Condensation of vaporous amino acids in the presence of silica. Formation of bi- and tricyclic amidines

Basiuk, Vladimir A.

doi:10.1007/bf01809370

Cited by 16 publications

(11 citation statements)

References 14 publications

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“…They demonstrated the catalytic ability of silica and alumina surfaces to convert amino acid vapors (in vacuum and temperatures above 200~ into oligopeptides, cyclic anhydrides [12,13] and other reaction products [14]. The "vacuum environments" do not reflect the assumed prebiotic conditions and amino acid decomposition would precede their sublimation under normal air pressure.…”

Section: Introductionmentioning

confidence: 98%

Glycine oligomerization on silica and alumina

Bujdák

Rode

1997

React Kinet Catal Lett

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Oligomerization of glycine (gly) and diglycine (gly2) on silica and alumina was observed in experiments simulating wetting-drying cycles at 80~ Glycine produces less than 1% total yield of gly 2 and diketopiperazine (DKP) after one week. In experiments starting from gly2, more than 10% DKP is formed. Formation~ of higher oligomers (gly3-gly6) proceeded as well, with 3.8% and 5. l% total yields on silica and alumina surfaces respectively.

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Section: Introductionmentioning

confidence: 98%

Glycine oligomerization on silica and alumina

Bujdák

Rode

1997

React Kinet Catal Lett

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“…Clay minerals promote the polymerization of activated amino acid adenylates (PaechtHorowitz 1977(PaechtHorowitz , 1978Paecht-Horowitz and Eirich 1988;Paecht-Horowitz and Lahav 1977;Paecht-Horowitz et al 1970). At temperatures above the boiling point of water, polymerization of amino acids on silica or alumina was also observed without activation (Rohlfing and McAlhaney 1976;Basiuk et al 1990Basiuk et al , 1991Basiuk et al , 1992Gromovoy et al 1991;Basiuk 1992;Basiuk and Gromovoy 1994).…”

Section: Introductionmentioning

confidence: 99%

Silica, Alumina, and Clay-Catalyzed Alanine Peptide Bond Formation

Bujdák

Rode

1997

J Mol Evol

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The peptide bond formation of alanine (ala), ala + glycine (gly), ala + diglycine (gly 2 ), and ala + gly cyclic anhydride (cyc-gly 2 ) in drying/wetting cycles at 80°C was studied. Silica, alumina, and representative smectites-montmorillonite and hectorite-were used as catalysts, and the dependence of reaction yields on the available amount of water in the reaction systems was evaluated. Silica and alumina catalyze the formation of oligopeptide mainly in temperature fluctuation experiments, whereas higher amounts of water in the reaction system support clay-catalyzed reactions. Silica and alumina are much more efficient for amino acid dimerization than clays. Whereas only 0.1% of ala oligomerized on hectorite and no reaction proceeded on montmorillonite, about 0.9 and 3.8% alanine converted into its dimer and cyclic anhydride on silica and alumina, respectively. Clay minerals, on the other hand, seem to more efficiently catalyze peptide chain elongation than amino acid dimerization. The reaction yields of ala-gly-gly and glygly-ala from ala + gly 2 and ala + cyc-gly 2 reached about 0.3% on montmorillonite and 1.0% on hectorite. The possible mechanisms of these reactions and the relevance of the results for prebiotic chemistry are discussed.

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“…The linkage can be formed by the condensation of the COOH group of the amino acid and the SiOH group of the surface releasing one water molecule. According to our previous results, this process is favorable under anhydrous conditions and elevated temperatures. , The ester-type linkage can be identified in IR spectra due to the ν C  O band at 1750−1760 cm -1 . ,, For several decades, it was believed to be an “activated intermediate” in the silica-catalyzed intermolecular condensation of amino acids. − ,− , On the other hand, recent quantum chemical calculations by Ugliengo's group 39 did not confirm the enhanced reactivity of this linkage. We hoped to provide an additional insight for our particular type of surface reactions.…”

Section: Resultsmentioning

confidence: 96%

“…For example, due to the abundance of metal cations (e.g., Na, Ca, Al, and Fe) in clays and seawater, the salt-induced peptide formation reaction was suggested to be the simplest and most universal mechanism to produce peptides from amino acid building blocks . Nevertheless, most studies in this area − focus on the role of catalytically active inorganic oxide surfaces. In turn, pure cation-free silica and alumina became the most commonly used models of clays and other complex minerals, where the role of surface silicon and aluminum atoms in the process of amino acids activation became another specific problem.…”

Section: Introductionmentioning

confidence: 99%

Imidazo[1,2-a]pyrazine-3,6-diones Derived from α-Amino Acids: A Theoretical Mechanistic Study of Their Formation via Pyrolysis and Silica-Catalyzed Process

Contreras‐Torres

Basiuk

2006

J. Phys. Chem. A

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Imidazo[1,2-a]pyrazine-3,6-diones are unusual compounds composed of three alpha-amino acid fragments. These bicyclic amidines (BCAs) form under high temperatures or with the use of strong dehydrating reagents. We gave insight into the mechanisms of BCA formation via gas-phase pyrolytic and silica-catalyzed reactions of glycine (Gly) and alpha-aminoisobutyric acid (AIB) with related diketopiperazines (DKPs), using quantum chemical calculations. The entire process requires four steps: (1) O-acylation of DKP with free or silica-bonded amino acid, (2) acyl transfer from the oxygen to the nitrogen atom, (3) intramolecular condensation of the N-acyl DKP into a cyclol, and (4) elimination of water. To study step (1) at silica surface (modeled by H7Si8O12-OH cluster), we employed two-level ONIOM calculations (AM1:UFF, B3LYP/3-21G:UFF and B3LYP/6-31G(d):UFF); all gas-phase reactions were studied at the AM1, B3LYP/3-21G and B3LYP/6-31G(d) levels. The catalytic effect of silica was observed for both Gly and AIB: the activation energy in the O-acylation at the surface was lower by more than 9 kcal mol(-1) as compared to the gas-phase process. Contrary to the exothermic O-acylation, the gas-phase transfer reaction (step 2) was exothermic in both cases, but more favorable for Gly. The cyclocondensation of N-acylated DKPs into BCAs (steps 3 and 4) is endothermic for Gly and exothermic for AIB.

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Condensation of vaporous amino acids in the presence of silica. Formation of bi- and tricyclic amidines

Cited by 16 publications

References 14 publications

Glycine oligomerization on silica and alumina

Glycine oligomerization on silica and alumina

Silica, Alumina, and Clay-Catalyzed Alanine Peptide Bond Formation

Imidazo[1,2-a]pyrazine-3,6-diones Derived from α-Amino Acids: A Theoretical Mechanistic Study of Their Formation via Pyrolysis and Silica-Catalyzed Process

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