Your search keyword '"METEOROIDS"' showing total 165 results

1. Higher Microbial Biomass Accumulation on El Médano 464 Meteorite Compared with Adjacent Soils in the Atacama Desert.

Author

Pinto GA, Lezcano MÁ, Sanchéz-García L, Martínez R, Parro V, and Carrizo D

Subjects

Carbon Isotopes analysis, Soil chemistry, Chile, Bacteria classification, Bacteria genetics, Bacteria metabolism, Soil Microbiology, Desert Climate, Meteoroids, Biomass

Abstract

Chondritic meteorites can be appropriate substrates for the colonization of terrestrial microorganisms. However, determining whether organic compounds are intrinsic to the meteorite or come from external (terrestrial) contamination is still controversial. This research explores the molecular distribution and carbon isotopic composition of three lipid families (hydrocarbons, alkanoic acids, and alcohols) as well as DNA extracted from the interior of a CO carbonaceous chondrite named El Médano 464 (EM 464), discovered in the Atacama Desert in 2019. Three soil samples from the discovery area of EM 464 were collected and used as a background control for the composition and distribution of organic compounds. Our results revealed a higher abundance of the three lipid families in EM 464 compared with the surrounding soil samples. The organic compounds in EM 464 showed a mean δ 13 C value of -27.8 ± 0.5 for hydrocarbons ( N = 20), -27.6 ± 1.1 for alkanoic acids ( N = 17), and -27.5 ± 2.2‰ for alcohols ( N = 18). These δ 13 C-depleted values are compatible with terrestrial biosignatures and are within isotopic values produced as a result of carbon fixation due to the Calvin cycle (δ 13 C of ca. from -19 to -34‰) widely used by photosynthetic terrestrial microorganisms. The DNA analysis (based on the bacterial 16S rRNA gene) showed a dominance of Proteobacteria (now Pseudomonadota) and Actinobacteriota in both meteorite and soils but exhibited different bacterial composition at the family level. This suggests that the microbial material inside the meteorite may have partially come from the adjacent soils, but we cannot rule out other sources, such as windborne microbes from distant locations. In addition, the meteorite showed higher bacterial diversity (H' = 2.4-2.8) compared with the three soil samples (H' = 0.3-1.8). Based on the distribution and δ 13 C value of organic compounds as well as DNA analysis, we suggest that most, if not all, of the organic compounds detected in the studied CO chondrite are of terrestrial origin ( i.e. , contamination). The terrestrial contamination of EM 464 by a diverse microbial community indicates that Atacama chondrites can offer distinctive ecological conditions for microorganisms to thrive in the harsh desert environment, which can result in an accumulation of microbial biomass and preservation of molecular fossils over time.

Published

2025

2. Production of Organic Precursors via Meteoritic Impacts and Its Implications for Prebiotic Inventory of Early Planetary Surfaces.

Author

Farcy B, Ni Z, Arevalo R Jr, Eller M, Pinnick VT, Schweikert EA, and Brinckerhoff WB

Subjects

Extraterrestrial Environment chemistry, Planets, Nitrates chemistry, Nitrates analysis, Origin of Life, Cyanides chemistry, Organic Chemicals chemistry, Exobiology methods, Ammonium Chloride chemistry, Surface Properties, Calcium Carbonate chemistry, Meteoroids

Abstract

Meteoritic impacts on planetary surfaces deliver a significant amount of energy that can produce prebiotic organic compounds such as cyanides, which may be a key step to the formation of biomolecules. To study the chemical processes of impact-induced organic synthesis, we simulated the physicochemical processes of hypervelocity impacts (HVI) in experiments with both high-speed 13 C 60 + projectiles and laser ablation. In the first approach, a 13 C 60 + beam was accelerated to collide with ammonium nitrate (NH 4 NO 3 ) to reproduce the shock process and plume generation of meteoritic impacts on nitrogen-rich planetary surfaces. In a complementary investigation, a high-power laser was focused on a mixture of calcium carbonate (CaCO 3 ) and either ammonium chloride (NH 4 Cl) or sodium nitrate (NaNO 3 ) to induce atomization and enable the study of molecular recombination in the postimpact plume. Additionally, isotopically spiked starting material, namely, Ca 13 CO 3 , 15 NH 4 Cl, Na 15 NO 3 , and 15 NH 4 15 NO 3 , was also employed to disambiguate the source of prebiotic molecule production in the resulting recombination plume. Both experiments independently demonstrated the formation of CN - ions as recombination products, with characteristic mass peak shifts corresponding to the isotopic labeling of the starting material. Yield curves generated from the laser experiments using varying ratios of calcite and NH 4 Cl or NaNO 3 indicate that nitrate enables more efficient production of CN - than ammonium. Thermodynamic software modeling of the laser ablation plume confirmed and further elucidated the experimental yield results, producing good agreement of modeled CN - yield with observed yield curves. These models indicate that the reduction of atomic N from incomplete NH 4 - atomization during the ablation pulse may have contributed to the lower CN - yield from the ammonia source relative to the nitrate source. The results of these experiments demonstrated that CN - , and by proxy, hydrogen cyanide, and other organic precursor molecules could have formed from carbonate deposits, a previously under-appreciated source of organic carbon for impact-induced organic synthesis. These results have implications for the formation of life during meteoritic bombardment on early Earth as well as for other carbonate-bearing planetary bodies such as Mars and Ceres.

Published

2025

3. Beyond Homochirality: Computer Modeling Hints of Heterochiral Proteins in Early and Extraterrestrial Life.

Author

Casimo G, Micca Longo G, and Longo S

Subjects

Stereoisomerism, Origin of Life, Amino Acids chemistry, Amino Acids analysis, Meteoroids, Extraterrestrial Environment chemistry, Exobiology methods, Computer Simulation, Proteins chemistry

Abstract

Agent-based simulations are set to describe the early biotic selection of oligomers made of monomers of different chirality. The simulations consider the spatial distribution of agents and resources, the balance of biomass of different chirality, and the balance of chemical energy. Following the well-known Wald's hypothesis, a disadvantage is attributed to the change in chirality along the biochemical sequence. A racemic amino acid budget is considered, based on findings in meteorites and the results of Miller's experiments. It is also hypothesized that the very first life forms were heterotrophic. Given these assumptions, our simulations showed that biological sequences were not strictly homochiral and had few chirality changes. These results suggest that the current dominance of homochiral species may have been preceded by a more structurally varied biochemistry. This might be reflected in the few known heterochiral proteins, whose structures are based neither on alpha-helices nor on beta-sheets. Extraterrestrial life forms might be based on such heterochiral proteins.

Published

2025

4. Some Pertinent Issues for Interstellar Panspermia Raised after the Discovery of 1I/'Oumuamua.

Author

Desch, Steven J. and Jackson, Alan P.

Subjects

*'OUMUAMUA, *PANSPERMIA, *INTERSTELLAR medium, *EXTRATERRESTRIAL life, *SOLAR sails, *MOLECULAR clouds, *METEOROIDS

Abstract

The interstellar objects 1I/'Oumuamua and 2I/Borisov confirm the long-held expectation that bodies from one stellar system will be carried to another, allowing, in principle, interstellar panspermia. Life might be transferred between stellar systems, depending on the nature of the bodies and how they escaped their systems. 2I/Borisov appears to be a comet, with no more likelihood of carrying life than Solar System comets. In contrast, the nature of 1I/'Oumuamua has been difficult to determine. We review various hypotheses for its origin, including ejection of N2 ice from the surface of an exo-Pluto, formation in a molecular cloud by freezing of H2, and a derelict solar sail of alien construction. Of these, the N2 ice fragment hypothesis is uniquely falsifiable, plausible, and completely consistent with all observations. The possibility of interstellar panspermia would be made more probable if 'Oumuamua originated on a dwarf planet rather than a comet, although substantial challenges to transfer of life would remain. Of proposed mechanisms for interstellar panspermia, transfer of life via rocky meteoroids is perhaps less improbable. [ABSTRACT FROM AUTHOR]

Published

2022

5. Simplified Meteorite Parent Body Alteration of Amino Acids by Hydrothermal Processes.

Author

Materese CK, Aponte JC, McLain HL, Farnsworth KK, Tribbett PD, Ferguson FT, Knudson CA, McAdam AC, Thorpe MT, and Dworkin JP

Subjects

Water chemistry, Exobiology methods, Minerals chemistry, Meteoroids, Amino Acids chemistry, Extraterrestrial Environment chemistry

Abstract

Amino acids have been identified in extraterrestrial materials such as meteorites and returned samples from asteroids and comets. Some of these amino acids or their precursors may have formed on icy interstellar dust grains or at a later phase when these grains became incorporated into larger parent bodies. In this work, we simulated parent body aqueous alteration of the residues from irradiated interstellar ice analogs in the presence of relevant minerals (pulverized serpentinite and Allende meteorite). We tracked the change in amino acid abundances as a function of hydrothermal processing time and examined how these differed based on the presence of minerals. We find that the presence of minerals and their mineralogy can have a significant impact on the formation and destruction of amino acids during simulated aqueous alteration experiments.

Published

2024

6. Multiple Cosmic Sources for Meteorite Macromolecules?

Author

Sephton, Mark A, Watson, Jonathan S, Meredith, William, Love, Gordon D, Gilmour, Iain, and Snape, Colin E

Subjects

Carbon Isotopes, Hydrocarbons, Aromatic, Macromolecular Substances, Meteoroids, Gas Chromatography-Mass Spectrometry, Abiotic organic synthesis, Carbonaceous chondrite, Cosmochemistry, Meteorites, Astronomical and Space Sciences, Geochemistry, Geology, Astronomy & Astrophysics

Abstract

The major organic component in carbonaceous meteorites is an organic macromolecular material. The Murchison macromolecular material comprises aromatic units connected by aliphatic and heteroatom-containing linkages or occluded within the wider structure. The macromolecular material source environment remains elusive. Traditionally, attempts to determine source have strived to identify a single environment. Here, we apply a highly efficient hydrogenolysis method to liberate units from the macromolecular material and use mass spectrometric techniques to determine their chemical structures and individual stable carbon isotope ratios. We confirm that the macromolecular material comprises a labile fraction with small aromatic units enriched in (13)C and a refractory fraction made up of large aromatic units depleted in (13)C. Our findings suggest that the macromolecular material may be derived from at least two separate environments. Compound-specific carbon isotope trends for aromatic compounds with carbon number may reflect mixing of the two sources. The story of the quantitatively dominant macromolecular material in meteorites appears to be made up of more than one chapter.

Published

2015

7. Four-Year Operation of Tanpopo: Astrobiology Exposure and Micrometeoroid Capture Experiments on the JEM Exposed Facility of the International Space Station.

