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Correlating Nitrile IR Frequencies to Local Electrostatics Quantifies Noncovalent Interactions of Peptides and Proteins

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dc.contributor.advisor Bagchi, Sayan
dc.contributor.author Deb, Pranab
dc.contributor.author Haldar, Tapas
dc.contributor.author Kashid, Somnath
dc.contributor.author Banerjee, Subhrashis
dc.contributor.author Chakrabarty, Suman
dc.contributor.author Bagchi, Sayan
dc.date.accessioned 2023-10-10T03:58:27Z
dc.date.available 2023-10-10T03:58:27Z
dc.date.issued 2016-04-26
dc.identifier.other https://doi.org/10.1021/acs.jpcb.6b02732
dc.identifier.uri https://hdl.handle.net/20.500.12252/6240
dc.description.abstract Noncovalent interactions, in particular the hydrogen bonds and nonspecific long-range electrostatic interactions are fundamental to biomolecular functions. A molecular understanding of the local electrostatic environment, consistently for both specific (hydrogen-bonding) and nonspecific electrostatic (local polarity) interactions, is essential for a detailed understanding of these processes. Vibrational Stark Effect (VSE) has proven to be an extremely useful method to measure the local electric field using infrared spectroscopy of carbonyl and nitrile based probes. The nitrile chemical group would be an ideal choice because of its absorption in an infrared spectral window transparent to biomolecules, ease of site-specific incorporation into proteins, and common occurrence as a substituent in various drug molecules. However, the inability of VSE to describe the dependence of IR frequency on electric field for hydrogen-bonded nitriles to date has severely limited nitrile’s utility to probe the noncovalent interactions. In this work, using infrared spectroscopy and atomistic molecular dynamics simulations, we have reported for the first time a linear correlation between nitrile frequencies and electric fields in a wide range of hydrogen-bonding environments that may bridge the existing gap between VSE and H-bonding interactions. We have demonstrated the robustness of this field-frequency correlation for both aromatic nitriles and sulfur-based nitriles in a wide range of molecules of varying size and compactness, including small molecules in complex solvation environments, an amino acid, disordered peptides, and structured proteins. This correlation, when coupled to VSE, can be used to quantify noncovalent interactions, specific or nonspecific, in a consistent manner. en
dc.format.extent 13 en
dc.language.iso en_US en
dc.publisher The Journal of Physical Chemistry B en
dc.subject Electric fields en
dc.subject solvents en
dc.subject peptides and proteins en
dc.title Correlating Nitrile IR Frequencies to Local Electrostatics Quantifies Noncovalent Interactions of Peptides and Proteins en
dc.type Article en
local.division.division Physical and Materials Chemistry Division en
dc.description.university -- en


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