TY - JOUR
T1 - The transformation by catalysis of prebiotic chemical systems to useful biochemicals
T2 - A perspective based on IR spectroscopy of the primary chemicals: I. the synthesis of peptides by the condensation of amino acids
AU - Larsson, Ragnar
AU - Malek, Abdul
AU - Odenbrand, Ingemar
PY - 2020/1/31
Y1 - 2020/1/31
N2 - It is now widely speculated that life originated at the "Black Smokers" of the undersea hydrothermal vents, where conditions exist for the formation of the primary ingredients and their subsequent transformation to higher biotic species such as amino acids, alcohols, etc. Any possible routes for the prebiotic oligomerization of simple compounds like amino acids, necessary for cell formation, has so far not been well understood. However, Leman et al. recently reported that under standard laboratory conditions carbonyl sulfide (COS) can "mediate" the oligomerization of simple amino acids in moderate yield. COS being a well-known volcanic gas points to its possible role in prebiotic peptide formation in the environment of the hydrothermal vents. Based on a previously developed and tested model for selective (vibrational) energy transfer (SET), we show that a COS-catalyzed condensation of ff-amino-acids can lead to the formation of polypeptides. We also indicate that other agents can act as catalysts of the amino acid condensation, such as Fe(CN)6 3- and cyanamide (H2N-CN). This is related to the existence of vibrations with a frequency near to that of the critical vibration of the reactant, ρw (NH2). This wagging vibration occurs at 1048 ± 10 cm-1 (the mean value of Cu and Ni complexes) and, as the vibration of the presumed catalyst lies at 2079 cm-1, one notes that one quantum of the catalyst equals two quanta of the NH2 wagging: 2079/2 × 1048 = 0.9919. This is a good indication of a resonance.
AB - It is now widely speculated that life originated at the "Black Smokers" of the undersea hydrothermal vents, where conditions exist for the formation of the primary ingredients and their subsequent transformation to higher biotic species such as amino acids, alcohols, etc. Any possible routes for the prebiotic oligomerization of simple compounds like amino acids, necessary for cell formation, has so far not been well understood. However, Leman et al. recently reported that under standard laboratory conditions carbonyl sulfide (COS) can "mediate" the oligomerization of simple amino acids in moderate yield. COS being a well-known volcanic gas points to its possible role in prebiotic peptide formation in the environment of the hydrothermal vents. Based on a previously developed and tested model for selective (vibrational) energy transfer (SET), we show that a COS-catalyzed condensation of ff-amino-acids can lead to the formation of polypeptides. We also indicate that other agents can act as catalysts of the amino acid condensation, such as Fe(CN)6 3- and cyanamide (H2N-CN). This is related to the existence of vibrations with a frequency near to that of the critical vibration of the reactant, ρw (NH2). This wagging vibration occurs at 1048 ± 10 cm-1 (the mean value of Cu and Ni complexes) and, as the vibration of the presumed catalyst lies at 2079 cm-1, one notes that one quantum of the catalyst equals two quanta of the NH2 wagging: 2079/2 × 1048 = 0.9919. This is a good indication of a resonance.
KW - Amino acids
KW - Catalysis
KW - Polypeptides
KW - Prebiotic reactions
KW - Reorganization of orbital patterns (sp3 to sp2)
KW - Selective energy transfer (SET)
KW - Vibrational resonance
U2 - 10.3390/app10030928
DO - 10.3390/app10030928
M3 - Article
AN - SCOPUS:85081611181
SN - 2076-3417
VL - 10
JO - Applied Sciences (Switzerland)
JF - Applied Sciences (Switzerland)
IS - 3
M1 - 928
ER -