Author

Yamagishi, Akihiko, Hashimoto, Hirofumi, Yano, Hajime, Imai, Eiichi, Tabata, Makoto, Higashide, Masumi, and Okudaira, Kyoko

Subjects

*SPACE stations, *ASTROBIOLOGY, *SPACE environment, *AEROGELS, *IONIZING radiation, *METEOROIDS, *SPACE debris, *DOSIMETERS

Abstract

The Tanpopo experiment was the first Japanese astrobiology mission on board the International Space Station. It included exposure experiments of microbes and organic compounds as well as a capture experiment of hypervelocity impacting microparticles. We deployed three Exposure Panels, each consisting of 20 Exposure Units that contained microbes, organic compounds, an alanine UV dosimeter or an ionizing radiation dosimeter. The three Exposure Panels were situated on the zenith face of the Exposed Experiment Handrail Attachment Mechanism (ExHAM) that was pointing in zenith direction toward space, which was attached on a handrail of the Japanese Experiment Module (Kibo) Exposed Facility (JEM-EF) outside the International Space Station. The three Exposure Panels were one by one retrieved and returned to the ground after approximately 1, 2, and 3 years of exposure to the space environment. Capture Panels, each of which contained one or two blocks of amorphous silica aerogel, were exposed to collect hypervelocity impact microparticles. Possible captured particles may include micrometeoroids, human-made orbital debris, and natural terrestrial particles. Each year, Capture Panels containing from 11 to 12 aerogel blocks were attached to the three faces of the ExHAM (pointing to zenith, ram, and port); they remained in place for about 1 year and were then returned to the laboratory. This process was repeated three times, in total, during 2015–2018. Additional exposure of a Capture Panel facing ram was conducted between 2018 and 2019. Once the aerogel blocks were returned to the laboratory, they were encapsulated in dedicated transparent plastic cases and optically inspected by a specially designed microscopic system. Once located and recorded, hypervelocity impact signatures were excavated one by one and distributed for further detailed analyses. The apparatus, operation, and environmental factors of all the Tanpopo experiments are summarized in this article. [ABSTRACT FROM AUTHOR]

Published

2021

8. Using Organic Contaminants to Constrain the Terrestrial Journey of the Martian Meteorite Lafayette

Author

Áine Clare O'Brien, Lydia Jane Hallis, Clement Regnault, Douglas Morrison, Gavin Blackburn, Andrew Steele, Luke Daly, Alastair Tait, Marissa Marie Tremblay, Darcy E.P. Telenko, Jacqueline Gunn, Eleanor McKay, Nicola Mari, Mohammad Ali Salik, Philippa Ascough, Jaime Toney, Sammy Griffin, Phil Whitfield, and Martin Lee

Subjects

Extraterrestrial Environment, Universities, Earth, Planet, Space and Planetary Science, Humans, Mars, Meteoroids, Agricultural and Biological Sciences (miscellaneous)

Abstract

A key part of the search for extraterrestrial life is the detection of organic molecules since these molecules form the basis of all living things on Earth. Instrument suites such as SHERLOC (Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals) onboard the NASA Perseverance rover and the Mars Organic Molecule Analyzer onboard the future ExoMars Rosalind Franklin rover are designed to detect organic molecules at the martian surface. However, size, mass, and power limitations mean that these instrument suites cannot yet match the instrumental capabilities available in Earth-based laboratories. Until Mars Sample Return, the only martian samples available for study on Earth are martian meteorites. This is a collection of largely basaltic igneous rocks that have been exposed to varying degrees of terrestrial contamination. The low organic molecule abundance within igneous rocks and the expectation of terrestrial contamination make the identification of martian organics within these meteorites highly challenging. The Lafayette martian meteorite exhibits little evidence of terrestrial weathering, potentially making it a good candidate for the detection of martian organics despite uncertainties surrounding its fall history. In this study, we used ultrapure solvents to extract organic matter from triplicate samples of Lafayette and analyzed these extracts via hydrophilic interaction liquid chromatography-mass spectrometry (HILIC-MS). Two hundred twenty-four metabolites (organic molecules) were detected in Lafayette at concentrations more than twice those present in the procedural blanks. In addition, a large number of plant-derived metabolites were putatively identified, the presence of which supports the unconfirmed report that Lafayette fell in a semirural location in Indiana. Remarkably, the putative identification of the mycotoxin deoxynivalenol (or vomitoxin), alongside the report that the collector was possibly a student at Purdue University, can be used to identify the most likely fall year as 1919.

Published

2022

9. Meteorites as Food Source on Early Earth: Growth, Selection, and Inhibition of a Microbial Community on a Carbonaceous Chondrite

Author

Annemiek C. Waajen, R. Prescott, and Charles S. Cockell

Subjects

Earth, Planet, Space and Planetary Science, Microbiota, Humans, Meteoroids, Organic Chemicals, Agricultural and Biological Sciences (miscellaneous), Sulfur

Abstract

Meteoritic material accumulated on the surface of the anoxic early Earth during the Late Heavy Bombardment around 4.0 Gya and may have provided Earth's surface with extraterrestrial nutrients and energy sources. This research investigates the growth of an anaerobic microbial community from pond sediment on native and pyrolyzed (heat-treated) carbonaceous chondrite Cold Bokkeveld. The community was grown anaerobically in liquid media. Native Cold Bokkeveld supported the growth of a phylogenetically clustered subset of the original pond community by habitat filtering. The anaerobic community on meteorite was dominated by the Deltaproteobacteria Geobacteraceae and Desulfuromonadaceae. Members of these taxa are known to use elemental sulfur and ferric iron as electron acceptors, and organic compounds as electron donors. Pyrolyzed Cold Bokkeveld, however, was inhibitory to the growth of the microbial community. These results show that carbonaceous chondrites can support and select for a specific anaerobic microbial community, but that pyrolysis, for example by geothermal activity, could inhibit microbial growth and toxify the material. This research shows that extraterrestrial meteoritic material can shape the abundance and composition of anaerobic microbial ecosystems with implications for early Earth. These results also provide a basis to design anaerobic material processing of asteroidal material for future human settlement.

Published

2022

10. UV Time-Resolved Laser-Induced Fluorescence Spectroscopy of Amino Acids Found in Meteorites: Implications for Space Science and Exploration

Author

Michael Daly, Kimberly T. Tait, E. A. Lymer, Menelaos Konstantinidis, and Emmanuel Lalla

Subjects

In situ, chemistry.chemical_classification, Lasers, Meteoroids, Life on Mars, Agricultural and Biological Sciences (miscellaneous), Fluorescence, Fluorescence spectroscopy, Amino acid, Astrobiology, Spectrometry, Fluorescence, Meteorite, chemistry, Space and Planetary Science, Asteroid, Exobiology, Biosignature, Amino Acids

Abstract

Laser-induced fluorescence spectroscopy is a useful laboratory and in situ technique for planetary exploration, with applications in biosignature detection and the search for life on Mars. However,...

Published

2021

11. Uninhabitable and Potentially Habitable Environments on Mars: Evidence from Meteorite ALH 84001

Author

Allan H. Treiman

Subjects

Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Carbonates, Mars, engineering.material, 01 natural sciences, Astrobiology, chemistry.chemical_compound, Nakhlite, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Martian, Minerals, geography, geography.geographical_feature_category, Olivine, Meteoroids, Mars Exploration Program, Agricultural and Biological Sciences (miscellaneous), Volcanic rock, Igneous rock, Meteorite, chemistry, Space and Planetary Science, engineering, Carbonate, Geology

Abstract

The martian meteorite ALH 84001 formed before ∼4.0 Ga, so it could have preserved information about habitability on early Mars and habitability since then. ALH 84001 is particularly important as it contains carbonate (and other) minerals that were deposited by liquid water, raising the chance that they may have formed in a habitable environment. Despite vigorous efforts from the scientific community, there is no accepted evidence that ALH 84001 contains traces or markers of ancient martian life-all the purported signs have been shown to be incorrect or ambiguous. However, the meteorite provides evidence for three distinct episodes of potentially habitable environments on early Mars. First is evidence that the meteorite's precursors interacted with clay-rich material, formed approximately at 4.2 Ga. Second is that igneous olivine crystals in ALH 84001 were partially dissolved and removed, presumably by liquid water. Third is, of course, the deposition of the carbonate globules, which occurred at ∼15-25°C and involved near-neutral to alkaline waters. The environments of olivine dissolution and carbonate deposition are not known precisely; hydrothermal and soil environments are current possibilities. By analogies with similar alteration minerals and sequences in the nakhlite martian meteorites and volcanic rocks from Spitzbergen (Norway), a hydrothermal environment is favored. As with the nakhlite alterations, those in ALH 84001 likely formed in a hydrothermal system related to a meteoroid impact event. Following deposition of the carbonates (at 3.95 Ga), ALH 84001 preserves no evidence of habitable environments, that is, interaction with water. The meteorite contains several materials (formed by impact shock at ∼3.9 Ga) that should have reacted readily with water to form hydrous silicates, but there is no evidence any formed.

Published

2021

12. Constraints for Use of Ultraviolet Spectropolarimetry to Detect Chiral Amino Acids from Comets

Author

Ana I. Gómez de Castro and Ana I. De Isidro-Gómez

Subjects

010504 meteorology & atmospheric sciences, Glycine, Astrophysics::Cosmology and Extragalactic Astrophysics, medicine.disease_cause, 01 natural sciences, Astrobiology, Planet, Ultraviolet spectroscopy, 0103 physical sciences, Comets, medicine, Chirality, Amino Acids, 010303 astronomy & astrophysics, Stellar evolution, Research Articles, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Physics, Alanine, Stereoisomerism, Meteoroids, Química analítica, Remote sensing, Agricultural and Biological Sciences (miscellaneous), Galaxy, Astronomía, Space and Planetary Science, Geodesia, Astrophysics::Earth and Planetary Astrophysics, Ultraviolet

Abstract

Life is pervasive on planet Earth, but whether life is ubiquitous in the Galaxy and sustainable over timescales comparable to stellar evolution is unknown. Evidence suggests that life first appeared on Earth more than 3.77 Gyr ago, during a period of heavy meteoric bombardment. Amino acids, the building blocks of proteins, have been demonstrated to exist in interstellar ice. As such, the contribution of space-generated amino acids to those existing on Earth should be considered. However, detection of space amino acids is challenging. In this study, we used analytical data from several meteorites and in situ measurements of the comet 67P/Churyumov-Gerasimenko collected by the Rosetta probe to evaluate the detectability of alanine by ultraviolet spectropolarimetry. Alanine is the second-most abundant amino acid after glycine and is optically active. This chirality produces a unique signature that enables reliable identification of this amino acid using the imprint of optical rotatory dispersion (ORD) and circular dichroism (CD) in the ultraviolet spectrum (130–230 nm). Here, we show that the ORD signature could be detected in comets by using ultraviolet spectropolarimetric observations conducted at middle size space observatories. These observations can also provide crucial information for the study of sources of enantiomeric imbalance on Earth.

