Vibrational Probes: From Small Molecule Solvatochromism Theory and Experiments to Applications in Complex Systems.

The vibrational frequency of a chosen normal mode is one of the most accurately measurable spectroscopic properties of molecules in condensed phases. Accordingly, infrared absorption and Raman scattering spectroscopy have provided valuable information on both distributions and ensemble-average values of molecular vibrational frequencies, and these frequencies are now routinely used to investigate structure, conformation, and even absolute configuration of chemical and biological molecules of interest. Recent advancements in coherent time-domain nonlinear vibrational spectroscopy have allowed the study of heterogeneous distributions of local structures and thermally driven ultrafast fluctuations of vibrational frequencies. To fully utilize IR probe functional groups for quantitative bioassays, a variety of biological and chemical techniques have been developed to site-specifically introduce vibrational probe groups into proteins and nucleic acids. These IR-probe-labeled biomolecules and chemically reactive systems are subject to linear and nonlinear vibrational spectroscopic investigations and provide information on the local electric field, conformational changes, site-site protein contacts, and/or function-defining features of biomolecules. A rapidly expanding library of data from such experiments requires an interpretive method with atom-level chemical accuracy. However, despite prolonged efforts to develop an all-encompassing theory for describing vibrational solvatochromism and electrochromism as well as dynamic fluctuations of instantaneous vibrational frequencies, purely empirical and highly approximate theoretical models have often been used to interpret experimental results. They are, in many cases, based on the simple assumption that the vibrational frequency of an IR reporter is solely dictated by electric potential or field distribution around the vibrational chromophore. Such simplified description of vibrational solvatochromism generally referred to as vibrational Stark effect theory has been considered to be quite appealing and, even in some cases, e.g., carbonyl stretch modes in amide, ester, ketone, and carbonate compounds or proteins, it works quantitatively well, which makes it highly useful in determining the strength of local electric field around the IR chromophore. However, noting that the vibrational frequency shift results from changes of solute-solvent intermolecular interaction potential along its normal coordinate, Pauli exclusion repulsion, polarization, charge transfer, and dispersion interactions, in addition to the electrostatic interaction between distributed charges of both vibrational chromophore and solvent molecules, are to be properly included in the theoretical description of vibrational solvatochromism. Since the electrostatic and nonelectrostatic intermolecular interaction components have distinctively different distance and orientation dependences, they affect the solvatochromic vibrational properties in a completely different manner. Over the past few years, we have developed a systematic approach to simulating vibrational solvatochromic data based on the effective fragment potential approach, one of the most accurate and rigorous theories on intermolecular interactions. We have further elucidated the interplay of local electric field with the general vibrational solvatochromism of small IR probes in either solvents or complicated biological systems, with emphasis on contributions from non-Coulombic intermolecular interactions to vibrational frequency shifts and fluctuations. With its rigorous foundation and close relation to quantitative interpretation of experimental data, this and related theoretical approaches and experiments will be of use in studying and quantifying the structure and dynamics of biomolecules with unprecedented time and spatial resolution when combined with time-resolved vibrational spectroscopy and chemically sensitive vibrational imaging techniques.

[1]  M. Gordon,et al.  Accurate first principles model potentials for intermolecular interactions. , 2013, Annual review of physical chemistry.

[2]  C. Morales,et al.  Molecular-level mechanisms of vibrational frequency shifts in a polar liquid. , 2011, The journal of physical chemistry. B.

[3]  J. Reimers,et al.  The Solvation of Acetonitrile , 1999 .

[4]  S. Andrews,et al.  Vibrational Stark Effects of Nitriles II. Physical Origins of Stark Effects from Experiment and Perturbation Models , 2002 .

[5]  J. Choi,et al.  Vibrational solvatochromism and electrochromism. II. Multipole analysis. , 2012, The Journal of chemical physics.

[6]  S. Boxer,et al.  Measuring electric fields and noncovalent interactions using the vibrational stark effect. , 2015, Accounts of chemical research.

[7]  S. Boxer,et al.  A solvatochromic model calibrates nitriles' vibrational frequencies to electrostatic fields. , 2012, Journal of the American Chemical Society.

[8]  A. D. Buckingham SOLVENT EFFECTS IN VIBRATIONAL SPECTROSCOPY , 1960 .

[9]  Feng Gai,et al.  C≡N stretching vibration of 5-cyanotryptophan as an infrared probe of protein local environment: what determines its frequency? , 2016, Physical chemistry chemical physics : PCCP.

[10]  Lauren J Webb,et al.  Vibrational solvatochromism of nitrile infrared probes: beyond the vibrational Stark dipole approach. , 2016, Physical chemistry chemical physics : PCCP.

[11]  H. Torii Amide I Vibrational Properties Affected by Hydrogen Bonding Out-of-Plane of the Peptide Group. , 2015, The journal of physical chemistry letters.

[12]  Katsumasa Fujita,et al.  Molecular imaging of live cells by Raman microscopy. , 2013, Current opinion in chemical biology.

[13]  C. Londergan,et al.  Covalently bound azido groups are very specific water sensors, even in hydrogen-bonding environments. , 2012, The journal of physical chemistry. B.

[14]  J. Skinner,et al.  Pronounced non-Condon effects in the ultrafast infrared spectroscopy of water. , 2005, The Journal of chemical physics.

[15]  B. A. Lindquist,et al.  Nitrile groups as vibrational probes of biomolecular structure and dynamics: an overview. , 2009, Physical chemistry chemical physics : PCCP.

