Electrostatic Interactions in Protein Structure, Folding, Binding, and Condensation

Zhou, Huan‐Xiang; Pang, Xiaodong

doi:10.1021/acs.chemrev.7b00305

Cited by 696 publications

(568 citation statements)

References 613 publications

(1,264 reference statements)

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“…Sequence analysis and coarse-grained modeling have identified some generic determinants, in particular charged residues, for disorder and mean sizes of IDPs (16)(17)(18)(19). In recent years, small angle x-ray/neutron scattering (SAXS/SANS) (20), fluorescence techniques including nanosecond fluorescence correlation spectroscopy (nsFCS) and single-molecule fluorescence resonance energy transfer (smFRET) (21)(22)(23), nuclear magnetic resonance (NMR) spectroscopy (24), and all-atom molecular dynamics (MD) simulations (25) have become key biophysical tools to characterize conformation ensembles of IDPs.…”

Section: Introductionmentioning

confidence: 99%

Sequence-dependent correlated segments in the intrinsically disordered region of ChiZ

Hicks

Escobar

Cross

et al. 2020

Preprint

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Intrinsically disordered proteins (IDPs) account for a significant fraction of any proteome and are central to numerous cellular functions. Yet how sequences of IDPs code for their conformational dynamics is poorly understood. Here we combined NMR spectroscopy, small-angle X-ray scattering (SAXS), and molecular dynamics (MD) simulations to characterize the conformations and dynamics of ChiZ1-64. This IDP is the N-terminal fragment (residues 1-64) of the transmembrane protein ChiZ, a component of the cell division machinery in Mycobacterium tuberculosis. Its Nhalf contains most of the prolines and all of the anionic residues while the C-half most of the glycines and cationic residues. MD simulations, first validated by SAXS and secondary chemical shift data, found scant a-helices or b-strands but considerable propensity for polyproline II (PPII) torsion angles. Importantly, several blocks of residues (e.g., 11-29) emerge as "correlated segments", identified by frequent formation of PPII stretches, salt bridges, cation-p interactions, and sidechain-backbone hydrogen bonds. NMR relaxation experiments showed non-uniform transverse relaxation rates (R2s) and nuclear Overhauser enhancements (NOEs) along the sequence (e.g., high R2s and NOEs for residues 11-14 and 23-28). MD simulations further revealed that the extent of segmental correlation is sequence-dependent: segments where internal interactions are more prevalent manifest elevated "collective" motions on the 5-10 ns timescale and suppressed local motions on the sub-ns timescale. Amide proton exchange rates provides corroboration, with residues in the most correlated segment exhibiting the highest protection factors. We propose correlated segment as a defining feature for the conformation and dynamics of IDPs.

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Section: Introductionmentioning

confidence: 99%

Sequence-dependent correlated segments in the intrinsically disordered region of ChiZ

Hicks

Escobar

Cross

et al. 2020

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“…[1,4] Deoxyribonuclease and ovalbumin, for example, have identical isoelectricp oints of pI = 5.1, but the formal and measured net charge of both proteins differ by approximately 7u nits at pH 8.4. [4] The systematic absence of experimentally determinedv alues of Z has likely impeded ar igorous understanding of most chemicalp rocesses in which proteinsa re involved including aggregation and self-assembly, [20][21][22][23][24][25][26] ligand binding, [27][28][29][30][31][32][33][34] catalysis, [35][36][37][38][39] electron transfer, [3,6,[40][41][42][43][44][45][46][47] protein crystallization, [14,48] analytical separation, [49,50] and protein engineering. [51][52][53][54][55][56] It is tempting to assume that the formal net chargeo faprotein predicted from generalized residue pK a values (Z seq )issosimilar to the actual net charge that any difference is irrelevant, and the isoelectric point tells us all we need to know about ap rotein's net charge.…”

Section: Introductionmentioning

confidence: 99%

What Are We Missing by Not Measuring the Net Charge of Proteins?