Published

2021

13. Comprehensive Search of Stable Isomers of Alanine and Alanine Precursors in Prebiotic Syntheses

Author

Mitsuo Shoji, Natsuki Watanabe, Yuta Hori, Kenji Furuya, Masayuki Umemura, Mauro Boero, Yasuteru Shigeta, Université de Tsukuba = University of Tsukuba, National Astronomical Observatory of Japan (NAOJ), Institut de Physique et Chimie des Matériaux de Strasbourg (IPCMS), Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Matériaux et Nanosciences Grand-Est (MNGE), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Réseau nanophotonique et optique, Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS), and Boero, Mauro

Subjects

Alanine, Stereoisomerism, Meteoroids, Minimum energy principle, Agricultural and Biological Sciences (miscellaneous), [CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistry, [CHIM.THEO] Chemical Sciences/Theoretical and/or physical chemistry, isomer, Space and Planetary Science, 2-aminopropanenitrile, [SDU.OTHER] Sciences of the Universe [physics]/Other, Chirality, Amino Acids, [SDU.OTHER]Sciences of the Universe [physics]/Other, Alanine precursor

Abstract

International audience; Enantiomeric excesses of l-amino acids have been detected in meteorites; however, their molecular mechanism and prebiotic syntheses are still a matter of debate. To elucidate the origin of homochirality, alanine and the chiral precursors formed in prebiotic processes were investigated with regard to their stabilities among their isomers by employing the minimum energy principle, namely, the abundancy of a molecule in the interstellar medium is directly correlated to the stability among isomers. To facilitate the search for possible isomers, we developed a new isomer search algorithm, the random connection method, and performed a thorough search for all the stable isomers within a given chemical formula. We found that alanine and most of its precursors are located at higher energy by more than 5.7 kcal mol−1, with respect to the most stable isomer that consists of a linear-chain structure, whereas only the 2-aminopropanenitrile is the most stable isomer among all others possible. The inherent stability of the α-amino nitrile suggests that the 2-aminopropanenitrile is the dominant contribution in the formation of the common enantiomeric excess over α-amino acids.

Published

2022

14. Cometary Glycolaldehyde as a Source of pre-RNA Molecules

Author

Jayden H. E. Butler, Vanessa P. McCaffrey, and Nicolle E. B. Zellner

Subjects

Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Origin of Life, Strecker amino acid synthesis, Comet, FOS: Physical sciences, Acetaldehyde, 01 natural sciences, chemistry.chemical_compound, Abiogenesis, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Earth and Planetary Astrophysics (astro-ph.EP), Glycolaldehyde, Threose, Radiochemistry, food and beverages, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Formose reaction, Interstellar medium, chemistry, Space and Planetary Science, Erythrose, RNA, Solar System, Astrophysics - Earth and Planetary Astrophysics

Abstract

Over 200 molecules have been detected in multiple extraterrestrial environments, including glycolaldehyde (C2(H2O)2, GLA), a two-carbon sugar precursor that has been detected in regions of the interstellar medium. Its recent in situ detection on the nucleus of comet 67P/Churyumov-Gerasimenko and via remote observations in the comae of others, provides tantalizing evidence that it is common on most (if not all) comets. Impact experiments conducted at the Experimental Impact Laboratory at NASA's Johnson Space Center have shown that samples of GLA and GLA mixed with montmorillonite clays can survive impact delivery in the pressure range of 4.5 GPa to 25 GPa. Extrapolated to amounts of GLA observed on individual comets and assuming a monotonic impact rate in the first billion years of solar system history, these experimental results show that up to 10^23 kg of cometary GLA could have survived impact delivery, with substantial amounts of threose, erythrose, glycolic acid, and ethylene glycol also produced or delivered. Importantly, independent of the profile of the impact flux in the early solar system, comet delivery of GLA would have provided (and may continue to provide) a reservoir of starting material for the formose reaction (to form ribose) and the Strecker reaction (to form amino acids). Thus, comets may have been important delivery vehicles for starting molecules necessary for life as we know it., Accepted manuscript, to appear in the journal Astrobiology

Published

2020

15. Cometary Delivery of Hydrogen Cyanide to the Early Earth

Author

Karin I. Öberg and Zoe R. Todd

Subjects

Evolution, Chemical, Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Earth, Planet, Radical, Cyanide, Origin of Life, Comet, Hydrogen cyanide, Meteoroids, Early Earth, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Astrobiology, chemistry.chemical_compound, chemistry, Space and Planetary Science, Abiogenesis, Hydrogen Cyanide, 0103 physical sciences, Molecule, 010303 astronomy & astrophysics, Late Heavy Bombardment, 0105 earth and related environmental sciences

Abstract

Delivery of water and organics by asteroid and comet impacts may have influenced prebiotic chemistry on the early Earth. Some recent prebiotic chemistry experiments emphasize hydrogen cyanide (HCN) as a feedstock molecule for the formation of sugars, ribonucleotides, amino acids, and lipid precursors. Here, we assess how much HCN originally contained in a comet would survive impact, using parametric temperature and pressure profiles together with a time-dependent chemistry model. We find that HCN survival mainly depends on whether the impact is hot enough to thermally decompose H2O into reactive radicals, and HCN is therefore rather insensitive to the details of the chemistry. In the most favorable impacts (low impact angle, low velocity, small radius), this temperature threshold is not reached, and intact delivery of HCN is possible. We estimate the global delivery of HCN during a period of Early and Late Heavy Bombardment of the early Earth, as well as local HCN concentrations achieved by individual impacts. In the latter case, comet impacts can provide prebiotically interesting HCN levels for thousands to millions of years, depending on properties of the impactor and of the local environment.

Published

2020

16. The Albedo of Ryugu: Evidence for a High Organic Abundance, as Inferred from the Hayabusa2 Touchdown Maneuver

Author

Christian Potiszil, Ryoji Tanaka, Eizo Nakamura, Katsura Kobayashi, and Tak Kunihiro

Subjects

Solar System, Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Sample return, 01 natural sciences, Astrobiology, Abundance (ecology), Comet nucleus, 0103 physical sciences, Ryugu, Organic matter, Hypothesis Article, Organic Chemicals, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, chemistry.chemical_classification, Minerals, Spectrum Analysis, Albedo. Astrobiology 20, 916–921, Meteoroids, Space Flight, Albedo, Agricultural and Biological Sciences (miscellaneous), chemistry, Meteorite, Space and Planetary Science, Asteroid, Carbonaceous chondrite, Environmental science, Hayabusa2

Abstract

The Hayabusa2 mission successfully collected samples from the asteroid Ryugu last year and will return these to Earth in December 2020. It is anticipated that the samples will enable the analysis of terrestrially uncontaminated organic matter and minerals. Such analyses are in turn expected to elucidate the evolution of organic matter through Solar System history, including the origination and processing of biogenically important molecules, which could have been utilized by the first organisms on Earth. In anticipation, studies have made predictions concerning the properties of Ryugu, including its composition. The spectral characteristics of Ryugu, such as albedo, have been employed to relate the asteroid to members of the carbonaceous chondrite group that have been identified on Earth. However, the recent Hayabusa2 touchdown highlights a disparity between the color of surfaces of displaced platy fragments, indicating a brightening trend for the surface exposed to space compared to that facing into the body. Here we present a mass balance calculation with reference to data from the literature, which indicates that Ryugu may contain a significantly higher abundance of organic matter (likely >50%) than the currently most accepted meteorite analogues. A high organic content may result in high levels of extractable organic matter for the second touchdown site, where the spacecraft sampled freshly exposed material. However, high abundances of insoluble aromatic/graphitic rich organic matter may be present in the first touchdown site, which sampled the surface of Ryugu that had been exposed to space. Moreover, we suggest that the potentially high organic abundance and the rubble-pile nature of Ryugu may originate from the capture of rocky debris by a comet nucleus and subsequent water-organic-mineral interactions and sublimation of water ice.

Published

2020

17. Thiophenes on Mars: Biotic or Abiotic Origin?

Author

Jacob Heinz and Dirk Schulze-Makuch

Subjects

Martian, chemistry.chemical_classification, Abiotic component, Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Sulfates, Temperature, Mars, Meteoroids, Thiophenes, Mars Exploration Program, Curiosity rover, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Biosynthetic Pathways, Astrobiology, Biomarker, chemistry, Space and Planetary Science, 0103 physical sciences, Environmental science, Organic matter, 010303 astronomy & astrophysics, Biomarkers, 0105 earth and related environmental sciences

Abstract

The question whether organic compounds occur on Mars remained unanswered for decades. However, the recent discovery of various classes of organic matter in martian sediments by the Curiosity rover seems to strongly suggest that indigenous organic compounds exist on Mars. One intriguing group of detected organic compounds were thiophenes, which typically occur on Earth in kerogen, coal, and crude oil as well as in stromatolites and microfossils. Here we provide a brief synopsis of conceivable pathways for the generation and degradation of thiophenes on Mars. We show that the origin of thiophene derivatives can either be biotic or abiotic, for example, through sulfur incorporation in organic matter during early diagenesis. The potential of thiophenes to represent martian biomarkers is discussed as well as a correlation between abundances of thiophenes and sulfate-bearing minerals. Finally, this study provides suggestions for future investigations on Mars and in Earth-based laboratories to answer the question whether the martian thiophenes are of biological origin.

Published

2020

18. Resolving the History of Life on Earth by Seeking Life As We Know It on Mars

Author

Christopher E. Carr

Subjects

Earth and Planetary Astrophysics (astro-ph.EP), Extraterrestrial Environment, Earth, Planet, FOS: Physical sciences, Mars, Biomolecules (q-bio.BM), Geology, Popular Physics (physics.pop-ph), Meteoroids, Physics - Popular Physics, Agricultural and Biological Sciences (miscellaneous), Quantitative Biology - Biomolecules, Space and Planetary Science, FOS: Biological sciences, Exobiology, Astrophysics - Earth and Planetary Astrophysics

Abstract

An origin of Earth life on Mars would resolve significant inconsistencies between the inferred history of life and Earth's geologic history. Life as we know it utilizes amino acids, nucleic acids, and lipids for the metabolic, informational, and compartment-forming subsystems of a cell. Such building blocks may have formed simultaneously from cyanosulfidic chemical precursors in a planetary surface scenario involving ultraviolet light, wet-dry cycling, and volcanism. However, early Earth was a water world, and the timing of the rise of oxygen on Earth is inconsistent with final fixation of the genetic code in response to oxidative stress. A cyanosulfidic origin of life could have taken place on Mars via photoredox chemistry, facilitated by orders of magnitude more sub-aerial crust than early Earth, and an earlier transition to oxidative conditions. Meteoritic bombardment may have generated transient habitable environments and ejected and transferred life to Earth. The Mars 2020 Perseverance Rover offers an unprecedented opportunity to confirm or refute evidence consistent with a cyanosulfidic origin of life on Mars, search for evidence of ancient life, and constrain the evolution of Mars' oxidation state over time. We should seek to prove or refute a Martian origin for life on Earth alongside other possibilities., Comment: 13 pages, 1 figure

Published

2022

19. Irradiation of Phenylalanine at 300 K by MeV Ions

Author

Christian Mejía, Cíntia A.P. da Costa, Peter Iza, and Enio F. da Silveira

Subjects

Ions, Kinetics, Space and Planetary Science, Phenylalanine, Spectroscopy, Fourier Transform Infrared, Meteoroids, Agricultural and Biological Sciences (miscellaneous)

Abstract

Phenylalanine (Phe) is an amino acid that has been identified in carbonaceous meteorites; its formation mechanism in space is unknown, and its radioresistance has been the subject of investigation. This work aims at studying, in the laboratory, the Phe radiolysis by cosmic analogues. The Phe destruction rate, at 300 K, is measured for H, He, and N ion beam irradiation in the 0.5 to 2 kinetic MeV range. Fourier transform infrared (FTIR) spectroscopy was employed to monitor the molecular degradation as a function of fluence. The Phe apparent destruction cross-section

