Abstract
Clay-catalyzed glycine and diglycine oligomerizations were performed as drying/wetting cycles at 80°C. Two trioctahedral smectites (hectorite and saponite), three pure montmorillonites, a ferruginous smectite, an Fe(II)-rich smectite, and three smectites containing goethite admixture were used as catalysts. Highest peptide bond formation was found with trioctahedral smectites. About 7% of glycine was converted to diglycine and diketopiperazine on hectorite after 7 days. In the case of dioctahedral smectites, highest yields were achieved using clays with a negative-layer charge localized in the octahedral sheets (up to 2% of converted glycine after 7 days). The presence of Fe(II) in clay is reflected in a higher efficiency in catalyzing amino acid dimerization (about 3.5% of converted glycine after 7 days). The possible significance of the results for prebiotic chemistry is discussed.
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Bujdák, J., Rode, B.M. The effect of smectite composition on the catalysis of peptide bond formation. J Mol Evol 43, 326–333 (1996). https://doi.org/10.1007/BF02339007
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DOI: https://doi.org/10.1007/BF02339007