Conformational behavior of phenylglycines and hydroxyphenylglycines and non-planarity of phenyl rings.

The non-proteinogenic amino acids — phenylglycine (PG) and hydroxyphenylglycine (HPG) are crucial components of certain peptidic natural products and are important for the preparation of various medicines. In this, study, the conformation of model dipeptides Ac-X-NHMe of PG, p-HPG and 3, 5-di-hydroxyphenylglycine (3, 5-DHPG) was studied both in R and S form by quantum mechanical (QM) and molecular dynamics approaches. On the energy scale, the conformational states of these molecules in both the R and S were found to be degenerate by QM studies, stabilized by non-covalent interactions like carbonyl--carbonyl interactions, carbonyl-lp··π (aromatic ring) interactions etc. These interactions disappeared/weakened due to interaction of water molecules with carbonyl groups of backbone in simulation and water was found to interact with the aromatic ring through Ow-H··π or Owlp··π interactions. The degeneracy of conformational states was lifted in favor of R-form of PG and DHPG and water molecules interactions with aromatic ring led to non-planarity of the aromatic ring. In simulation studies, irrespective of the starting geometry, the , values for the R form correspond to inverse b/inverse collagen region and for the S-form, the , values correspond to b/collagen region i.e., adopt single conformation. The obtained results were in conformity with the CD spectroscopic data on D-PG and D-p-HPG. The conformational behavior of the unusual amino acids might be of great help in designing of bioactive peptides/peptide based drugs to be realized in single conformation – an essential requirement.

Conformational study of N-methylated alanine peptides and design of Aẞ inhibitor.

N-Methylation increases the proteolytic stability of peptides and leads to improved pharmacological and increased nematicidal property against plant pathogens. In this study, the quantum mechanical and molecular dynamic simulation approaches were used to investigate conformational behavior of peptides containing only N-methylated alanine (NMeAla) residues and N-methylated alanine and alanine residues at alternate positions. The amide bond geometry was found to be trans and the poly NMeAla peptides were shown to populate in the helical structure without hydrogen bond with , values of ~ 0, 90˚ stabilized by carbonyl-carbonyl interactions. Molecular dynamic simulations in water/methanol revealed the formation of β-strand structure, irrespective of the starting geometry due to the interaction of solvent molecules with the carbonyl groups of peptide backbone. Analysis of simulation results as a function of time suggested that the opening of helical structure without hydrogen bond started from C-terminal. Conformational behavior of peptides containing N-MeAla and Ala was used to design Ab peptide inhibitor and the model tetrapeptide Ac-Ala-NMeAla-Ala-NHMe in the β-strand structure was shown to interact with the hydrophobic stretch of Aβ15-42 peptide.