Published

2022

20. A Review of the 'Black Beauty' Martian Regolith Breccia and Its Martian Habitability Record

Author

Arthur Goodwin, Romain Tartèse, and Russell Garwood

Subjects

Martian regolith breccia, Volatiles, Beauty, Extraterrestrial Environment, Space and Planetary Science, Geochronology, Habitability. Astrobiology 22, 755-767, Mars, Water, NWA 7034, Meteoroids, Agricultural and Biological Sciences (miscellaneous)

Abstract

The regolith breccia Northwest Africa (NWA) 7034 and paired samples are unique meteorite representatives of the martian crust. They are water rich, lithologically varied, and preserve the oldest martian zircon grains yet discovered that formed ca. 4500–4300 Ma. The meteorite thus provides us with an invaluable record of the crustal and environmental conditions on early Mars. Resetting of some radioisotopic chronometers occurred in response to a major thermal disturbance event ca. 1500–1400 Ma, likely caused by an impactor that brecciated and redeposited NWA 7034 near the surface in an ejecta blanket. Lithologies comprising NWA 7034 were then aqueously altered by a long-lasting impact-induced hydrothermal system, before being excavated and ejected by a subsequent impact at ca. 5–15 Ma. This review compiles chronological and petrological information into an overarching geochronological summary for NWA 7034 and paired samples. We then provide a synopsis for the volatile (H2O, C) inventory and hydrothermal alteration history of NWA 7034. From this geochronological history and volatile inventory, we interpret and assess two potential periods of martian habitability: (1) an early window of pre-Noachian planetary habitability, and (2) impact-derived hydrothermal systems that allowed intermittent habitable crater environments well into the Amazonian.

Published

2022

21. Preservation of Terrestrial Microorganisms and Organics Within Alteration Products of Chondritic Meteorites from the Nullarbor Plain, Australia

Author

Alastair W. Tait, Siobhan A. Wilson, Andrew G. Tomkins, Jessica L. Hamilton, Emma J. Gagen, Alex I. Holman, Kliti Grice, Louisa J. Preston, David J. Paterson, and Gordon Southam

Subjects

Minerals, Extraterrestrial Environment, Space and Planetary Science, Earth, Planet, Exobiology, Mars, Meteoroids, Agricultural and Biological Sciences (miscellaneous)

Abstract

Meteorites that fall to Earth quickly become contaminated with terrestrial microorganisms. These meteorites are out of chemical equilibrium in the environments where they fall, and equilibration promotes formation of low-temperature alteration minerals that can entomb contaminant microorganisms and thus preserve them as microfossils. Given the well-understood chemistry of meteorites and their recent discovery on Mars by rovers, a similarly weathered meteorite on Mars could preserve organic and fossil evidence of a putative past biosphere at the martian surface. Here, we used several techniques to assess the potential of alteration minerals to preserve microfossils and biogenic organics in terrestrially weathered ordinary chondrites from the Nullarbor Plain, Australia. We used acid etching of ordinary chondrites to reveal entombed fungal hyphae, modern biofilms, and diatoms within alteration minerals. We employed synchrotron X-ray fluorescence microscopy of alteration mineral veins to map the distribution of redox-sensitive elements of relevance to chemolithotrophic organisms, such as Mn-cycling bacteria. We assessed the biogenicity of fungal hyphae within alteration veins using a combination of Fourier-transform infrared spectroscopy and pyrolysis gas chromatography-mass spectrometry, which showed that alteration minerals sequester and preserve organic molecules at various levels of decomposition. Our combined analyses results show that fossil microorganisms and the organic molecules they produce are preserved within calcite-gypsum admixtures in meteorites. Furthermore, the distributions of redox-sensitive elements (

Published

2022

22. Space Exposure of Amino Acids and Their Precursors during the Tanpopo Mission

Author

Yumiko Obayashi, Kensei Kobayashi, Hajime Mita, Yoshiyuki Oguri, Isao Yoda, Yoko Kebukawa, Hirofumi Hashimoto, Akihiko Yamagishi, Takeo Kaneko, Eiichi Imai, Shin-ichi Yokobori, tomohito sato, Hitoshi Fukuda, Takuya Yokoo, Hajime Yano, Satoshi Yoshida, Kazuhiro Kanda, Kazumichi Nakagawa, and Saaya Minematsu

Subjects

chemistry.chemical_classification, Cosmic Dust, Extraterrestrial Environment, Earth, Planet, fungi, Space exposure, Meteoroids, Space Flight, Agricultural and Biological Sciences (miscellaneous), Amino acid, Astrobiology, chemistry, Space and Planetary Science, Chondrite, Extraterrestrial life, International Space Station, Amino Acids, Earth (classical element)

Abstract

Amino acids have been detected in extraterrestrial bodies such as carbonaceous chondrites (CCs), which suggests that extraterrestrial organics could be the source of the first life on Earth, and interplanetary dust particles (IDPs) or micrometeorites (MMs) are promising carriers of extraterrestrial organic carbon. Some amino acids found in CCs are amino acid precursors, but these have not been well characterized. The Tanpopo mission was conducted in Earth orbit from 2015 to 2019, and the stability of glycine (Gly), hydantoin (Hyd), isovaline (Ival), 5-ethyl-5-methylhydantoin (EMHyd), and complex organics formed by proton irradiation from CO, NH

Published

2021

23. Growth on Carbohydrates from Carbonaceous Meteorites Alters the Immunogenicity of Environment-Derived Bacterial Pathogens

Author

Mihai G. Netea, Georgios Renieris, Jorge Domínguez-Andrés, Petra Rettberg, Huub J. M. Op den Camp, Laura van Niftrik, Rob Mesman, Marien I. de Jonge, Evangelos J. Giamarellos-Bourboulis, Sam J. Moons, Thomas J. Boltje, Jos W. M. van der Meer, and Marc J. Eleveld

Subjects

Extraterrestrial Environment, lnfectious Diseases and Global Health Radboud Institute for Molecular Life Sciences [Radboudumc 4], Carbohydrates, Microorganisms, Mars, Synthetic Organic Chemistry, Biology, 01 natural sciences, Astrobiology, 03 medical and health sciences, All institutes and research themes of the Radboud University Medical Center, Lead (geology), 0103 physical sciences, Spacecraft, 010303 astronomy & astrophysics, 030304 developmental biology, 0303 health sciences, Bacteria, Immunity, Meteoroids, Space Flight, Space Exploration, Agricultural and Biological Sciences (miscellaneous), Space and Planetary Science, Ecological Microbiology, Extraterrestrial life, Cytokines, Meteorites

Abstract

The last decade has witnessed a renewed interest in space exploration. Public and private institutions are investing considerable effort toward the direct exploration of the Moon and Mars, as well as more distant bodies in the solar system. Both automated and human-crewed spacecraft are being considered in these efforts. As inevitable fellow travelers on the bodies of astronauts, spaceships, or equipment, terrestrial microorganisms will undoubtedly come into contact with extraterrestrial environments, despite stringent decontamination. These microorganisms could eventually adapt and grow in their new habitats, where they might potentially recolonize and lead to the infection of the human space travelers. In this article, we demonstrate that clinically relevant bacterial species found in the environment are able to grow in minimal media with sugar compounds identified in extraterrestrial carbon sources. As a surrogate model, we used carbohydrates previously isolated from carbonaceous meteorites. The bacteria underwent an adaptation process that caused structural modifications in the cell envelope that sparked changes in pathogenic potential, both in vitro and in vivo. Understanding the adaptation of microorganisms exposed to extraterrestrial environments, with subsequent changes in their immunogenicity and virulence, requires a comprehensive analysis of such scenarios to ensure the safety of major space expeditions in the decades to come.

Published

2020

24. Photolysis of Cometary Organic Dust Analogs on the EXPOSE-R2 Mission at the International Space Station

Author

Didier Chaput, Giovanni Strazzulla, G. A. Baratta, Maria Elisabetta Palumbo, Hervé Cottin, Mario Accolla, Centre National d'Études Spatiales [Toulouse] (CNES), Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA (UMR_7583)), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), ITA, and FRA

Subjects

Organic dust, Time Factors, Astrochemistry, Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Space (mathematics), Helium, 01 natural sciences, Astrobiology, 0103 physical sciences, International Space Station, Organic Chemicals, Spacecraft, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Photolysis, [SDU.ASTR]Sciences of the Universe [physics]/Astrophysics [astro-ph], Spectrum Analysis, Photodissociation, Dust, Meteoroids, Agricultural and Biological Sciences (miscellaneous), EXPOSE, [SDU]Sciences of the Universe [physics], Space and Planetary Science, Environmental science

Abstract

International audience; We describe the results obtained on a set of organic samples that have been part of the experiment "Photochemistry on the Space Station (PSS)" on the EXPOSE-R2 mission conducted on the EXPOSE-R facility situated outside the International Space Station (ISS). The organic samples were prepared in the Catania laboratory by 200 keV He+ irradiation of N2:CH4:CO icy mixtures deposited at 17 K, on vacuum UV (VUV) transparent MgF2 windows. This organic material contains different chemical groups, including triple CN bonds, that are thought to be of interest for astrobiology. It is widely accepted that materials similar to that produced in the laboratory by ion irradiation of frozen ices could be present in some astrophysical environments such as comets. Once expelled from comets, these materials are exposed to solar radiation during their interplanetary journey. In the young Solar System, some of these processed materials could have reached early Earth and contributed to its chemical and prebiotic evolution. The samples were exposed for 16 months to the unshielded solar UV photons. It was found that, if an interplanetary dust particle (IDP) containing organic material (50% vol) is large enough (>20-30 μm), relevant chemical groups, such as those containing the CN triple bond, can survive for many years (>104 years) in the interplanetary medium.

Published

2019

25. Survival of Extremotolerant Bacteria from the Mukundpura Meteorite Impact Crater

Author

Priyanka Kulkarni, B S Patil, J K Meka, Rebecca Thombre, S. Vijayan, Parag Vaishampayan, T Pataskar, Bhalamurugan Sivaraman, Arman Seuylemezian, and E. Shivakarthik

Subjects

DNA, Bacterial, 010504 meteorology & atmospheric sciences, Origin of Life, Bacillus, 01 natural sciences, High-Energy Shock Waves, Astrobiology, Impact crater, Abiogenesis, RNA, Ribosomal, 16S, Proteobacteria, 0103 physical sciences, 010303 astronomy & astrophysics, Soil Microbiology, 0105 earth and related environmental sciences, Microbial Viability, Microbiota, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Acidobacteria, Actinobacteria, Prebiotic chemistry, Meteorite, Space and Planetary Science, Carbonaceous chondrite, Geological survey, Metagenomics, Bacillus thermocopriae, Geology

Abstract

Carbonaceous meteorites provide clues with regard to prebiotic chemistry and the origin of life. Geological Survey of India recorded a carbonaceous chondrite meteorite fall in Mukundpura, India, on June 6, 2017. We conducted a study to investigate the microbial community that survived the meteorite impact. 16S rRNA metagenomic sequencing indicates the presence of Actinobacteria, Proteobacteria, and Acidobacteria in meteorite impact soil. Comparative phylogenetic analysis revealed an intriguing abundance of class Bacilli in the impact soil.

