First principle computational study on the full conformational space of L-proline diamides |
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Authors: | Sahai Michelle A Kehoe Tara A K Koo Joseph C P Setiadi David H Chass Gregory A Viskolcz Bela Penke Botond Pai Emil F Csizmadia Imre G |
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Institution: | Department of Medical Biophysics, University of Toronto, Ontario Cancer Institute, Princess Margaret Hospital, 610 University Avenue, Toronto, Ontario, Canada M5G 2M9. michelle.sahai@utoronto.ca |
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Abstract: | Ab initio molecular orbital computations were carried out at three levels of theory: RHF/3-21G, RHF/6-31G(d), and B3LYP/6-31G(d), on four model systems of the amino acid proline, HCO-Pro-NH2 I], HCO-Pro-NH-Me II], MeCO-Pro-NH2 III], and MeCO-Pro-NH-Me IV], representing a systematic variation in the protecting N- and C-terminal groups. Three previously located backbone conformations, gammaL, epsilonL, and alphaL, were characterized together with two ring-puckered forms syn (gauche+ = g+) or "DOWN" and anti (gauche- = g-) or "UP", as well as trans-trans, trans-cis, cis-trans, and cis-cis peptide bond isomers. The topologies of the conformational potential energy cross-sections (PECS) of the potential energy hypersurfaces (PEHS) for compounds I]-IV] were explored and analyzed in terms of potential energy curves (PEC), and HCO-Pro-NH2 I] was also analyzed in terms of potential energy surfaces (PESs). Thermodynamic functions were also calculated for HCO-Pro-NH2 I] at the CBS-4M and G3MP2 levels of theory. The study confirms that the use of the simplest model, compound I] with P(N) = P(C) = H, along with the RHF/3-21G level of theory, is an acceptable practice for the analysis of peptide models because only minor differences in geometry and stability are observed. |
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