Glycine Peptide Bond Formation Catalyzed by Faujasite

The catalysis of peptide bond formation between two glycine molecules on H‐FAU zeolite was computationally studied by the M08‐HX density functional. Two reaction pathways, the concerted and the stepwise mechanism, starting from three differently adsorbed reactants, amino‐bound, carboxyl‐bound, and hydroxyl‐bound, are studied. Adsorption energies, activation energies, and reaction energies, as well as the corresponding intrinsic rate constants were calculated. A comparison of the computed energetics of the various reaction paths for glycine indicates that the catalyzed reaction proceeds preferentially via the concerted reaction mechanism of the hydroxyl‐bound configuration. This involves an eight‐membered ring of the transition structure instead of the four‐membered ring of the others. The step from the amino‐bound configuration to glycylglycine is the rate‐determining step of the concerted mechanism. It has an estimated activation energy of 51.2 kcal mol^?1. Although the catalytic reaction can also occur via the stepwise reaction mechanism, this path is not favored.