Published

2019

26. Earth-like Habitable Environments in the Subsurface of Mars

Author

Vlada Stamenkovic, B. Sherwood Lollar, John F. Mustard, Ana-Catalina Plesa, Joseph R. Michalski, Oliver Warr, Tullis C. Onstott, A. M. Palumbo, K. M. Cannon, J. D. Tarnas, J.-P. Lorand, Laboratoire de Planétologie et Géodynamique [UMR 6112] (LPG), Université d'Angers (UA)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), and Université de Nantes (UN)-Université de Nantes (UN)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

010504 meteorology & atmospheric sciences, Extraterrestrial Environment, Earth, Planet, subsurface environment, Mars, 01 natural sciences, Astrobiology, Pore water pressure, chemistry.chemical_compound, 0103 physical sciences, Sulfate, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Martian, habitable environments, Biosphere, Mars Exploration Program, Meteoroids, 15. Life on land, Agricultural and Biological Sciences (miscellaneous), habitability, chemistry, Meteorite, 13. Climate action, Space and Planetary Science, [SDU]Sciences of the Universe [physics], sulfate-reducing bacteria, Radiolysis, Environmental science, Mars subsurface, Groundwater, Hydrogen

Abstract

In Earth's deep continental subsurface, where groundwaters are often isolated for >106 to 109 years, energy released by radionuclides within rock produces oxidants and reductants that drive metabolisms of non-photosynthetic microorganisms. Similar processes could support past and present life in the martian subsurface. Sulfate-reducing microorganisms are common in Earth's deep subsurface, often using hydrogen derived directly from radiolysis of pore water and sulfate derived from oxidation of rock-matrix-hosted sulfides by radiolytically derived oxidants. Radiolysis thus produces redox energy to support a deep biosphere in groundwaters isolated from surface substrate input for millions to billions of years on Earth. Here, we demonstrate that radiolysis by itself could produce sufficient redox energy to sustain a habitable environment in the subsurface of present-day Mars, one in which Earth-like microorganisms could survive wherever groundwater exists. We show that the source localities for many martian meteorites are capable of producing sufficient redox nutrients to sustain up to millions of sulfate-reducing microbial cells per kilogram rock via radiolysis alone, comparable to cell densities observed in many regions of Earth's deep subsurface. Additionally, we calculate variability in supportable sulfate-reducing cell densities between the martian meteorite source regions. Our results demonstrate that martian subsurface groundwaters, where present, would largely be habitable for sulfate-reducing bacteria from a redox energy perspective via radiolysis alone. We present evidence for crustal regions that could support especially high cell densities, including zones with high sulfide concentrations, which could be targeted by future subsurface exploration missions.

Published

2021

27. Eukaryotic Colonization of Micrometer-Scale Cracks in Rocks: A 'Microfluidics' Experiment Using Naturally Weathered Meteorites from the Nullarbor Plain, Australia

Author

Andrew G. Tomkins, Emma J. Gagen, Siobhan A. Wilson, Alastair W. Tait, and Gordon Southam

Subjects

Micrometer scale, Extraterrestrial Environment, Endolith, Surface Properties, Microfluidics, Australia, Eukaryota, Mars, Microporous material, Meteoroids, Microfluidic Analytical Techniques, Agricultural and Biological Sciences (miscellaneous), Astrobiology, Calcium Carbonate, Meteorite, Space and Planetary Science, Exobiology, Colonization, Porosity, Geology

Abstract

The advent of microfluidics has revolutionized the way we understand how microorganisms propagate through microporous spaces. Here, we apply this understanding to the study of how endolithic environmental microorganisms colonize the interiors of sterile rock. The substrates used for our study are stony meteorites from the Nullarbor Plain, Australia; a semiarid limestone karst that provides an ideal setting for preserving meteorites. Periodic flooding of the Nullarbor provides a mechanism by which microorganisms and exogenous nutrients may infiltrate meteorites. Our laboratory experiments show that environmental microorganisms reach depths greater than 400 μm by propagating through existing brecciation, passing through cracks no wider than the diameter of a resident cell (

Published

2019

28. Comprehensive Search of Stable Isomers of Alanine and Alanine Precursors in Prebiotic Syntheses.

Author

Shoji M, Watanabe N, Hori Y, Furuya K, Umemura M, Boero M, and Shigeta Y

Subjects

Amino Acids chemistry, Stereoisomerism, Alanine, Meteoroids

Abstract

Enantiomeric excesses of l-amino acids have been detected in meteorites; however, their molecular mechanism and prebiotic syntheses are still a matter of debate. To elucidate the origin of homochirality, alanine and the chiral precursors formed in prebiotic processes were investigated with regard to their stabilities among their isomers by employing the minimum energy principle, namely, the abundancy of a molecule in the interstellar medium is directly correlated to the stability among isomers. To facilitate the search for possible isomers, we developed a new isomer search algorithm, the random connection method, and performed a thorough search for all the stable isomers within a given chemical formula. We found that alanine and most of its precursors are located at higher energy by more than 5.7 kcal mol -1 , with respect to the most stable isomer that consists of a linear-chain structure, whereas only the 2-aminopropanenitrile is the most stable isomer among all others possible. The inherent stability of the α-amino nitrile suggests that the 2-aminopropanenitrile is the dominant contribution in the formation of the common enantiomeric excess over α-amino acids.

Published

2022

29. Resolving the History of Life on Earth by Seeking Life As We Know It on Mars.

Author

Carr CE

Subjects

Earth, Planet, Exobiology, Extraterrestrial Environment chemistry, Geology, Mars, Meteoroids

Abstract

An origin of Earth life on Mars would resolve significant inconsistencies between the inferred history of life and Earth's geologic history. Life as we know it utilizes amino acids, nucleic acids, and lipids for the metabolic, informational, and compartment-forming subsystems of a cell. Such building blocks may have formed simultaneously from cyanosulfidic chemical precursors in a planetary surface scenario involving ultraviolet light, wet-dry cycling, and volcanism. On the inferred water world of early Earth, such an origin would have been limited to volcanic island hotspots. A cyanosulfidic origin of life could have taken place on Mars via photoredox chemistry, facilitated by orders-of-magnitude more sub-aerial crust than early Earth, and an earlier transition to oxidative conditions that could have been involved in final fixation of the genetic code. Meteoritic bombardment may have generated transient habitable environments and ejected and transferred life to Earth. Ongoing and future missions to Mars offer an unprecedented opportunity to confirm or refute evidence consistent with a cyanosulfidic origin of life on Mars, search for evidence of ancient life, and constrain the evolution of Mars' oxidation state over time. We should seek to prove or refute a martian origin for life on Earth alongside other possibilities.

Published

2022

30. Preservation of Terrestrial Microorganisms and Organics Within Alteration Products of Chondritic Meteorites from the Nullarbor Plain, Australia.

Author

Tait AW, Wilson SA, Tomkins AG, Hamilton JL, Gagen EJ, Holman AI, Grice K, Preston LJ, Paterson DJ, and Southam G

Subjects

Earth, Planet, Exobiology methods, Extraterrestrial Environment, Minerals analysis, Mars, Meteoroids

Abstract

Meteorites that fall to Earth quickly become contaminated with terrestrial microorganisms. These meteorites are out of chemical equilibrium in the environments where they fall, and equilibration promotes formation of low-temperature alteration minerals that can entomb contaminant microorganisms and thus preserve them as microfossils. Given the well-understood chemistry of meteorites and their recent discovery on Mars by rovers, a similarly weathered meteorite on Mars could preserve organic and fossil evidence of a putative past biosphere at the martian surface. Here, we used several techniques to assess the potential of alteration minerals to preserve microfossils and biogenic organics in terrestrially weathered ordinary chondrites from the Nullarbor Plain, Australia. We used acid etching of ordinary chondrites to reveal entombed fungal hyphae, modern biofilms, and diatoms within alteration minerals. We employed synchrotron X-ray fluorescence microscopy of alteration mineral veins to map the distribution of redox-sensitive elements of relevance to chemolithotrophic organisms, such as Mn-cycling bacteria. We assessed the biogenicity of fungal hyphae within alteration veins using a combination of Fourier-transform infrared spectroscopy and pyrolysis gas chromatography-mass spectrometry, which showed that alteration minerals sequester and preserve organic molecules at various levels of decomposition. Our combined analyses results show that fossil microorganisms and the organic molecules they produce are preserved within calcite-gypsum admixtures in meteorites. Furthermore, the distributions of redox-sensitive elements ( e.g. , Mn) within alteration minerals are localized, which qualitatively suggests that climatically or microbially facilitated element mobilization occurred during the meteorite's residency on Earth. If returned as part of a sample suite from the martian surface, ordinary chondrites could preserve similar, recognizable evidence of putative past life and/or environmental change.

Published

2022

31. Irradiation of Phenylalanine at 300 K by MeV Ions.

Author

Mejía C, da Costa CAP, Iza P, and da Silveira EF

Subjects

Ions, Kinetics, Spectroscopy, Fourier Transform Infrared, Meteoroids, Phenylalanine

Abstract

Phenylalanine (Phe) is an amino acid that has been identified in carbonaceous meteorites; its formation mechanism in space is unknown, and its radioresistance has been the subject of investigation. This work aims at studying, in the laboratory, the Phe radiolysis by cosmic analogues. The Phe destruction rate, at 300 K, is measured for H, He, and N ion beam irradiation in the 0.5 to 2 kinetic MeV range. Fourier transform infrared (FTIR) spectroscopy was employed to monitor the molecular degradation as a function of fluence. The Phe apparent destruction cross-section, σ ap d , which includes radiolysis and sputtering processes, is determined to be proportional to the electronic stopping power, S e . The measured parameter D 0  = 14.3 ± 2.2 eV/molec in the relationship, and σ d a p  =  S e / D 0 is interpreted as the mean absorbed dose necessary to dissociate or eject a Phe molecule. The Phe half-life in the interstellar medium is predicted to be about 10 million years, H + ions the main destructive cosmic ray constituent.

Published

2022

32. Perspectives on Comets, Comet-like Asteroids, and Their Predisposition to Provide an Environment That Is Friendly to Life

Author

Georg Hildenbrand, Katharina Bosiek, and Michael Hausmann

Subjects

Physics, Solar System, 010504 meteorology & atmospheric sciences, Meteoroid, Comet, Astronomy, Meteoroids, Centaur, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Minor Planets, Astrobiology, Meteorite, Space and Planetary Science, Asteroid, 0103 physical sciences, Asteroid belt, 010303 astronomy & astrophysics, Late Heavy Bombardment, 0105 earth and related environmental sciences

Abstract

In recent years, studies have shown that there are many similarities between comets and asteroids. In some cases, it cannot even be determined to which of these groups an object belongs. This is especially true for objects found beyond the main asteroid belt. Because of the lack of comet fragments, more progress has been made concerning the chemical composition of asteroids. In particular, the SMASSII classification establishes a link between the reflecting spectra and chemical composition of asteroids and meteorites. To find clues for the chemical structure of comets, the parameters of all known asteroids of the SMASSII classification were compared to those of comet groups like the Encke-type comets, the Jupiter-family comets, and the Halley-type comets, as well as comet-like objects like the damocloids and the centaurs. Fifty-six SMASSII objects similar to comets were found and are categorized as comet-like asteroids in this work. Aside from the chemistry, it is assumed that the available energy on these celestial bodies plays an important role concerning habitability. For the determination of the available energy, the effective temperature was calculated. Additionally, the size of these objects was considered in order to evaluate the possibility of a liquid water core, which provides an environment that is more likely to support processes necessary to create the building blocks of life. Further study of such objects could be notable for the period of the Late Heavy Bombardment and could therefore provide important implications for our understanding of the inner workings of the prebiotic evolution within the Solar System since the beginning.

