High-Resolution Terahertz Spectroscopy of Crystalline Trialanine:  Extreme Sensitivity to β-Sheet Structure and Cocrystallized Water

Siegrist, K.; Bucher, Christine R.; Mandelbaum, I.; Walker, Angela R. Hight; Balu, Radhakrishnan; Gregurick, Susan K.; Plusquellic, David F.

doi:10.1021/ja058176u

Cited by 97 publications

(89 citation statements)

References 45 publications

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“…The sharp orientation-dependent resonances may originate from either intramolecular motions or crystal lattice vibrations, phonons. Typical molecular crystals (such as sucrose) with basis group molecular weights of B100 Da have lattice phonons in the 10-100 cm À 1 range [29][30][31] . The lattice phonon frequency will scale inversely with the square root of the mass of the lattice basis, suggesting the lattice phonons for the 14-kDa molecular weight CEWL basis crystals are over an order of magnitude smaller, with frequencies less than 10 cm À 1 .…”

Section: Normal Mode Analysismentioning

confidence: 99%

Optical measurements of long-range protein vibrations

et al. 2014

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Protein biological function depends on structural flexibility and change. From cellular communication through membrane ion channels to oxygen uptake and delivery by haemoglobin, structural changes are critical. It has been suggested that vibrations that extend through the protein play a crucial role in controlling these structural changes. While nature may utilize such long-range vibrations for optimization of biological processes, bench-top characterization of these extended structural motions for engineered biochemistry has been elusive. Here we show the first optical observation of long-range protein vibrational modes. This is achieved by orientation-sensitive terahertz near-field microscopy measurements of chicken egg white lysozyme single crystals. Underdamped modes are found to exist for frequencies 410 cm À 1 . The existence of these persisting motions indicates that damping and intermode coupling are weaker than previously assumed. The methodology developed permits protein engineering based on dynamical network optimization.

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Section: Normal Mode Analysismentioning

confidence: 99%

Optical measurements of long-range protein vibrations

et al. 2014

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“…Dielectric spectroscopy extends the time scale from microseconds down to 0.1 ns (5). Experiments have been extended to the THz range in films and crystals, probing motions on the picosecond time scale (6,7). Hydrated protein powders probed by inelastic neutron scattering (0.1-100 ps) or solid-state NMR (nanoseconds) reveal that slower protein time scales and faster solvent time scales indeed show correlated dynamics (8).…”

mentioning

confidence: 99%

An extended dynamical hydration shell around proteins

Ebbinghaus

Kim²,

Heyden

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

633

623

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The focus in protein folding has been very much on the protein backbone and sidechains. However, hydration waters make comparable contributions to the structure and energy of proteins. The coupling between fast hydration dynamics and protein dynamics is considered to play an important role in protein folding. Fundamental questions of protein hydration include, how far out into the solvent does the influence of the biomolecule reach, how is the water affected, and how are the properties of the hydration water influenced by the separation between protein molecules in solution? We show here that Terahertz spectroscopy directly probes such solvation dynamics around proteins, and determines the width of the dynamical hydration layer. We also investigate the dependence of solvation dynamics on protein concentration. We observe an unexpected nonmonotonic trend in the measured terahertz absorbance of the five helix bundle protein * 6 -85 as a function of the protein: water molar ratio. The trend can be explained by overlapping solvation layers around the proteins. Molecular dynamics simulations indicate water dynamics in the solvation layer around one protein to be distinct from bulk water out to Ϸ10 Å. At higher protein concentrations such that solvation layers overlap, the calculated absorption spectrum varies nonmonotonically, qualitatively consistent with the experimental observations. The experimental data suggest an influence on the correlated water network motion beyond 20 Å, greater than the pure structural correlation length usually observed.solvation dynamics ͉ THz spectroscopy ͉ lambda repressor ͉ molecular modeling W ater molecules interact with proteins on many length and time scales. Although the dynamics of the hydration water occurs on the picosecond time scale, ''slaving'' to fast solvent modes profoundly affects the slower but larger-scale protein motions (1). In return the protein influences the structure and dynamics of surrounding water molecules (2). X-ray crystallography has revealed ordered water structure around polar and charged sidechains (3), as well as cooperative insertion of water into hydrophobic cavities (4). Dielectric spectroscopy extends the time scale from microseconds down to 0.1 ns (5). Experiments have been extended to the THz range in films and crystals, probing motions on the picosecond time scale (6, 7). Hydrated protein powders probed by inelastic neutron scattering (0.1-100 ps) or solid-state NMR (nanoseconds) reveal that slower protein time scales and faster solvent time scales indeed show correlated dynamics (8). On the fastest time scales, 2D infrared spectroscopy and fluorescence of surface residues provide local probes of the dynamics in the femtosecond to picosecond range (9, 10). Coupling of modeling with experiments has revealed complex solvation structure around small biomolecules (11, 12), bridging our microscopic structural and thermodynamic understanding of biosolvation.Terahertz absorption spectroscopy of biomolecules fully solvated in water yields direct informa...

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“…23 Since the THz frequency matches the low-frequency vibration and the vibration modes of weak interactions, such as hydrogen bonds, THz-TDS constitutes a unique tool for studying various molecules and materials whose molecular and/or crystal structures are stabilized by these weak interactions. The steric structures of many biological molecules are stabilized by hydrogen bonds, and THz-TDS studies have been undertaken on proteins, 26 polypeptides, 7,27,28 and DNA. 29,30 Figure 3(a) shows the absorption spectra of myoglobin powder obtained with THz (solid line) and Fourier-transform infrared spectroscopy (dotted line).…”

Section: Terahertz Time-domain Spectroscopy (Thz-tds)mentioning

confidence: 99%

“…28,40,41 Recently, we proposed a way to distinguish intramolecular modes selectively from intermolecular modes by incorporating target molecules in nano-sized spaces in porous materials to reduce the effect of the intermolecular interactions. 65 We measured the THz spectra of low molecular weights of organic acids, namely maleic and fumaric acids, with THz-TDS and compared the differences between the spectral features of the bulk crystal form and the molecules incorporated in the nano-sized pores of mesoporous silicate.…”

Section: Selective Detection Of Intramolecular Hydrogen Bondsmentioning

confidence: 99%