Raghu Nath Behera scite author profile

Aligned alpha helix peptide dipoles sum to a "macroscopic" dipole parallel to the helix axis that has been implicated in protein folding and function. However, in aqueous solution the dipole is counteracted by an electrostatic reaction field generated by the solvent, and the strength of the helix dipole may reduce drastically from its value in vacuum. Here, using atomic-detail helix models and Poisson-Boltzmann continuum electrostatics calculations, the net effective dipole moment, mu(eff), is calculated. Some initially surprising results are found. Whereas in vacuum mu(eff) increases with helix length, the opposite is found to be the case for transmembrane helices. In soluble proteins, mu(eff) is found to vary strongly with the orientation and position of the helix relative to the aqueous medium. A set of rules is established to estimate of the strength of mu(eff) from graphical inspection of protein structures.

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Comparative study of E⋯N (E=Se/Te) intramolecular interactions in organochalcogen compounds using density functional theory

Panda

Behera

2014

Journal of Hazardous Materials

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Effect of chelate ring and rigidity on Se⋯N interactions: a computational study

Behera

Panda

2012

RSC Adv.

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Nature of the Te⋯N intramolecular interaction in organotellurium compounds. A theoretical investigation by NBO and AIM methods

Behera

Panda

2012

Computational and Theoretical Chemistry

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Synthesis, characterization, and computational study of potential itaconimide-based initiators for atom transfer radical polymerization

et al. 2014

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