Zahler

Shaw

2019

Chemistry A European J

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The net electrostatic charge (Z) of a folded protein in solution represents a bird's eye view of its surface potentials—including contributions from tightly bound metal, solvent, buffer, and cosolvent ions—and remains one of its most enigmatic properties. Few tools are available to the average biochemist to rapidly and accurately measure Z at pH≠pI. Tools that have been developed more recently seem to go unnoticed. Most scientists are content with this void and estimate the net charge of a protein from its amino acid sequence, using textbook values of pKa. Thus, Z remains unmeasured for nearly all folded proteins at pH≠pI. When marveling at all that has been learned from accurately measuring the other fundamental property of a protein—its mass—one wonders: what are we missing by not measuring the net charge of folded, solvated proteins? A few big questions immediately emerge in bioinorganic chemistry. When a single electron is transferred to a metalloprotein, does the net charge of the protein change by approximately one elementary unit of charge or does charge regulation dominate, that is, do the pKa values of most ionizable residues (or just a few residues) adjust in response to (or in concert with) electron transfer? Would the free energy of charge regulation (ΔΔGz) account for most of the outer sphere reorganization energy associated with electron transfer? Or would ΔΔGz contribute more to the redox potential? And what about metal binding itself? When an apo‐metalloprotein, bearing minimal net negative charge (e.g., Z=−2.0) binds one or more metal cations, is the net charge abolished or inverted to positive? Or do metalloproteins regulate net charge when coordinating metal ions? The author's group has recently dusted off a relatively obscure tool—the “protein charge ladder”—and used it to begin to answer these basic questions.

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“…Thus, the solvent reaction field will be different for each solvent. Although the enzymatic environment is heterogeneous and much more complex than the model we use, the effect of the electric field on the mechanism and on the values of the free energies of activation allows us to obtain insight into the nature of the corresponding electric fields of enzymes and into the way enzymes catalyze the phosphoryl‐transfer reaction in RNA.…”

Section: Introductionmentioning

confidence: 64%

“…This theory was proposed in the context of an explicit formulation of the environment, but it can also be applied in an implicit model, such as the model used herein. It has been proposed that the inside of an enzyme can be modeled as a solvent with a value of the dielectric constant at around 4 when the enzyme is a protein or a molecule of RNA . For ϵ =4, our results indicate that the O2′‐P‐O5′ angle increases from 70° in R a to 120° in R r , with this last value still being quite far from linearity.…”

Section: Discussionmentioning

confidence: 99%

Phosphoryl‐Transfer Reaction in RNA under Alkaline Conditions

Acosta-Silva

Bertrán

Branchadell

et al. 2018

Chemistry A European J

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The phosphoryl-transfer reaction in RNA under alkaline conditions by exploring the influence of several solvents theoretically was studied. The calculations were carried out by using the M06-2X functional and the solvents were taken as a continuum by using the solvent model density (SMD) method. The main findings show that the O2'-P-O5' angle in the reactants, the free activation energies, and the reaction mechanism are clearly dependent on the dielectric constant of the environment, thus showing that the electrostatic term is the determining factor for this chemical system with two negative charges. Our study seems to indicate that water, the solvent with the greatest dielectric constant, would be the solvent that increases the reaction rate the most. As this outcome was not the case in enzymatic catalysis, one has to conclude that, in the case of proteins as well as for ribozymes, the enzymatic catalysis is not mainly due to the solvent reaction field, but to local electrical fields as a result of enzyme preorganization.

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Electrostatic Interactions in Protein Structure, Folding, Binding, and Condensation

Cited by 696 publications

References 613 publications

Sequence-dependent correlated segments in the intrinsically disordered region of ChiZ

Sequence-dependent correlated segments in the intrinsically disordered region of ChiZ

What Are We Missing by Not Measuring the Net Charge of Proteins?

Phosphoryl‐Transfer Reaction in RNA under Alkaline Conditions

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