Published

2016

33. Functional Properties of Amino Acid Side Chains as Biomarkers of Extraterrestrial Life

Author

Christos D. Georgiou

Subjects

0301 basic medicine, Protocell, Extraterrestrial Environment, Stereochemistry, Earth, Planet, Peptide, Catalysis, Protein Structure, Secondary, 03 medical and health sciences, chemistry.chemical_compound, Surface-Active Agents, Amide, Terminal groups, Exobiology, Hypothesis Article, Side chains, chemistry.chemical_classification, Hydrolysis, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Amino acid, 030104 developmental biology, Enzyme, chemistry, Space and Planetary Science, Thiol, Amino acids, Protein quaternary structure, Oligopeptides, Biomarkers

Abstract

The present study proposes to search our solar system (Mars, Enceladus, Europa) for patterns of organic molecules that are universally associated with biological functions and structures. The functions are primarily catalytic because life could only have originated within volume/space-constrained compartments containing chemical reactions catalyzed by certain polymers. The proposed molecular structures are specific groups in the side chains of amino acids with the highest catalytic propensities related to life on Earth, that is, those that most frequently participate as key catalytic groups in the active sites of enzymes such as imidazole, thiol, guanidinium, amide, and carboxyl. Alternatively, these or other catalytic groups can be searched for on non-amino-acid organic molecules, which can be tested for certain hydrolytic catalytic activities. The first scenario assumes that life may have originated in a similar manner as the terrestrial set of α-amino acids, while the second scenario does not set such a requirement. From the catalytic propensity perspective proposed in the first scenario, life must have invented amino acids with high catalytic propensity (His, Cys, Arg) in order to overcome, and be complemented by, the low catalytic propensity of the initially available abiogenic amino acids. The abiogenic and the metabolically invented amino acids with the lowest catalytic propensity can also serve as markers of extraterrestrial life when searching for patterns on the basis of the following functional propensities related to protein secondary/quaternary structure: (1) amino acids that are able to form α-helical intramembrane peptide domains, which can serve as primitive transporters in protocell membrane bilayers and catalysts of simple biochemical reactions; (2) amino acids that tend to accumulate in extremophile proteins of Earth and possibly extraterrestrial life. The catalytic/structural functional propensity approach offers a new perspective in the search for extraterrestrial life and could help unify previous amino acid–based approaches.

Published

2018

34. Heat, Aromatic Units, and Iron-Rich Phyllosilicates: A Mechanism for Making Macromolecules in the Early Solar System

Author

Mark A. Sephton and Jonathan S. Watson

Subjects

inorganic chemicals, Chromatography, Gas, Hot Temperature, Macromolecular Substances, Iron, Inorganic chemistry, chemistry.chemical_element, Hydrocarbons, Aromatic, Catalysis, Gas Chromatography-Mass Spectrometry, Metal, chemistry.chemical_compound, Nickel, Cations, Silicates, Cobalt, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Montmorillonite, chemistry, Polymerization, Metals, Space and Planetary Science, visual_art, Bentonite, visual_art.visual_art_medium, Clay, Aluminum Silicates, Oxidative coupling of methane, Solar System, Macromolecule

Abstract

The major organic component in carbonaceous chondrites is a highly aromatic macromolecular material. Aromatic organic matter and phyllosilicates are colocated in these meteorites, and it is possible that the physical association represents a synthetic chemical relationship. To explore the potential reactions that could take place to produce the aromatic macromolecular material, we heated various simple aromatic units in the presence of montmorillonite with different exchanged cations. The majority of cation-exchanged montmorillonites tested, sodium-, aluminum-, iron-, nickel-, and cobalt-rich montmorillonites, do not produce polymerization products. By contrast, Fe(3+) cation-exchanged montmorillonite readily facilitates addition reactions between aromatic hydrocarbons. A feasible mechanism for the process is oxidative coupling, which involves a corresponding reduction of the Fe(3+) cation to its Fe(2+) counterpart. A similar reduction process for the other metal cations does not take place, highlighting the importance of iron. This simple process is one feasible mechanism for the construction of aromatic macromolecules such as those found in carbonaceous chondrites. The search for a relationship between Fe(3+)-rich phyllosilicates and aromatic organic structures (particularly dimers, trimers, and more polymerized forms) in carbonaceous chondrites would represent an effective test for constraining the role of clay catalysis in the early Solar System.

Published

2015

35. Space Exposure of Amino Acids and Their Precursors during the Tanpopo Mission.

Author

Kobayashi K, Mita H, Kebukawa Y, Nakagawa K, Kaneko T, Obayashi Y, Sato T, Yokoo T, Minematsu S, Fukuda H, Oguri Y, Yoda I, Yoshida S, Kanda K, Imai E, Yano H, Hashimoto H, Yokobori SI, and Yamagishi A

Subjects

Amino Acids analysis, Cosmic Dust analysis, Earth, Planet, Extraterrestrial Environment, Meteoroids, Space Flight

Abstract

Amino acids have been detected in extraterrestrial bodies such as carbonaceous chondrites (CCs), which suggests that extraterrestrial organics could be the source of the first life on Earth, and interplanetary dust particles (IDPs) or micrometeorites (MMs) are promising carriers of extraterrestrial organic carbon. Some amino acids found in CCs are amino acid precursors, but these have not been well characterized. The Tanpopo mission was conducted in Earth orbit from 2015 to 2019, and the stability of glycine (Gly), hydantoin (Hyd), isovaline (Ival), 5-ethyl-5-methylhydantoin (EMHyd), and complex organics formed by proton irradiation from CO, NH 3 , and H 2 O (CAW) in space were analyzed by high-performance liquid chromatography and/or gas chromatography/mass spectrometry. The target substances showed a logarithmic decomposition over 1-3 years upon space exposure. Recoveries of Gly and CAW were higher than those of Hyd, Ival, and EMHyd. Ground simulation experiments showed different results: Hyd was more stable than Gly. Solar ultraviolet light was fatal to all organics, and they required protection when carried by IDPs/MMs. Thus, complex amino acid precursors (such as CAW) were possibly more robust than simple precursors during transportation to primitive Earth. The Tanpopo 2 mission is currently being conducted to expose organics to more probable space conditions.

Published

2021

36. Selection of Amino Acid Chirality via Neutrino Interactions with

Author

Michael A, Famiano, Richard N, Boyd, Toshitaka, Kajino, and Takashi, Onaka

Subjects

Quantitative Biology::Biomolecules, Evolution, Chemical, Magnetic Fields, Electricity, Extraterrestrial Environment, Models, Chemical, Nitrogen, Stereoisomerism, Meteoroids, Amino Acids, Elementary Particles, Research Articles

Abstract

Previous work has suggested that the chirality of the amino acids could be established in the magnetic field of a nascent neutron star from a core-collapse supernova or massive collapsar. The magnetic field would orient the 14N nuclei, and the alignment of its nuclear spin with respect to those of the electron antineutrinos emitted from the collapsing star would determine the probability of destruction of the 14N nuclei by interactions with the antineutrinos. Subsequent work estimated the bulk polarization of the 14N nuclei in large rotating meteoroids in such an environment. The present work adds a crucial piece of this model by describing the details by which the selective 14N nuclear destruction would produce molecular chiral selectivity. The effects of the neutrino-induced interactions on the 14N nuclei bound in amino acids polarized in strong magnetic fields are studied. It is shown that electric fields in the reference frame of the nuclei modify the magnetic field at the nucleus, creating nuclear magnetizations that are asymmetric in chirality. The antineutrino cross sections depend on this magnetization, creating a selective destructive effect. The environmental conditions and sites in which such a selection mechanism could occur are discussed. Selective destruction of D-enantiomers results in enantiomeric excesses which may be sufficient to drive subsequent autocatalysis necessary to produce the few-percent enantiomeric excesses found in meteorites and subsequent homochirality. Molecular quantum chemical calculations were performed for alanine, and the chirality-dependent effects studied were included. A preference for left-handed molecules was found, and enantiomeric excesses as high as 0.02% were estimated for molecules in the electromagnetic conditions expected from a core-collapse supernova. Key Words: Amino acids—Supernovae—Antineutrinos—Enantiomeric excess—Chirality. Astrobiology 18, 190–206.

Published

2017

37. Earth-like Habitable Environments in the Subsurface of Mars.

Author

Tarnas JD, Mustard JF, Sherwood Lollar B, Stamenković V, Cannon KM, Lorand JP, Onstott TC, Michalski JR, Warr O, Palumbo AM, and Plesa AC

Subjects

Earth, Planet, Extraterrestrial Environment, Hydrogen, Mars, Meteoroids

Abstract

In Earth's deep continental subsurface, where groundwaters are often isolated for >10 6 to 10 9 years, energy released by radionuclides within rock produces oxidants and reductants that drive metabolisms of non-photosynthetic microorganisms. Similar processes could support past and present life in the martian subsurface. Sulfate-reducing microorganisms are common in Earth's deep subsurface, often using hydrogen derived directly from radiolysis of pore water and sulfate derived from oxidation of rock-matrix-hosted sulfides by radiolytically derived oxidants. Radiolysis thus produces redox energy to support a deep biosphere in groundwaters isolated from surface substrate input for millions to billions of years on Earth. Here, we demonstrate that radiolysis by itself could produce sufficient redox energy to sustain a habitable environment in the subsurface of present-day Mars, one in which Earth-like microorganisms could survive wherever groundwater exists. We show that the source localities for many martian meteorites are capable of producing sufficient redox nutrients to sustain up to millions of sulfate-reducing microbial cells per kilogram rock via radiolysis alone, comparable to cell densities observed in many regions of Earth's deep subsurface. Additionally, we calculate variability in supportable sulfate-reducing cell densities between the martian meteorite source regions. Our results demonstrate that martian subsurface groundwaters, where present, would largely be habitable for sulfate-reducing bacteria from a redox energy perspective via radiolysis alone. We present evidence for crustal regions that could support especially high cell densities, including zones with high sulfide concentrations, which could be targeted by future subsurface exploration missions.

