X-ray snapshots reveal conformational influence on active site ligation during metalloprotein folding

Hsu, Darren J.; Leshchev, Denis; Rimmerman, Dolev; Hong, Junghwa; Kelley, Matthew S.; Kosheleva, Irina; Zhang, Xiaoyi; Chen, Lin X.

doi:10.1039/c9sc02630d

Cited by 18 publications

(12 citation statements)

References 73 publications

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“…However, the functions of a protein also depend on its stereostructure, which is not being provided by conventional MS based technologies. Biophysical methods such as X-ray crystallography, [4][5][6][7] nuclear magnetic resonance (NMR), [8][9][10] and electron microscopy [11][12][13] could provide detailed structural information of proteins but require laborious sample preparation, and the analysis of heterogeneous mixtures remains challenging. [14][15][16][17][18] Nanopores and nanopipettes have also been developed to analyze the volume, surface charge and structure dynamic process of proteins.…”

Section: Introductionmentioning

confidence: 99%

Rapid 3-dimensional shape determination of globular proteins by mobility capillary electrophoresis and native mass spectrometry

Zhang

et al. 2020

Chem. Sci.

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Section: Introductionmentioning

confidence: 99%

Rapid 3-dimensional shape determination of globular proteins by mobility capillary electrophoresis and native mass spectrometry

Zhang

et al. 2020

Chem. Sci.

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“…The X-ray scattering differences at longer time delays tracked the propagation of heme-doming motions into conformational changes in the outer protein, revealed in the species-associated difference signals in the SAXS regime. 60 A similar experiment on cyt c was also conducted to monitor structural changes upon electron transport, initiated by the photoexcitation of NADH. 63 Although this folding pathway did not reveal disordered intermediate states, the experimental data were modeled with an ensemble of MD simulated structures.…”

Section: Time-resolved Characterizations For MDmentioning

confidence: 99%

“…An obvious application of pump–probe approaches is toward photoactive proteins. For example, the structural dynamics of heme proteins (myoglobin and cytochrome c oxidase) have been widely studied with laser-triggered photolysis of a ligand to observe subsequent heme-doming and transient intermediates, critical in active site activation and oxidase reaction mechanisms. ,− Cytochrome c (cyt c ), a 104-residue electron transport chain protein, is a long-established model system for heme protein biophysics. In parallel time-resolved spectroscopy and scattering experiments, the folding mechanisms, including transient intermediates, of cyt c were observed upon the photodissociation of a CO-bound ground state.…”

Section: Time-resolved Characterizations For MD Structural Refinementmentioning

confidence: 99%

“…(c) Species-associated difference (SAD) on the left and their corresponding relative measured population on the right for the two intermediates, U M and U H , and the final unfolded state, F M . Reproduced from ref with permission from the Royal Society of Chemistry.…”

Section: Time-resolved Characterizations For MD Structural Refinementmentioning

confidence: 99%

“…Since the EXAFS structural characterization and wide-angle X-ray scattering (WAXS) were well correlated to describe the heme and nearby ligand dynamics, the two parallel observations were stitched together to distinguish more transient species than each experiment could individually. The X-ray scattering differences at longer time delays tracked the propagation of heme-doming motions into conformational changes in the outer protein, revealed in the species-associated difference signals in the SAXS regime . A similar experiment on cyt c was also conducted to monitor structural changes upon electron transport, initiated by the photoexcitation of NADH .…”

Section: Time-resolved Characterizations For MD Structural Refinementmentioning

confidence: 99%

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Resolving Dynamics in the Ensemble: Finding Paths through Intermediate States and Disordered Protein Structures

et al. 2021

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Proteins have been found to inhabit a diverse set of threedimensional structures. The dynamics that govern protein interconversion between structures happen over a wide range of time scalespicoseconds to seconds. Our understanding of protein functions and dynamics is largely reliant upon our ability to elucidate physically populated structures. From an experimental structural characterization perspective, we are often limited to measuring the ensemble-averaged structure both in the steady-state and time-resolved regimes. Generating kinetic models and understanding protein structure−function relationships require atomistic knowledge of the populated states in the ensemble. In this Perspective, we present ensemble refinement methodologies that integrate time-resolved experimental signals with molecular dynamics models. We first discuss integration of experimental structural restraints to molecular models in disordered protein systems that adhere to the principle of maximum entropy for creating a complete set of ensemble structures. We then propose strategies to find kinetic pathways between the refined structures, using time-resolved inputs to guide molecular dynamics trajectories and the use of inference to generate tailored stimuli to prepare a desired ensemble of protein states.

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Sensitivity of time‐resolved diffraction data to changes in internuclear distances and atomic positions

Jeong

Kim

et al. 2022

Bulletin Korean Chem Soc

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Time-resolved x-ray liquidography (TRXL) is a powerful technique to study molecular structural dynamics in the solution phase. Typically, a TRXL experiment is conducted during limited beamtime at a beamline of a synchrotron or an x-ray free-electron laser, demanding a proper design and careful planning. In this regard, the optimal q range needs to be determined to find the optimal x-ray energy and sample-to-detector distance. For such purpose, here, we present effective ways to quantify the sensitivity of the TRXL data as a function of q to various factors such as the atomic positions, internuclear distances, solvent cage, and bulk solvent. The developed approaches are also applicable to other types of time-resolved diffraction, such as ultrafast electron diffraction.

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X-ray snapshots reveal conformational influence on active site ligation during metalloprotein folding

Cited by 18 publications

References 73 publications

Rapid 3-dimensional shape determination of globular proteins by mobility capillary electrophoresis and native mass spectrometry

Rapid 3-dimensional shape determination of globular proteins by mobility capillary electrophoresis and native mass spectrometry

Resolving Dynamics in the Ensemble: Finding Paths through Intermediate States and Disordered Protein Structures

Sensitivity of time‐resolved diffraction data to changes in internuclear distances and atomic positions

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