[16]  Joshua P Layfield,et al.  Calculation of vibrational shifts of nitrile probes in the active site of ketosteroid isomerase upon ligand binding. , 2013, Journal of the American Chemical Society.

[17]  C. Londergan,et al.  Dynamic asymmetry and the role of the conserved active-site thiol in rabbit muscle creatine kinase. , 2015, Biochemistry.

[18]  Louise K. Charkoudian,et al.  Probing the Phosphopantetheine Arm Conformations of Acyl Carrier Proteins Using Vibrational Spectroscopy , 2014, Journal of the American Chemical Society.

[19]  M. Cho,et al.  Vibrational solvatochromism. III. Rigorous treatment of the dispersion interaction contribution. , 2015, The Journal of chemical physics.

[20]  S. Andrews,et al.  Vibrational Stark Effects of Nitriles I. Methods and Experimental Results , 2000 .

[21]  M. Cho Two-Dimensional Optical Spectroscopy , 2009 .

[22]  Lu Wei,et al.  Live-cell imaging of alkyne-tagged small biomolecules by stimulated Raman scattering , 2014, Nature Methods.

[23]  S. Mukamel,et al.  Electrostatic DFT map for the complete vibrational amide band of NMA. , 2005, The journal of physical chemistry. A.

[24]  J. Straub,et al.  Empirical Maps For The Calculation of Amide I Vibrational Spectra of Proteins From Classical Molecular Dynamics Simulations , 2014, The journal of physical chemistry. B.

[25]  M. Cho,et al.  Infrared probes for studying the structure and dynamics of biomolecules. , 2013, Chemical reviews.

[26]  M. Cho,et al.  Vibrational solvatochromism. II. A first-principle theory of solvation-induced vibrational frequency shift based on effective fragment potential method. , 2014, The Journal of chemical physics.

[27]  M. Cho,et al.  Infrared Probes Based on Nitrile-Derivatized Prolines: Thermal Insulation Effect and Enhanced Dynamic Range , 2013 .

[28]  Patrick W. Fowler,et al.  A model for the geometries of Van der Waals complexes , 1985 .

[29]  T. Jansen,et al.  Linear absorption and two-dimensional infrared spectra of N-methylacetamide in chloroform revisited: polarizability and multipole effects. , 2014, The journal of physical chemistry. B.

[30]  Minhaeng Cho,et al.  Isonitrile as an Ultrasensitive Infrared Reporter of Hydrogen-Bonding Structure and Dynamics. , 2016, The journal of physical chemistry. B.

[31]  M. Maienschein-Cline,et al.  The CN stretching band of aliphatic thiocyanate is sensitive to solvent dynamics and specific solvation. , 2007, The journal of physical chemistry. A.

[32]  Lauren J. Webb,et al.  Nitrile Probes of Electric Field Agree with Independently Measured Fields in Green Fluorescent Protein Even in the Presence of Hydrogen Bonding. , 2016, Journal of the American Chemical Society.

[33]  J. Knoester,et al.  A transferable electrostatic map for solvation effects on amide I vibrations and its application to linear and two-dimensional spectroscopy. , 2006, The Journal of chemical physics.

[34]  C. Londergan,et al.  Cyanylated Cysteine: A Covalently Attached Vibrational Probe of Protein−Lipid Contacts , 2010, The journal of physical chemistry letters.

[35]  Rossend Rey,et al.  Vibrational phase and energy relaxation of CN− in water , 1998 .

[36]  F. Gai,et al.  Site-specific infrared probes of proteins. , 2015, Annual review of physical chemistry.

[37]  M. Cho,et al.  Non-Gaussian statistics of amide I mode frequency fluctuation of N-methylacetamide in methanol solution: linear and nonlinear vibrational spectra. , 2004, The Journal of chemical physics.

[38]  M. Cho,et al.  Vibrational solvatochromism: towards systematic approach to modeling solvation phenomena. , 2013, The Journal of chemical physics.

[39]  J. Choi,et al.  Nitrile and thiocyanate IR probes: molecular dynamics simulation studies. , 2008, The Journal of chemical physics.

[40]  J. Skinner,et al.  Water Dynamics: Vibrational Echo Correlation Spectroscopy and Comparison to Molecular Dynamics Simulations , 2004 .

[41]  Minhaeng Cho,et al.  Nitrile and thiocyanate IR probes: quantum chemistry calculation studies and multivariate least-square fitting analysis. , 2008, The Journal of chemical physics.

[42]  C. Londergan,et al.  Using infrared spectroscopy of cyanylated cysteine to map the membrane binding structure and orientation of the hybrid antimicrobial peptide CM15. , 2011, Biochemistry.

[43]  Aurélien Planchat,et al.  A database of dispersion-induction DI, electrostatic ES, and hydrogen bonding α1 and β1 solvent parameters and some applications to the multiparameter correlation analysis of solvent effects. , 2015, The journal of physical chemistry. B.

[44]  M. Cho Vibrational solvatochromism and electrochromism: coarse-grained models and their relationships. , 2009, The Journal of chemical physics.

[45]  Feng Gai,et al.  Site-Specific Spectroscopic Reporters of the Local Electric Field, Hydration, Structure, and Dynamics of Biomolecules. , 2011, The journal of physical chemistry letters.

[46]  D. Ben‐Amotz,et al.  Solvent and pressure‐induced perturbations of the vibrational potential surface of acetonitrile , 1992 .

[47]  Ilya Kaliman,et al.  LIBEFP: A new parallel implementation of the effective fragment potential method as a portable software library , 2013, J. Comput. Chem..