Published

2021

38. Martian Magmatic Clay Minerals Forming Vesicles: Perfect Niches for Emerging Life?

Author

Viennet JC, Bernard S, Le Guillou C, Sautter V, Grégoire B, Jambon A, Pont S, Beyssac O, Zanda B, Hewins R, and Remusat L

Subjects

Clay, Extraterrestrial Environment, Minerals, Mars, Meteoroids

Abstract

Mars was habitable in its early history, but the consensus is that it is quite inhospitable today, in particular because its modern climate cannot support stable liquid water at the surface. Here, we report the presence of magmatic Fe/Mg clay minerals within the mesostasis of the martian meteorite NWA 5790, an unaltered 1.3 Ga nakhlite archetypal of the martian crust. These magmatic clay minerals exhibit a vesicular texture that forms a network of microcavities or pockets, which could serve as microreactors and allow molecular crowding, a necessary step for the emergence of life. Because their formation does not depend on climate, such niches for emerging life may have been generated on Mars at many periods throughout its history, regardless of the stability or availability of liquid water at the surface.

Published

2021

39. Experimental Investigation of the Formation of Formaldehyde by Hadean and Noachian Impacts.

Author

Masuda S, Furukawa Y, Kobayashi T, Sekine T, and Kakegawa T

Subjects

Atmosphere, Earth, Planet, Formaldehyde, Water, Meteoroids

Abstract

Formaldehyde (FA) is an important precursor in the abiotic synthesis of major biomolecules including amino acids, sugars, and nucleobases. Thus, spontaneous formation of prebiotic FA must have been crucial for the chemical origin of life. The frequent impacts of meteorites and asteroids on Hadean Earth have been considered one of the abiotic synthetic processes of organic compounds. However, the impact-induced formation of FA from CO 2 as the major atmospheric constituent has not been confirmed yet. This study investigated the formation of FA in impact-induced reactions among meteoritic minerals, bicarbonate, gaseous nitrogen, and water to simulate the abiotic process experimentally. Products were analyzed with ultra-high-performance liquid chromatography/tandem mass spectrometry and powder X-ray diffraction techniques. The results show the formation of FA and oxidation of metallic iron to siderite in the impact shock experiments. This indicates that this important prebiotic molecule was also synthesized by impacts of iron-bearing meteorites/asteroids on the Hadean oceans. The impact events might have generated spatially and temporally FA-enriched localized environments. Moreover, the impact-induced synthesis of FA may have also occurred on Noachian Mars given the presence of liquid water and a CO 2 -N 2 -rich atmosphere on the planet.

Published

2021

40. Following the Interstellar History of Carbon: From the Interiors of Stars to the Surfaces of Planets

Author

Wolf D. Geppert, DeWayne T. Halfen, Yuri Aikawa, and Lucy M. Ziurys

Subjects

Solar System, Cosmic Dust, Astrochemistry, 010504 meteorology & atmospheric sciences, Interstellar cloud, Planets, Astrophysics, 01 natural sciences, Astrobiology, Interplanetary dust cloud, Stars, Celestial, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Physics, Star formation, Interstellar ice, Circumstellar envelope, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Carbon, Interstellar medium, Space and Planetary Science, Astrophysics::Earth and Planetary Astrophysics

Abstract

The chemical history of carbon is traced from its origin in stellar nucleosynthesis to its delivery to planet surfaces. The molecular carriers of this element are examined at each stage in the cycling of interstellar organic material and their eventual incorporation into solar system bodies. The connection between the various interstellar carbon reservoirs is also examined. Carbon has two stellar sources: supernova explosions and mass loss from evolved stars. In the latter case, the carbon is dredged up from the interior and then ejected into a circumstellar envelope, where a rich and unusual C-based chemistry occurs. This molecular material is eventually released into the general interstellar medium through planetary nebulae. It is first incorporated into diffuse clouds, where carbon is found in polyatomic molecules such as H2CO, HCN, HNC, c-C3H2, and even C60+. These objects then collapse into dense clouds, the sites of star and planet formation. Such clouds foster an active organic chemistry, producing compounds with a wide range of functional groups with both gas-phase and surface mechanisms. As stars and planets form, the chemical composition is altered by increasing stellar radiation, as well as possibly by reactions in the presolar nebula. Some molecular, carbon-rich material remains pristine, however, encapsulated in comets, meteorites, and interplanetary dust particles, and is delivered to planet surfaces. Key Words: Carbon isotopes-Prebiotic evolution-Interstellar molecules-Comets-Meteorites. Astrobiology 16, 997-1012.

Published

2016

41. Formation of Replicating Saponite from a Gel in the Presence of Oxalate: Implications for the Formation of Clay Minerals in Carbonaceous Chondrites and the Origin of Life

Author

Reinhard Hesse, S. Kelly Sears, Hojatollah Vali, Dennis D. Eberl, Dirk Schumann, and Hyman Hartman

Subjects

Origin of Life, Mineralogy, engineering.material, Catalysis, Oxalate, chemistry.chemical_compound, Microscopy, Electron, Transmission, X-Ray Diffraction, Magnesium Silicates, Chondrite, Aluminosilicate, Saponite, Minerals, Oxalates, Mineral, Chondrule, Meteoroids, Agricultural and Biological Sciences (miscellaneous), Silicate, chemistry, Chemical engineering, Space and Planetary Science, engineering, Aluminum Silicates, Crystallization, Clay minerals, Gels

Abstract

The potential role of clay minerals in the abiotic origin of life has been the subject of ongoing debate for the past several decades. At issue are the clay minerals found in a class of meteorites known as carbonaceous chondrites. These clay minerals are the product of aqueous alteration of anhydrous mineral phases, such as olivine and orthopyroxene, that are often present in the chondrules. Moreover, there is a strong correlation in the occurrence of clay minerals and the presence of polar organic molecules. It has been shown in laboratory experiments at low temperature and ambient pressure that polar organic molecules, such as the oxalate found in meteorites, can catalyze the crystallization of clay minerals. In this study, we show that oxalate is a robust catalyst in the crystallization of saponite, an Al- and Mg-rich, trioctahedral 2:1 layer silicate, from a silicate gel at 60°C and ambient pressure. High-resolution transmission electron microscopy analysis of the saponite treated with octadecylammonium (n(C)=18) cations revealed the presence of 2:1 layer structures that have variable interlayer charge. The crystallization of these differently charged 2:1 layer silicates most likely occurred independently. The fact that 2:1 layer silicates with variable charge formed in the same gel has implications for our understanding of the origin of life, as these 2:1 clay minerals most likely replicate by a mechanism of template-catalyzed polymerization and transmit the charge distribution from layer to layer. If polar organic molecules like oxalate can catalyze the formation of clay-mineral crystals, which in turn promote clay microenvironments and provide abundant adsorption sites for other organic molecules present in solution, the interaction among these adsorbed molecules could lead to the polymerization of more complex organic molecules like RNA from nucleotides on early Earth.

Published

2012

42. Weathering of Post-Impact Hydrothermal Deposits from the Haughton Impact Structure: Implications for Microbial Colonization and Biosignature Preservation

Author

Neil R. Banerjee, John Parnell, Matthew R.M. Izawa, Roberta L. Flemming, Gordon R. Osinski, and Charles S. Cockell

Subjects

Calcite, Minerals, Mineral, Geochemistry, Mars, Mineralogy, Nunavut, Weathering, Meteoroids, Sulfides, Agricultural and Biological Sciences (miscellaneous), Hot Springs, Hydrothermal circulation, chemistry.chemical_compound, chemistry, Space and Planetary Science, Exobiology, Biosignature, Environmental Microbiology, Megacryst, Quartz, Iron Compounds, Gossan, Geology

Abstract

Meteorite impacts are among the very few processes common to all planetary bodies with solid surfaces. Among the effects of impact on water-bearing targets is the formation of post-impact hydrothermal systems and associated mineral deposits. The Haughton impact structure (Devon Island, Nunavut, Canada, 75.2 °N, 89.5 °W) hosts a variety of hydrothermal mineral deposits that preserve assemblages of primary hydrothermal minerals commonly associated with secondary oxidative/hydrous weathering products. Hydrothermal mineral deposits at Haughton include intra-breccia calcite-marcasite vugs, small intra-breccia calcite or quartz vugs, intra-breccia gypsum megacryst vugs, hydrothermal pipe structures and associated surface "gossans," banded Fe-oxyhydroxide deposits, and calcite and quartz veins and coatings in shattered target rocks. Of particular importance are sulfide-rich deposits and their associated assemblage of weathering products. Hydrothermal mineral assemblages were characterized structurally, texturally, and geochemically with X-ray diffraction, micro X-ray diffraction, optical and electron microscopy, and inductively coupled plasma atomic emission spectroscopy. Primary sulfides (marcasite and pyrite) are commonly associated with alteration minerals, including jarosite (K,Na,H(3)O)Fe(3)(SO(4))(2)(OH)(6), rozenite FeSO(4)·4(H(2)O), copiapite (Fe,Mg)Fe(4)(SO(4))(6)(OH)(2)·20(H(2)O), fibroferrite Fe(SO(4))(OH)·5(H(2)O), melanterite FeSO(4)·7(H(2)O), szomolnokite FeSO(4)·H(2)O, goethite α-FeO(OH), lepidocrocite γ-FeO(OH) and ferrihydrite Fe(2)O(3)·0.5(H(2)O). These alteration assemblages are consistent with geochemical conditions that were locally very different from the predominantly circumneutral, carbonate-buffered environment at Haughton. Mineral assemblages associated with primary hydrothermal activity, and the weathering products of such deposits, provide constraints on possible microbial activity in the post-impact environment. The initial period of active hydrothermal circulation produced primary mineral assemblages, including Fe sulfides, and was succeeded by a period dominated by oxidation and low-temperature hydration of primary minerals by surface waters. Active hydrothermal circulation can enable the rapid delivery of nutrients to microbes. Nutrient availability following the cessation of hydrothermal circulation is likely more restricted; therefore, the biological importance of chemical energy from hydrothermal mineral deposits increases with time. Weathering of primary hydrothermal deposits and dissolution and reprecipitation of mobile weathering products also create many potential habitats for endolithic microbes. They also provide a mechanism that may preserve biological materials, potentially over geological timescales.

Published

2011

43. Distribution and Stable Isotopic Composition of Amino Acids from Fungal Peptaibiotics: Assessing the Potential for Meteoritic Contamination

Author

Jason P. Dworkin, Daniel P. Glavin, Jamie E. Elsila, Michael P. Callahan, and Hans Brückner

Subjects

Aminoisobutyric Acids, Extraterrestrial Environment, Molecular Sequence Data, chemistry.chemical_element, chemistry.chemical_compound, Isotopes, Tandem Mass Spectrometry, Chondrite, Amino Acid Sequence, Amino Acids, Peptaibols, chemistry.chemical_classification, Isotope, Fungi, Valine, Meteoroids, Contamination, Agricultural and Biological Sciences (miscellaneous), Nitrogen, Amino acid, Isovaline, chemistry, Biochemistry, Meteorite, Space and Planetary Science, Carbon

Abstract

The presence of nonprotein α-dialkyl-amino acids such as α-aminoisobutyric acid (α-AIB) and isovaline (Iva), which are considered to be relatively rare in the terrestrial biosphere, has long been used as an indication of the indigeneity of meteoritic amino acids. However, recent work showing the presence of α-AIB and Iva in peptides produced by a widespread group of filamentous fungi indicates the possibility of a terrestrial biotic source for the α-AIB observed in some meteorites. We measured the amino acid distribution and stable carbon and nitrogen isotopic composition of four α-AIB-containing fungal peptides and compared this data to similar meteoritic measurements. We show that the relatively simple distribution of the C(4) and C(5) amino acids in fungal peptides is distinct from the complex distribution observed in many carbonaceous chondrites. We also identify potentially diagnostic relationships between the stable isotopic compositions of pairs of amino acids from the fungal peptides that may aid in ruling out fungal contamination as a source of meteoritic amino acids.

