2013
DOI: 10.1021/ja403917z
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Measuring Electrostatic Fields in Both Hydrogen-Bonding and Non-Hydrogen-Bonding Environments Using Carbonyl Vibrational Probes

Abstract: Vibrational probes can provide a direct read-out of the local electrostatic field in complex molecular environments, such as protein binding sites and enzyme active sites. This information provides an experimental method to explore the underlying physical causes of important biomolecular processes such as binding and catalysis. However, specific chemical interactions such as hydrogen bonds can have complicated effects on vibrational probes and confound simple electrostatic interpretations of their frequency sh… Show more

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Cited by 192 publications
(408 citation statements)
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“…Thus, in contrast to Ref. 30, we find no evidence for H-bonding with chloroform from the present MD runs. The H-bonding in water can explain why the variation in C==O frequency is much larger in water than in the other solvents.…”
Section: B Solute-solvent Configurationscontrasting
confidence: 99%
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“…Thus, in contrast to Ref. 30, we find no evidence for H-bonding with chloroform from the present MD runs. The H-bonding in water can explain why the variation in C==O frequency is much larger in water than in the other solvents.…”
Section: B Solute-solvent Configurationscontrasting
confidence: 99%
“…Acetophenone is a model compound for the unnatural amino acid p-acetylphenylalanine, which can be site-specifically introduced into proteins by several methods. 29 The carbonyl probe has attracted increasing attention due to the observations that (i) it has a rather large oscillator strength and Stark tuning rate, 30 (ii) its frequency varies linearly with the field also for hydrogen bonding solvents, as opposed to nitrile vibrations, 31 thus making it applicable across both hydrogen and non-hydrogen bonding environments, and (iii) its experimental use in proteins has been demonstrated by overcoming the complication related to the C==O spectral overlap with the intrinsic amide I vibration of the peptide bonds 32 by a suitable choice of reference sample. 30,33 Here, we perform classical MD simulations of the acetophenone-solvent systems, and the PE-DFT model is used to compute the C==O vibrational frequency as well as the corresponding local electric field sensed by acetophenone in the geometrically frozen solvent cages for each MD configuration.…”
Section: Introductionmentioning
confidence: 99%
“…For example, upon changing the solvent from hexane to DMSO, the center frequency of MA is red-shifted by 18.1 cm -1 , compared to the 14.4 cm -1 shift observed for p-Ac-Phe. [7] Thus, these results substantiate the utility of these ester carbonyl stretching vibrations as sensitive probes of the local electric field, provided that a quantitative relationship between the electric field and frequency can be determined.Interestingly, while in aprotic solvents the ester carbonyl stretching vibration results in a single absorption band, in protic solvents, where H-bonding between the vibrator and solvent is possible, the linear IR spectra contain more than one resolvable feature, suggesting that differently solvated or H-bonded species are present. Such spectral features have also been observed for nitrile and amide modes in protic solvents such as methanol.…”
supporting
confidence: 63%
“…For example, upon changing the solvent from hexane to DMSO, the center frequency of MA is red-shifted by 18.1 cm -1 , compared to the 14.4 cm -1 shift observed for p-Ac-Phe. [7] Thus, these results substantiate the utility of these ester carbonyl stretching vibrations as sensitive probes of the local electric field, provided that a quantitative relationship between the electric field and frequency can be determined.…”
supporting
confidence: 63%
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