Perturbation of peptide conformations induced in anisotropic environments

Although noted as hydrophilic residues with helix-breaking potential, proline residues are observed in putatively a-helical transmembrane (TM) segments of many channel-forming integral membrane proteins. In addition to the recognized property of X-Pro peptide bonds (where X = any amino acid) to occu

The crystal structure of the model tripeptide Boc-Aib-Gly-Leu-OMe (1) reveals two independent molecules in the asymmetric unit that adopt ''enantiomeric'' type I and type I b-turn conformations with the Aib and Gly residues occupying the corner (i / 1 and i / 2) positions. 13 C cross polarization an

and Kates119] based on the deuterium isotopic perturbation effect. An additional factor that supports this conclusion can be found by analyzing further the CH stretching region. In the hypothetical classical 2-norbornyl cation, the hyperconjugative interaction of the C ( 3 j H bonds with the formall

Transmembrane segments (TM) are important structural elements that often define the functional domain of membrane proteins.'.2 Structural studies of TM segments are thus becoming essential for understanding the structure/ function of membrane proteins, although their physical properties have often c

Enzymes bind NAD in extended conformations and yet NAD exists in aqueous solution as a compact, folded molecule. Thus, NAD conformation is environment dependent. In an attempt to investigate the effects of environmental changes on the conformation of NAD , a series of molecular dynamics simulations

Solid state nuclear magnetic resonance has the potential to characterize membrane protein structures at very high resolution. This paper focuses on the use of orientational constraints for this purpose. These constraints are based on observing the orientation dependence of nuclear spin interactions.