Transient 2D IR spectroscopy of ubiquitin unfolding dynamics

Chung, Hoi Sung; Ganim, Ziad; Jones, Kevin C.; Tokmakoff, Andrei

doi:10.1073/pnas.0700959104

Cited by 164 publications

(190 citation statements)

References 51 publications

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“…7,8 Other important ways to increase effective resolution of the optical spectra include site-specific labeling with stable isotopes 9 and twodimensional multiphoton spectra sampling the chromophore coupling. 10 Simulations by modern quantum-chemical methods represent powerful tools for the spectra interpretations. 7,11,12 By comparison of the computed and experimental Raman and ROA spectral shapes not only the equilibrium structure but also an important knowledge about molecular flexibility and multiconformational states could be acquired.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics with restrictions derived from optical spectra

2008

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The information about molecular structure coded in the optical spectra must often be deciphered by complicated computational procedures. A combination of spectral modeling with the molecular dynamic simulations makes the process simpler, by implicit accounting for the inhomogeneous band broadening and Boltzmann averaging of many conformations. Ideally, geometries of studied systems can be deduced by a direct confrontation of such modeling with the experiment. In this work, the comparison is enhanced by restrictions to molecular dynamics propagations based on the Raman and Raman optical activity spectra. The methodology is introduced and tested on model systems comprising idealized H 2 O 2 , H 2 O 3 molecules, and the alanine zwitterion. An additional gradient term based on the spectral overlap smoothed by Fourier transformation is constructed and added to the molecular energy during the molecular dynamics run. For systems with one prevalent conformation the method did allow to enrich the Boltzmann ensemble by a spectroscopically favored structure. For systems with multiconformational equilibria families preferential conformations can be selected. An alternative algorithm based on the comparison of the averaged spectra with the reference enabling iterative updates of the conformer probabilities provided even more distinct distributions in shorter times. It also accounts for multiconformer equilibria and provided realistic spectra and conformer distribution for the alanine.

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Section: Introductionmentioning

confidence: 99%

Molecular dynamics with restrictions derived from optical spectra

2008

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“…Under these conditions a quantitative analysis of the spectra-structure relationships can be obtained. The 2D IR spectra of amyloid fibrils with 13 CA 18 O substitutions exhibit novel manifestations of the extended 3D structure of the fibrils, including the spatial arrangement of the coupled amide units and the presence of both static and fluctuating electric fields.…”

Section: A Myloid Fibrils Are Found In the Brain Tissue Of Persons Withmentioning

confidence: 99%

“…There has been a considerable amount of experimental work relating the 2D IR spectra of small peptide aggregates to their structure (13)(14)(15)(16)(17), and the recent experimental and theoretical applications of 2D IR have involved macromolecular systems such as folding proteins (18) and fibrils (19,20).…”

Section: A Myloid Fibrils Are Found In the Brain Tissue Of Persons Withmentioning

confidence: 99%

Two-dimensional infrared spectra of isotopically diluted amyloid fibrils from Aβ40

Kim

Liu

Axelsen

et al. 2008

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

132

224

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The 2D IR spectra of the amide-I vibrations of amyloid fibrils from A␤40 were obtained. The matured fibrils formed from strands having isotopic substitution by 13 CA 18 O at Gly-38, Gly-33, Gly-29, or Ala-21 show vibrational exciton spectra having reduced dimensionality. Indeed, linear chain excitons of amide units are seen, for which the interamide vibrational coupling is measured in fibrils grown from 50% and 5% mixtures of labeled and unlabeled strands. The data prove that the 1D excitons are formed from parallel in-register sheets. The coupling constants show that for each of the indicated residues the amide carbonyls in the chains are separated by 0.5 ؎ 0.05 nm. The isotope replacement of Gly-25 does not reveal linear excitons, consistent with the region of the strand having a different structure distribution. The vibrational frequencies of the amide-I modes, freed from effects of amide vibrational excitation exchange by 5% dilution experiments, point to there being a component of an electric field along the fibril axis that increases through the sequence Gly-38, Gly-33, Gly-29. The field is dominated by side chains of neighboring residues.␤-amyloid 40 ͉ exciton ͉ two-dimensional infrared spectroscopy A myloid fibrils are found in the brain tissue of persons with Alzheimer's disease, where they accumulate as plaques surrounded by regions of neuronal death. Although it remains unclear whether fibril formation is a cause of the neuronal loss in Alzheimer's disease, or a byproduct of another neurotoxic process, the formation and structure of amyloid fibrils is of intense interest.Fibrils are composed primarily of ␤-amyloid (A␤) proteins that range in length from 39 to 42 residues. They diffract x-rays with a characteristic ''cross-␤'' pattern (1-3), indicating that the polypeptide strands lie transverse to the fibril axis, with an interstrand spacing that is typical of a ␤-sheet. Solid-state NMR (4) and EPR (5) studies have shown that the ␤-sheet configuration is parallel and in register. Based on information from NMR, supplemented with information from atomic force microscopy, electron microscopy, and cross-linking studies, Tycko and coworkers (6, 7) have developed detailed models of the fibrils formed by 40-residue (A␤40) proteins. These models feature parallel in-register ␤-sheets involving residues 9-24 and 30-40 and a loop region, 23-29, that can vary with fibrillization conditions. A monofilament is formed by folding of each polypeptide chain such that the two sheets are apposed to each other, and two such monofilaments comprise the fibril (Fig. 1A). There is significant plasticity in the structural features of amyloid fibrils (8), and alternative models have been proposed (9).In the current work the structure and internal dynamics of amyloid fibrils are examined by 2D IR spectroscopy (10-12). There has been a considerable amount of experimental work relating the 2D IR spectra of small peptide aggregates to their structure (13-17), and the recent experimental and theoretical applications of 2D IR have in...

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“…The 2DIR technique distinguishes β-sheet structures by producing Z shape like spectra [18,19] when this particular structural motif is present. In the past decades a number of 2DIR studies have been reported of peptides and proteins in solution [16,[20][21][22][23][24][25][26][27][28][29][30][31][32][33] or confined in membranes [34][35][36][37][38], revealing structural details and conformational changes from femtosecond (fs) to nanosecond (ns) time scales, and the nature of dynamic environments. For the structure determination of peptides that are in gas phase or micro-solvated (surrounded by few solvent molecules) the mid-infrared spectroscopic technique has become a promising tool [39][40][41][42].…”

Section: Introductionmentioning

confidence: 99%

Solvent and conformation dependence of amide I vibrations in peptides and proteins containing proline

Roy

Lessing

Meisl

et al. 2011

The Journal of Chemical Physics

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We present a mixed quantum-classical model for studying the amide I vibrational dynamics (predominantly CO stretching) in peptides and proteins containing proline. There are existing models developed for determining frequencies of and couplings between the secondary amide units. However, these are not applicable to proline because this amino acid has a tertiary amide unit. Therefore, a new parametrization is required for infrared-spectroscopic studies of proteins that contain proline, such as collagen, the most abundant protein in humans and animals. Here, we construct the electrostatic and dihedral maps accounting for solvent and conformation effects on frequency and coupling for the proline unit. We examine the quality and the applicability of these maps by carrying out spectral simulations of a number of peptides with proline in D 2 O and compare with experimental observations.

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Transient 2D IR spectroscopy of ubiquitin unfolding dynamics

Cited by 164 publications

References 51 publications

Molecular dynamics with restrictions derived from optical spectra

Molecular dynamics with restrictions derived from optical spectra

Two-dimensional infrared spectra of isotopically diluted amyloid fibrils from Aβ40

Solvent and conformation dependence of amide I vibrations in peptides and proteins containing proline

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