Probing Local Electrostatics of Glycine in Aqueous Solution by THz Spectroscopy

Sebastiani, Federico; Yu, Chun; Funke, Sarah; Bäumer, Alexander; Decka, Dominique; Hoberg, Claudius; Esser, Andrea; Forbert, Harald; Schwaab, Gerhard; Marx, Dominik; Havenith, Martina

doi:10.1002/anie.202014133

Cited by 24 publications

(30 citation statements)

References 32 publications

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“…This is consistent with a population increase in the hard‐librations and a loss in population of soft‐librations, as observed experimentally. We want to mention that a similar absorption increase in the THz spectra at frequencies >400 cm −1 has been previously reported for hydration water molecules as a result of strong interactions with ions or with polar groups of biomolecules [43–45] . In order to quantify this effect, we take the slope of the absorption increase in the 450–600 cm −1 region and we compare it for different alcohols in Figure 3C.…”

Section: Figuresupporting

confidence: 55%

Spectroscopic Fingerprints of Cavity Formation and Solute Insertion as a Measure of Hydration Entropic Loss and Enthalpic Gain

et al. 2022

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Hydration free energies are dictated by a subtle balance of hydrophobic and hydrophilic interactions. We present here a spectroscopic approach, which gives direct access to the two main contributions: Using THz‐spectroscopy to probe the frequency range of the intermolecular stretch (150–200 cm−1) and the hindered rotations (450–600 cm−1), the local contributions due to cavity formation and hydrophilic interactions can be traced back. We show that via THz calorimetry these fingerprints can be correlated 1 : 1 with the group specific solvation entropy and enthalpy. This allows to deduce separately the hydrophobic (i.e. cavity formation) and hydrophilic contributions to thermodynamics, as shown for hydrated alcohols as a case study. Accompanying molecular dynamics simulations quantitatively support our experimental results. In the future our approach will allow to dissect hydration contributions in inhomogeneous mixtures and under non‐equilibrium conditions.

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Section: Figuresupporting

confidence: 55%

Spectroscopic Fingerprints of Cavity Formation and Solute Insertion as a Measure of Hydration Entropic Loss and Enthalpic Gain

et al. 2022

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“…The mutations introduced in MMP14-SIA induce changes in the surface electrostatic potential: the charge of six surface exposed groups (L117K, Q120D, A139E, E248G, V270R, E286 K; Table S1) is altered, the majority of which result in a more positively charged surface. The change of a charge, from i.e., negative to positive, as well as surface charge density is known to influence the organization of water molecules within the interfacial regime. − In a recent study, we could show that the THz absorption coefficient Δα provides a measure for local electrostatics of amino acids, with the positively charged state giving rise to an increased THz response . Considering the surface electrostatic potential of the three MMPs investigated here, the following trend of increasing positive potential is revealed: MMP14-WT < MMP9-WT < MMP14-SIA .…”

Section: Resultsmentioning

confidence: 68%

“… 49 − 51 In a recent study, we could show that the THz absorption coefficient Δα provides a measure for local electrostatics of amino acids, with the positively charged state giving rise to an increased THz response. 52 Considering the surface electrostatic potential of the three MMPs investigated here, the following trend of increasing positive potential is revealed: MMP14-WT < MMP9-WT < MMP14-SIA. 11 We note that this trend corresponds surprisingly well with the observed THz absorption coefficients in which the THz response becomes more positive in sign for a more positively charged surface distribution.…”

Section: Resultsmentioning

confidence: 78%

Local Mutations Can Serve as a Game Changer for Global Protein Solvent Interaction

Adams

Pezzotti

Ahlers

et al. 2021

JACS Au

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Although it is well-known that limited local mutations of enzymes, such as matrix metalloproteinases (MMPs), may change enzyme activity by orders of magnitude as well as its stability, the completely rational design of proteins is still challenging. These local changes alter the electrostatic potential and thus local electrostatic fields, which impacts the dynamics of water molecules close the protein surface. Here we show by a combined computational design, experimental, and molecular dynamics (MD) study that local mutations have not only a local but also a global effect on the solvent: In the specific case of the matrix metalloprotease MMP14, we found that the nature of local mutations, coupled with surface morphology, have the ability to influence large patches of the water hydrogen-bonding network at the protein surface, which is correlated with stability. The solvent contribution can be experimentally probed via terahertz (THz) spectroscopy, thus opening the door to the exciting perspective of rational protein design in which a systematic tuning of hydration water properties allows manipulation of protein stability and enzymatic activity.

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“…In the present study we provide a detailed characterization of the HB-network which is formed by water at a set of distinct “hydrophobic” environments, by combining density functional theory-based MD (DFT-MD) simulations with theoretical SFG and experimental/theoretical THz-IR vibrational spectroscopies. While SFG is a natural probe of the vibrational properties of buried interfaces, we complement it with THz-IR absorption spectroscopy, which has been proved to be an extremely sensitive technique to reveal the intermolecular dynamics of water. , The strength of the THz low-frequency spectroscopic fingerprints is that they can be directly related to the corresponding hydrogen bond network motifs close to hydrophilic and hydrophobic moieties. − …”

Section: Dft-md To Characterize the 2d-hb-networkmentioning

confidence: 99%

Molecular Fingerprints of Hydrophobicity at Aqueous Interfaces from Theory and Vibrational Spectroscopies

Pezzotti

Serva

Sebastiani

et al. 2021

J. Phys. Chem. Lett.

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Hydrophobicity/hydrophilicity of aqueous interfaces at the molecular level results from a subtle balance in the water–water and water–surface interactions. This is characterized here via density functional theory–molecular dynamics (DFT-MD) coupled with vibrational sum frequency generation (SFG) and THz-IR absorption spectroscopies. We show that water at the interface with a series of weakly interacting materials is organized into a two-dimensional hydrogen-bonded network (2D-HB-network), which is also found above some macroscopically hydrophilic silica and alumina surfaces. These results are rationalized through a descriptor that measures the number of “vertical” and “horizontal” hydrogen bonds formed by interfacial water, quantifying the competition between water–surface and water–water interactions. The 2D-HB-network is directly revealed by THz-IR absorption spectroscopy, while the competition of water–water and water–surface interactions is quantified from SFG markers. The combination of SFG and THz-IR spectroscopies is thus found to be a compelling tool to characterize the finest details of molecular hydrophobicity at aqueous interfaces.

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Probing Local Electrostatics of Glycine in Aqueous Solution by THz Spectroscopy

Cited by 24 publications

References 32 publications

Spectroscopic Fingerprints of Cavity Formation and Solute Insertion as a Measure of Hydration Entropic Loss and Enthalpic Gain

Spectroscopic Fingerprints of Cavity Formation and Solute Insertion as a Measure of Hydration Entropic Loss and Enthalpic Gain

Local Mutations Can Serve as a Game Changer for Global Protein Solvent Interaction

Molecular Fingerprints of Hydrophobicity at Aqueous Interfaces from Theory and Vibrational Spectroscopies

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