José C Aponte1,2, Jamie E Elsila2, Jason E Hein3, Jason P Dworkin2, Daniel P Glavin2, Hannah L McLain1,2, Eric T Parker2, Timothy Cao4, Eve L Berger5, Aaron S Burton6. 1. Department of Chemistry Catholic University of America Washington District of Columbia 20064 USA. 2. Solar System Exploration Division NASA Goddard Space Flight Center Greenbelt Maryland 20771 USA. 3. University of British Columbia British Columbia V6T 1Z2 Canada. 4. Department of Chemistry University of California Merced California 95343 USA. 5. Astromaterials Research and Exploration Science Division Texas State University / Jacobs JETS Contract NASA Johnson Space Center Houston Texas 77058 USA. 6. Astromaterials Research and Exploration Science Division NASA Johnson Space Center Houston Texas 77058 USA.
Abstract
The abundances, relative distributions, and enantiomeric and isotopic compositions of amines, amino acids, and hydroxy acids in Miller Range (MIL) 090001 and MIL 090657 meteorites were determined. Chiral distributions and isotopic compositions confirmed that most of the compounds detected were indigenous to the meteorites and not the result of terrestrial contamination. Combined with data in the literature, suites of these compounds have now been analyzed in a set of six CR chondrites, spanning aqueous alteration types 2.0-2.8. Amino acid abundances ranged from 17 to 3300 nmol g-1 across the six CRs; hydroxy acid abundances ranged from 180 to 1800 nmol g-1; and amine abundances ranged from 40 to 2100 nmol g-1. For amino acids and amines, the weakly altered chondrites contained the highest abundances, whereas hydroxy acids were most abundant in the more altered CR2.0 chondrite. Because water contents in the meteorites are orders of magnitude greater than soluble organics, synthesis of hydroxy acids, which requires water, may be less affected by aqueous alteration than amines and amino acids that require nitrogen-bearing precursors. Two chiral amino acids that were plausibly extraterrestrial in origin were present with slight enantiomeric excesses: L-isovaline (~10% excess) and D-β-amino-n-butyric acid (~9% excess); further studies are needed to verify that the chiral excess in the latter compound is truly extraterrestrial in origin. The isotopic compositions of compounds reported here did not reveal definitive links between the different compound classes such as common synthetic precursors, but will provide a framework for further future in-depth analyses.
The abundances, relative distributions, and enantiomeric and isotopic compositions of amines, amino acids, and n class="Chemical">hydroxy acids in Miller Range (MIL) 090001 and MIL 090657 meteorites were determined. Chiral distributions and isotopic compositions confirmed that most of the compounds detected were indigenous to the meteorites and not the result of terrestrial contamination. Combined with data in the literature, suites of these compounds have now been analyzed in a set of six CR chondrites, spanning aqueous alteration types 2.0-2.8. Amino acid abundances ranged from 17 to 3300 nmol g-1 across the six CRs; hydroxy acid abundances ranged from 180 to 1800 nmol g-1; and amine abundances ranged from 40 to 2100 nmol g-1. For amino acids and amines, the weakly altered chondrites contained the highest abundances, whereas hydroxy acids were most abundant in the more altered CR2.0 chondrite. Because water contents in the meteorites are orders of magnitude greater than soluble organics, synthesis of hydroxy acids, which requires water, may be less affected by aqueous alteration than amines and amino acids that require nitrogen-bearing precursors. Two chiral amino acids that were plausibly extraterrestrial in origin were present with slight enantiomeric excesses: L-isovaline (~10% excess) and D-β-amino-n-butyric acid (~9% excess); further studies are needed to verify that the chiral excess in the latter compound is truly extraterrestrial in origin. The isotopic compositions of compounds reported here did not reveal definitive links between the different compound classes such as common synthetic precursors, but will provide a framework for further future in-depth analyses.
Authors: Christopher Mayer-Bacon; Markus Meringer; Riley Havel; José C Aponte; Stephen Freeland Journal: J Mol Evol Date: 2022-06-06 Impact factor: 3.973
Authors: Katharina Kaiser; Fabian Schulz; Julien F Maillard; Felix Hermann; Iago Pozo; Diego Peña; H James Cleaves; Aaron S Burton; Gregoire Danger; Carlos Afonso; Scott Sandford; Leo Gross Journal: Meteorit Planet Sci Date: 2022-02-01 Impact factor: 2.890