification, Thallus, 030104 developmental biology, Mars environment

Abstract

Lichens are extremely resistant organisms that colonize harsh climatic areas, some of them defined as “Mars-analog sites.” There still remain many unsolved questions as to how lichens survive under such extreme conditions. Several studies have been performed to test the resistance of various lichen species under space and in simulated Mars-like conditions. The results led to the proposal that Circinaria gyrosa (Lecanoromycetes, Ascomycota) is one of the most durable astrobiological model lichens. However, although C. gyrosa has been exposed to Mars-like environmental conditions while in a latent state, it has not been exposed in its physiologically active mode. We hypothesize that the astrobiological test system “Circinaria gyrosa,” could be able to be physiologically active and to survive under Mars-like conditions in a simulation chamber, based on previous studies performed at dessicated-dormant stage under simulated Mars-like conditions, that showed a complete recover of the PSII activity (Sánchez et al., 2012). Epifluorescence and confocal laser scanning microscopy (CLSM) showed that living algal cells were more abundant in samples exposed to niche conditions, which simulated the conditions in micro-fissures and micro-caves close to the surface that have limited scattered or time-dependent light exposure, than in samples exposed to full UV radiation. The medulla was not structurally affected, suggesting that the niche exposure conditions did not disturb the lichen thalli structure and morphology as revealed by field emission scanning electron microscopy (FESEM). In addition, changes in the lichen thalli chemical composition were determined by analytical pyrolysis. The chromatograms resulting from analytical pyrolysis at 500°C revealed that lichen samples exposed to niche conditions and full UV radiation consisted primarily of glycosidic compounds, lipids, and sterols, which are typical constituents of the cell walls. However, specific differences could be detected and used as markers of the UV-induced damage to the lichen membranes. Based on its viability responses after rehydration, our study shows that the test lichen survived the 30-day incubation in the Mars chamber particularly under niche conditions. However, the photobiont was not able to photosynthesize under the Mars-like conditions, which indicates that the surface of Mars is not a habitable place for C. gyrosa., The authors acknowledge the Spanish Ministry of Economy, Industry and Competitiveness (MINECO, project SUBLIMAS ESP2015-69810-R). AM and JR thank the MINECO for the Juan de la Cierva–Incorporación (IJCI-2014-20443) and Ramón y Cajal (RYC-2014-16338) post-doctoral contracts, respectively. The authors are grateful to Dr. Ronald Charles Wolf for English improvement. CP and SO thank ASI grant BIOMEX-MCF n. 2013-063-R.0.

Published

2018

37. Cryptoendolithic Antarctic Black Fungus Cryomyces antarcticus Irradiated with Accelerated Helium Ions: Survival and Metabolic Activity, DNA and Ultrastructural Damage

Author

Silvano Onofri, Laura Zucconi, Akira Fujimori, Ralf Moeller, Laura Selbmann, Claudia Pacelli, and Teske, Andreas

Subjects

0301 basic medicine, Microbiology (medical), HZE particles, lcsh:QR1-502, Fungus, He²⁺ ions, Spaceflight, 01 natural sciences, Microbiology, lcsh:Microbiology, Ionizing radiation, law.invention, Strahlenbiologie, 03 medical and health sciences, chemistry.chemical_compound, cosmic rays, law, space radiation environment, 0103 physical sciences, extremotolerance, medicine, Extremophile, He2+ ions, Irradiation, 010303 astronomy & astrophysics, extremophiles, Cryomyces antarcticus, biology, Ecology, biology.organism_classification, medicine.drug_formulation_ingredient, 030104 developmental biology, chemistry, Biophysics, Ultrastructure, fungi, DNA

Abstract

Space represents an extremely harmful environment for life and survival of terrestrial organisms. In the last decades, a considerable deal of attention was paid to characterize the effects of spaceflight relevant radiation on various model organisms. The aim of this study was to test the survival capacity of the cryptoendolithic black fungus Cryomyces antarcticus CCFEE 515 to space relevant radiation, to outline its endurance to space conditions. In the frame of an international radiation campaign, dried fungal colonies were irradiated with accelerated Helium ion (150 MeV/n, LET 2.2 keV/μm), up to a final dose of 1.,000 Gy, as one of the space-relevant ionizing radiation. Results showed that the fungus maintained high survival and metabolic activity with no detectable DNA and ultrastructural damage, even after the highest dose irradiation. These data give clues on the resistance of life towards space ionizing radiation in general and on the resistance and responses of eukaryotic cells in particular.

Published

2017

38. The effect of protracted X-ray exposure on cell survival and metabolic activity of fast and slow growing fungi capable of melanogenesis

Author

Claudia Pacelli, Ekaterina Dadachova, Laura Selbmann, Ruth A. Bryan, Laura Zucconi, Silvano Onofri, and Igor Shuryak

Subjects

0301 basic medicine, Cryptococcus neoformans, Melanins, biology, Chemistry, X-Rays, Dose-Response Relationship, Radiation, Models, Theoretical, X ray exposure, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), Molecular biology, Ionizing radiation, Melanin, 03 medical and health sciences, 030104 developmental biology, Ascomycota, MTT assay, Metabolic activity, Ecology, Evolution, Behavior and Systematics, Cell survival, Intracellular

Abstract

The aim of this study was to analyse how protracted exposure to X-rays delivered at low dose rates of 0.0032-0.052 kGy h-1 affects the survival and metabolic activity of two microfungi capable of melanogenesis: fast-growing Cryptococcus neoformans (CN) and slow-growing Cryomyces antarcticus (CA). Melanized CN and CA cells survived the protracted exposure better than non-melanized ones, which was consistent with previous reports on the radioprotective role of melanin in these fungi after high dose rate exposures. The survival data were described by the linear quadratic dose response model. The XTT metabolic profiles were practically identical for melanized CN and CA with activity dose-dependent increasing: no changes in the activity of the non-melanized CN and CA were recorded by this assay. In contrast, the MTT assay, which measures the intracellular energy-related processes, recorded an increase in activity of non-melanized CN and CA cells, but not in their melanized counterparts. This could reflect intensive repair processes initiated by the non-melanized cells post exposure. This study suggests that differences in radiation responses between melanized and non-melanized fungal cells occur over a wide range of radiation dose rates.