Published

2011

44. Urea, Glycolic Acid, and Glycerol in an Organic Residue Produced by Ultraviolet Irradiation of Interstellar/Pre-Cometary Ice Analogs

Author

Michel Nuevo, Uwe J. Meierhenrich, Wolfram Thiemann, Louis Le Sergeant d'Hendecourt, and Jan Hendrik Bredehöft

Subjects

Glycerol, Solar System, Astrochemistry, Earth, Planet, Ultraviolet Rays, Origin of Life, Inorganic chemistry, Chemical reaction, Gas Chromatography-Mass Spectrometry, Residue (chemistry), chemistry.chemical_compound, Abiogenesis, Acetamides, Exobiology, Urea, Glycolic acid, Chemistry, Ice, Temperature, Meteoroids, Amides, Agricultural and Biological Sciences (miscellaneous), Glycolates, Interstellar medium, Models, Chemical, Meteorite, Space and Planetary Science, Acids

Abstract

More than 50 stable organic molecules have been detected in the interstellar medium (ISM), from ground-based and onboard-satellite astronomical observations, in the gas and solid phases. Some of these organics may be prebiotic compounds that were delivered to early Earth by comets and meteorites and may have triggered the first chemical reactions involved in the origin of life. Ultraviolet irradiation of ices simulating photoprocesses of cold solid matter in astrophysical environments have shown that photochemistry can lead to the formation of amino acids and related compounds. In this work, we experimentally searched for other organic molecules of prebiotic interest, namely, oxidized acid labile compounds. In a setup that simulates conditions relevant to the ISM and Solar System icy bodies such as comets, a condensed CH(3)OH:NH(3) = 1:1 ice mixture was UV irradiated at approximately 80 K. The molecular constituents of the nonvolatile organic residue that remained at room temperature were separated by capillary gas chromatography and identified by mass spectrometry. Urea, glycolic acid, and glycerol were detected in this residue, as well as hydroxyacetamide, glycerolic acid, and glycerol amide. These organics are interesting target molecules to be searched for in space. Finally, tentative mechanisms of formation for these compounds under interstellar/pre-cometary conditions are proposed.

Published

2010

45. Growth on Carbohydrates from Carbonaceous Meteorites Alters the Immunogenicity of Environment-Derived Bacterial Pathogens.

Author

Domínguez-Andrés J, Eleveld M, Renieris G, Boltje TJ, Mesman RJ, van Niftrik L, Moons SJ, Rettberg P, van der Meer JWM, Giamarellos-Bourboulis EJ, Op den Camp HJM, de Jonge MI, and Netea MG

Subjects

Space Flight, Spacecraft, Bacteria growth & development, Bacteria immunology, Carbohydrates, Extraterrestrial Environment, Mars, Meteoroids

Abstract

The last decade has witnessed a renewed interest in space exploration. Public and private institutions are investing considerable effort toward the direct exploration of the Moon and Mars, as well as more distant bodies in the solar system. Both automated and human-crewed spacecraft are being considered in these efforts. As inevitable fellow travelers on the bodies of astronauts, spaceships, or equipment, terrestrial microorganisms will undoubtedly come into contact with extraterrestrial environments, despite stringent decontamination. These microorganisms could eventually adapt and grow in their new habitats, where they might potentially recolonize and lead to the infection of the human space travelers. In this article, we demonstrate that clinically relevant bacterial species found in the environment are able to grow in minimal media with sugar compounds identified in extraterrestrial carbon sources. As a surrogate model, we used carbohydrates previously isolated from carbonaceous meteorites. The bacteria underwent an adaptation process that caused structural modifications in the cell envelope that sparked changes in pathogenic potential, both in vitro and in vivo . Understanding the adaptation of microorganisms exposed to extraterrestrial environments, with subsequent changes in their immunogenicity and virulence, requires a comprehensive analysis of such scenarios to ensure the safety of major space expeditions in the decades to come.

Published

2020

46. The Role of Meteorite Impacts in the Origin of Life.

Author

Osinski GR, Cockell CS, Pontefract A, and Sapers HM

Subjects

Geological Phenomena, Earth, Planet, Evolution, Chemical, Extraterrestrial Environment chemistry, Meteoroids, Origin of Life

Abstract

The conditions, timing, and setting for the origin of life on Earth and whether life exists elsewhere in our solar system and beyond represent some of the most fundamental scientific questions of our time. Although the bombardment of planets and satellites by asteroids and comets has long been viewed as a destructive process that would have presented a barrier to the emergence of life and frustrated or extinguished life, we provide a comprehensive synthesis of data and observations on the beneficial role of impacts in a wide range of prebiotic and biological processes. In the context of previously proposed environments for the origin of life on Earth, we discuss how meteorite impacts can generate both subaerial and submarine hydrothermal vents, abundant hydrothermal-sedimentary settings, and impact analogues for volcanic pumice rafts and splash pools. Impact events can also deliver and/or generate many of the necessary chemical ingredients for life and catalytic substrates such as clays as well. The role that impact cratering plays in fracturing planetary crusts and its effects on deep subsurface habitats for life are also discussed. In summary, we propose that meteorite impact events are a fundamental geobiological process in planetary evolution that played an important role in the origin of life on Earth. We conclude with the recommendation that impact craters should be considered prime sites in the search for evidence of past life on Mars. Furthermore, unlike other geological processes such as volcanism or plate tectonics, impact cratering is ubiquitous on planetary bodies throughout the Universe and is independent of size, composition, and distance from the host star. Impact events thus provide a mechanism with the potential to generate habitable planets, moons, and asteroids throughout the Solar System and beyond.

Published

2020

47. Explaining the Variations in Isotopic Ratios in Meteoritic Amino Acids.

Author

Famiano MA, Boyd RN, Kajino T, Chiba S, Mo Y, Onaka T, and Suzuki T

Subjects

Amino Acids isolation & purification, Stereoisomerism, Amino Acids chemistry, Electrons, Evolution, Chemical, Extraterrestrial Environment chemistry, Meteoroids

Abstract

Measurements of the isotopic abundances in meteoritic amino acids have found enhancements of 2 H/H, 15 N/ 14 N, and 13 C/ 12 C in the amino acids in the meteorites studied. We show that they are consistent with the processing of the constituents of the meteorites by electron antineutrinos that would be expected from a core-collapse supernova or neutron-star merger. Using theoretical electron antineutrino cross-sections, we are able to predict these isotopic ratio variations depending on the time-integrated antineutrino flux at the site where the amino acids were processed.

Published

2020

48. Preservation of Biological Markers in Clasts Within Impact Melt Breccias from the Haughton Impact Structure, Devon Island

Author

John Parnell, Gordon R. Osinski, Paula Lindgren, Stephen A. Bowden, Colin Taylor, and Pascal Lee

Subjects

Maturity (geology), Canada, Hot Temperature, Arctic Regions, Fossils, Carbonates, Geochemistry, Mineralogy, Meteoroids, Impactite, Agricultural and Biological Sciences (miscellaneous), chemistry.chemical_compound, chemistry, Impact crater, Space and Planetary Science, Clastic rock, Breccia, Carbonate, Sedimentary rock, Impact structure, Biomarkers, Geology

Abstract

The 39 +/- 2 Ma Haughton impact structure on Devon Island comprises a thick target succession of sedimentary rocks, mainly carbonates. The carbonates contain pre-impact organic matter, including fossil biological markers. Haughton is located in an area where no major thermal event has affected the sedimentary succession after heating caused by impact. This makes Haughton uniquely suitable for studies concerning the preservation of fossil biological markers following an impact event. Melt breccia is the most common impactite at Haughton. It is composed of clasts of the target, mainly carbonates, embedded in a fine groundmass. The groundmass is composed of material that was melted during impact. In this study, fossil biological marker maturity parameters (tricyclic terpane-hopane ratio and pregnane-sterane ratio) and an aromatic maturity parameter [methylphenanthrene ratio (MPR)] were used to compare the degree of thermal alteration in different size fractions of carbonate clasts (

Published

2009

49. Effects of Meteorite Impacts on the Atmospheric Evolution of Mars

Author

Véronique Dehant, Lê Binh San Pham, and Özgür Karatekin

Subjects

Extraterrestrial Environment, Atmosphere, Earth, Planet, Surface Properties, Liquid water, Habitability, Mars, Meteoroids, Mars Exploration Program, Models, Theoretical, Atmospheric sciences, Agricultural and Biological Sciences (miscellaneous), Astrobiology, Atmospheric Pressure, Meteorite, Space and Planetary Science, Asteroid, Greenhouse gas, Environmental science, Evolution, Planetary

Abstract

Early in its history, Mars probably had a denser atmosphere with sufficient greenhouse gases to sustain the presence of stable liquid water at the surface. Impacts by asteroids and comets would have played a significant role in the evolution of the martian atmosphere, not only by causing atmospheric erosion but also by delivering material and volatiles to the planet. We investigate the atmospheric loss and the delivery of volatiles with an analytical model that takes into account the impact simulation results and the flux of impactors given in the literature. The atmospheric loss and the delivery of volatiles are calculated to obtain the atmospheric pressure evolution. Our results suggest that the impacts alone cannot satisfactorily explain the loss of significant atmospheric mass since the Late Noachian (approximately 3.7-4 Ga). A period with intense bombardment of meteorites could have increased the atmospheric loss; but to explain the loss of a speculative massive atmosphere in the Late Noachian, other factors of atmospheric erosion and replenishment also need to be taken into account.

Published

2009

50. On the Survivability and Detectability of Terrestrial Meteorites on the Moon

Author

K. Tsembelis, Jeremy Bailey, E. C. Baldwin, Ian A. Crawford, and Emma A. Taylor

Subjects

Extraterrestrial Environment, Meteorite, Space and Planetary Science, Planet, Exobiology, Survivability, Meteoroids, Mars Exploration Program, Moon, Early Earth, Agricultural and Biological Sciences (miscellaneous), Astrobiology

Abstract

Materials blasted into space from the surface of early Earth may preserve a unique record of our planet's early surface environment. Armstrong et al. (2002) pointed out that such materials, in the form of terrestrial meteorites, may exist on the Moon and be of considerable astrobiological interest if biomarkers from early Earth are preserved within them. Here, we report results obtained via the AUTODYN hydrocode to calculate the peak pressures within terrestrial meteorites on the lunar surface to assess their likelihood of surviving the impact. Our results confirm the order-of-magnitude estimates of Armstrong et al. (2002) that substantial survivability is to be expected, especially in the case of relatively low velocity (ca. 2.5 km/s) or oblique (or=45 degrees) impacts, or both. We outline possible mechanisms for locating such materials on the Moon and conclude that searching for them would be a scientifically valuable activity for future lunar exploration.

Published

2008