Biology:Hemoglycin
| Hemoglycin | ||
|---|---|---|
| (Glycine-containing space polymer of amino acids found in meteorites) | ||
 Hemoglycin was found in Acfer 086, an Allende meteorite similar to that pictured. | ||
| Function | unknown, although possibly able to split water to hydroxyl and hydrogen moieties[1] | |
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Hemoglycin (previously termed hemolithin) is a space polymer that is the first polymer of amino acids found in meteorites.[2][3][4]
Structure
Structural work has determined that its 1494 Dalton core unit (Glycine18 / Hydroxy-glycine4 / Fe2O4) contains iron, but not lithium, leading to the more general term hemoglycin for these molecules [1][5] The hemoglycin core contains a total of 22 glycine residues in an anti-parallel beta sheet chain that is terminated at each end by an iron atom plus two oxygens. Four of these glycine residues are oxidized to hydroxy-glycine with hydroxy groups (-OH) on the alpha carbon. This structure was determined by mass spectrometry of meteoritic solvent extracts[1][2][5] and has been confirmed in X-ray scattering by crystals of hemoglycin,[6] and also by optical absorption.[3] Crystals show a 480 nm characteristic absorption that can only exist when hydroxy-glycine residues have “R” chirality and are C-terminal bonded to iron.[6]
History
Because hemoglycin has now been found to be the dominant polymer of amino acids in 6 different meteorites (Allende,[7] Acfer 086, Efremovka, Kaba, Orgueil and Sutter's Mill), each time with the same structure, it has been proposed[3][6] that it is produced by a process of template replication. The measured 480 nm absorbance is larger than expected for a racemic distribution of R and S chirality in the hydroxy-glycine residues, indicating an R chirality excess in the polymer. Modeling of template replication that is assumed to depend on 480 nm absorption leads to an excess of R chirality and thus is consistent with this finding.
Significance
Hemoglycin is a completely abiotic molecule that forms in molecular clouds going on to protoplanetary disks, way before biochemistry on exoplanets like Earth begins. Hemoglycin via its glycine could seed an exoplanet (one able to support early biochemistry) but its main function appears to be the accretion of matter via formation of an extensive low-density lattice[6] in space in a protoplanetary disk. Besides being present in carbonaceous meteorites, hemoglycin has also been extracted and crystallized from a fossil stromatolite that formed on Earth 2.1 billion years ago.[citation needed] Potentially this fossil hemoglycin was delivered during the Late Heavy Bombardment (LHB) to Earth. Data to support this being the hemoglycin in the fossil has extraterrestrial isotopes similar to that in meteorites.
The polymer on the precambrian Earth could have functioned to drive the Great Oxygenation Event (GOE) beginning 2.4 Gya by splitting water in response to ultraviolet irradiation. Also, it could provide an energy source to early biochemistry and/or it simply delivered a source of polymer glycine.
See also
- Ancient protein
- Bubble
- Earliest known life forms
- Evolutionary history of life
- Extraterrestrial: The First Sign of Intelligent Life Beyond Earth
- List of interstellar and circumstellar molecules
- Panspermia
- Protein
References
- ↑ 1.0 1.1 1.2 McGeoch, Malcolm. W.; Dikler, Sergei; McGeoch, Julie E. M. (22 February 2020). "Hemolithin: a Meteoritic Protein containing Iron and Lithium". arXiv:2002.11688 [astro-ph.EP].
- ↑ 2.0 2.1 McGeoch, J.E.M.; McGeoch, M.W. (2015). "Polymer amide in the Allende and Murchison meteorites.". Meteoritics & Planetary Science 50 (12): 1971–1983. doi:10.1111/maps.12558. Bibcode: 2015M&PS...50.1971M.
- ↑ 3.0 3.1 3.2 McGeogh, Julie E. M.; McGeogh, Malcolm W. (28 September 2022). "Chiral 480nm absorption in the hemoglycin space polymer: a possible link to replication". Scientific Reports 12 (1): 16198. doi:10.1038/s41598-022-21043-4. PMID 36171277.
- ↑ Staff (29 June 2021). "Polymers in meteorites provide clues to early solar system". Science Digest. https://www.sciencedaily.com/releases/2021/06/210629120835.htm. Retrieved 9 January 2023.
- ↑ 5.0 5.1 McGeoch, M. W.; Dikler, S.; McGeoch, J.E.M. (21 February 2021). "Meteoritic Proteins with Glycine, Iron and Lithium". arXiv:2102.10700 [physics.chem-ph].
- ↑ 6.0 6.1 6.2 6.3 McGeoch, Julie E. M.; McGeoch, Malcolm W. (29 June 2021). "Structural Organization of Space Polymers". Physics of Fluids 33 (6). doi:10.1063/5.0053302.
- ↑ Jujeczko, Pawel (2022). "Lessons learned from the examinations of Allende meteorite". Acta Societatis Metheoriticae Polonorium 13: 37–46. http://psjd.icm.edu.pl/psjd/element/bwmeta1.element.psjd-fba8e9c5-7d12-444b-831b-c720769fcfc8/c/ASMP-Roczniki-vol13-Jujeczko1.pdf. Retrieved 10 January 2023.
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