A Solvatochromic Model Calibrates Nitriles’ Vibrational Frequencies to Electrostatic Fields

Bagchi, Sayan; Fried, Stephen D.; Boxer, Steven G.

doi:10.1021/ja303895k

Cited by 115 publications

(221 citation statements)

References 29 publications

(110 reference statements)

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“…[21][22][23][24][25][26][27][28] The CN and N 3 probes have the advantage of being strong chromophores; however, unlike CÀD labels, CN and N 3 substituents are extrinsic probes that may introduce interactions that are not present in the native protein, and sensitivity to these artificial interactions may desensitize them to their native protein environment. Indeed, previous studies have indicated that both probes are predominantly sensitive to hydrogen bonding, [5,[29][30][31][32][33][34] interactions introduced by the probes themselves. Moreover, as extrinsic probes they might perturb the protein, a possibility exacerbated by the size of the N 3 group and by the H-bonding propensity of both CN and N 3 groups.…”

mentioning

confidence: 99%

IR Probes of Protein Microenvironments: Utility and Potential for Perturbation

Adhikary¹,

Zimmermann²,

Dawson³

et al. 2014

ChemPhysChem

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A variety of IR-active moieties with absorptions that are distinct from those of proteins have been developed as probes of local protein environments, including carbon-deuterium bonds (CD), cyano groups (CN), and azides (N3 ); however, no systematic analysis of their utility in a protein has been published. Previously, we characterized the N-terminal Src homology 3 domain of the murine adapter protein Crk-II (nSH3) with CD bonds site-selectively incorporated throughout, and showed that it is relatively rigid and electrostatically heterogeneous and that it thermally unfolds under equilibrium conditions via a simple two-state mechanism. We now report the synthesis and characterization of eight variants of nSH3 with CN and/or N3 probes at five of the same positions. In agreement with previous studies, the position-dependent spectra suggest that both probes are predominantly sensitive to hydration, and not to their local electrostatic environments. Importantly, both probes also tend to significantly perturb the protein if they are not incorporated at surface-exposed positions. Thus, unlike CD labels, which are both sensitive to their environment and non-perturbative, CN and N3 probes should be used with caution.

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mentioning

confidence: 99%

IR Probes of Protein Microenvironments: Utility and Potential for Perturbation

Adhikary¹,

Zimmermann²,

Dawson³

et al. 2014

ChemPhysChem

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“…9 The results herein suggest that these effects are readily accommodated by augmenting experimental spectroscopy with electronic structure calculations, thereby affording a means to rationalize any deviation from purely electrostatic contributions. Coupled with Kubo-Anderson lineshape analysis this tool becomes even more versatile, facilitating exploration of the vibrational probe's solvation shell.…”

Section: Discussionmentioning

confidence: 86%

“…Thus, while the calculated shifts are not identical to the experimental shifts, the use of reference data establish a correlation can provide a quantitative conversion factor. While prior studies avoided hydrogen bonding solvents due to difficulties in interpretation, 9 these concerns may be mitigated when theoretical calculations are used to augment experimental investigations. As a final note, the scatter and deviation from a linear dependence of the solvatochromic shift on the Onsager reaction field may be attributed, in part, to the crude nature of the Onsager approximation.…”

Section: A Solvatochromic Shiftsmentioning

confidence: 99%

“…In fact, other nitrile and nitrile-free probes including alcohols, azides, fluorides, nitrosyl, and carbonyl compounds have been investigated both experimentally 2,4,19,20 and theoretically. [21][22][23][24][25] Furthermore, the aforementioned studies have all utilized the Stark effect, with a few notable exceptions 9,10 in which the nitrile solvatochromic shift was calibrated against a standard series of solvents. The latter approach is ideal as it drastically simplifies the measurement technique and permits observations over a broad range of physiologically relevant conditions.…”

Section: Introductionmentioning

confidence: 99%

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Solvatochromism and the solvation structure of benzophenone

Elenewski

Hackett

2013

The Journal of Chemical Physics

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Many complex molecular phenomena, including macromolecular association, protein folding, and chemical reactivity, are determined by the nuances of their electrostatic landscapes. The measurement of such electrostatic effects is nonetheless difficult, and is typically accomplished by exploiting a spectroscopic probe within the system of interest, such as through the vibrational Stark effect. Raman spectroscopy and solvatochromism afford an alternative to this method, circumventing the limitations of infrared spectroscopy, providing a lower detection limit, and permitting measurement in a native chemical environment. To explore this possibility, the solvatochromism of the C=O and aromatic C-H stretching modes of benzophenone are investigated using Raman spectroscopy. In conjunction with density functional theory calculations, these observations are sufficient to determine the probe electrostatic environment as well as contributions from halogen and hydrogen bonding. Further analysis using a detailed Kubo-Anderson lineshape model permits the detailed assignment of distinct hydrogen bonding configurations for water in the benzophenone solvation shell. These observations reinforce the use of benzophenone as an effective electrostatic probe for complex chemical systems.

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“…Previously used nitrile probes for proteins include CN-labelled phenylalanine 289–291 and the nitrile-containing IDD type inhibitor for human aldose reductase 278,292 . Benzonitrile (PhCN) is another potentially useful probe to determine the local electrostatic environment as it fulfills three important criteria: the -CN stretching mode at

\approx 2200

cm – 1 (a) absorbs in a frequency range (i.e., between 1800 cm – 1 and 2800 cm – 1 ) in which proteins containing only naturally occurring amino acids have no vibrational spectral response (except for the -SH group in cysteine), (b) is to a good approximation a local mode (i.e., uncoupled from other framework modes), and (c) the dipole moment of PhCN is to a large extent that of the nitrile group itself.…”

Section: Applicationsmentioning

confidence: 99%

Ultrafast dynamics induced by the interaction of molecules with electromagnetic fields: Several quantum, semiclassical, and classical approaches

Antipov

Bhattacharyya

Hage

et al. 2017

Structural Dynamics

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Several strategies for simulating the ultrafast dynamics of molecules induced by interactions with electromagnetic fields are presented. After a brief overview of the theory of molecule-field interaction, we present several representative examples of quantum, semiclassical, and classical approaches to describe the ultrafast molecular dynamics, including the multiconfiguration time-dependent Hartree method, Bohmian dynamics, local control theory, semiclassical thawed Gaussian approximation, phase averaging, dephasing representation, molecular mechanics with proton transfer, and multipolar force fields. In addition to the general overview, some focus is given to the description of nuclear quantum effects and to the direct dynamics, in which the ab initio energies and forces acting on the nuclei are evaluated on the fly. Several practical applications, performed within the framework of the Swiss National Center of Competence in Research “Molecular Ultrafast Science and Technology,” are presented: These include Bohmian dynamics description of the collision of H with H2, local control theory applied to the photoinduced ultrafast intramolecular proton transfer, semiclassical evaluation of vibrationally resolved electronic absorption, emission, photoelectron, and time-resolved stimulated emission spectra, infrared spectroscopy of H-bonding systems, and multipolar force fields applications in the condensed phase.

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A Solvatochromic Model Calibrates Nitriles’ Vibrational Frequencies to Electrostatic Fields

Cited by 115 publications

References 29 publications

IR Probes of Protein Microenvironments: Utility and Potential for Perturbation

IR Probes of Protein Microenvironments: Utility and Potential for Perturbation

Solvatochromism and the solvation structure of benzophenone

Ultrafast dynamics induced by the interaction of molecules with electromagnetic fields: Several quantum, semiclassical, and classical approaches

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