Published

2017

39. Draft Genome Sequences of the Antarctic Endolithic Fungi Rachicladosporium antarcticum CCFEE 5527 and Rachicladosporium sp. CCFEE 5018

Author

Silvano Onofri, Laura Selbmann, Claudia Pacelli, Claudia Coleine, Jason E. Stajich, Laura Zucconi, and Sawyer Masonjones

Subjects

0301 basic medicine, Rachicladosporium, Ecology, 030108 mycology & parasitology, Biology, Rachicladosporium sp. CCFEE 5018, Genome, 03 medical and health sciences, 030104 developmental biology, Genus, Botany, Genetics, Molecular Biology, Rachicladosporium antarcticum

Abstract

The draft genome sequences of Rachicladosporium antarcticum CCFEE 5527 and Rachicladosporium sp. CCFEE 5018 are the first sequenced genomes from this genus, which comprises rock-inhabiting fungi. These endolithic strains were isolated from inside rocks collected from the Antarctic Peninsula and Battleship Promontory (McMurdo Dry Valleys), Antarctica, respectively.

Published

2017

40. Draft Genome Sequences of the Antarctic Endolithic Fungi

Author

Claudia, Coleine, Sawyer, Masonjones, Laura, Selbmann, Laura, Zucconi, Silvano, Onofri, Claudia, Pacelli, and Jason E, Stajich

Subjects

Eukaryotes

Abstract

The draft genome sequences of Rachicladosporium antarcticum CCFEE 5527 and Rachicladosporium sp. CCFEE 5018 are the first sequenced genomes from this genus, which comprises rock-inhabiting fungi. These endolithic strains were isolated from inside rocks collected from the Antarctic Peninsula and Battleship Promontory (McMurdo Dry Valleys), Antarctica, respectively.

Published

2017

41. BIOMEX experiment: ultrastructural alterations, molecular damage and survival of the fungus Cryomyces antarcticus after the Experiment Verification Tests

Author

Rosa de la Torre, Silvano Onofri, Claudia Pacelli, Laura Zucconi, Laura Selbmann, Jean-Pierre de Vera, Gerda Horneck, and Elke Rabbow

Subjects

0301 basic medicine, BIOMEX, Space simulations . Survival, Extraterrestrial Environment, Ultraviolet Rays, Antarctic Regions, Mars, Fungus, 01 natural sciences, Astrobiology, 03 medical and health sciences, Strahlenbiologie, Extant taxon, Ascomycota, 0103 physical sciences, Exobiology, medicine, Extremophile, 010303 astronomy & astrophysics, DNAdamage, Ecology, Evolution, Behavior and Systematics, Cryomyces antarcticus, Martian, biology, Leitungsbereich PF, General Medicine, biology.organism_classification, Regolith, medicine.drug_formulation_ingredient, 030104 developmental biology, Space and Planetary Science, Cryptoendolithic black fungus

Abstract

The search for traces of extinct or extant life in extraterrestrial environments is one of the main goals for astrobiologists; due to their ability to withstand stress producing conditions, extremophiles are perfect candidates for astrobiological studies. The BIOMEX project aims to test the ability of biomolecules and cell components to preserve their stability under space and Mars-like conditions, while at the same time investigating the survival capability of microorganisms. The experiment has been launched into space and is being exposed on the EXPOSE-R2 payload, outside of the International Space Station (ISS) over a time-span of 1.5 years. Along with a number of other extremophilic microorganisms, the Antarctic cryptoendolithic black fungus Cryomyces antarcticus CCFEE 515 has been included in the experiment. Before launch, dried colonies grown on Lunar and Martian regolith analogues were exposed to vacuum, irradiation and temperature cycles in ground based experiments (EVT1 and EVT2). Cultural and molecular tests revealed that the fungus survived on rock analogues under space and simulated Martian conditions, showing only slight ultra-structural and molecular damage.

Published

2016

42. Vegetation, pH and Water Content as Main Factors for Shaping Fungal Richness, Community Composition and Functional Guilds Distribution in Soils of Western Greenland

Author

Fabiana Canini, Laura Zucconi, Claudia Pacelli, Laura Selbmann, Silvano Onofri, and József Geml

Subjects

13. Climate action, metabarcoding, functional guilds, ITS1, 15. Life on land, shrub encroachment, edaphic factors

Abstract

This is the final paper "Vegetation, pH and Water Content as Main Factors for Shaping Fungal Richness, Community Composition and Functional Guilds Distribution in Soils of Western Greenland" published in Frontiers in Microbiology2019Volume 102348doi: 10.3389/fmicb.2019.02348 https://www.frontiersin.org/articles/10.3389/fmicb.2019.02348/full