Trajectory Taken by Dimeric Cu/Zn Superoxide Dismutase through the Protein Unfolding and Dissociation Landscape Is Modulated by Salt Bridge Formation

McAlary, Luke; Harrison, Julian A.; Aquilina, J. Andrew; Fitzgerald, S.; Kelso, Céline; Benesch, Justin L. P.; Yerbury, Justin J.

doi:10.1021/acs.analchem.9b01699

Cited by 10 publications

(10 citation statements)

References 63 publications

(157 reference statements)

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“…Hybrid MD–Monte Carlo approaches have been developed for the combined search of conformer and charge-isomer space in the gas phase. These indicate that side chains have a propensity to fold onto the protein surface with consequent structure contraction and formation of new hydrogen bonds and salt bridges, a prediction for which experimental evidence is emerging . Such structural rearrangements promote self-solvation and are compatible with maintenance of a native-like fold.…”

Section: Determining How Charges Are Distributed On the Proteinmentioning

confidence: 98%

“…These indicate that side chains have a propensity to fold onto the protein surface with consequent structure contraction and formation of new hydrogen bonds and salt bridges, 70 a prediction for which experimental evidence is emerging. 73 Such structural rearrangements promote selfsolvation and are compatible with maintenance of a native-like fold. An interesting feature in the emerging picture of folded protein ions in the gas phase is their ability to compensate for the energetic penalty of charge separation in vacuo with favorable, conformation-specific intramolecular interactions, in line with growing experimental and theoretical evidence.…”

Section: Modelsmentioning

confidence: 99%

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Computational Strategies and Challenges for Using Native Ion Mobility Mass Spectrometry in Biophysics and Structural Biology

et al. 2020

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Native mass spectrometry (MS) allows the interrogation of structural aspects of macromolecules in the gas phase, under the premise of having initially maintained their solution-phase non-covalent interactions intact. In the more than 25 years since the first reports, the utility of native MS has become well established in the structural biology community. The experimental and technological advances during this time have been rapid, resulting in dramatic increases in sensitivity, mass range, resolution, and complexity of possible experiments. As experimental methods are improved, there have been accompanying developments in computational approaches for analysing and exploiting the profusion of MS data in a structural and biophysical context. Here, based on discussions within the EU COST Action BM1403 on Native MS and Related Methods for Structural Biology with broad participation from Europe and North America, we consider the computational strategies currently being employed by the community, aspects of best practice, and the challenges that remain to be addressed.

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Section: Determining How Charges Are Distributed On the Proteinmentioning

confidence: 98%

Section: Modelsmentioning

confidence: 99%

Computational Strategies and Challenges for Using Native Ion Mobility Mass Spectrometry in Biophysics and Structural Biology

et al. 2020

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“…For example, a superoxide dismutase mutant containing an additional arginine exhibits altered stability in IM-MS due to the formation of an additional salt bridge after desolvation. 23 In solution, alkaline pH unfolds proteins by breaking salt bridges and H-bonds and causing coulombic repulsion due to the high density of negative charges. In positive ionization mode, the negative charges are neutralized mitigating their repulsive effect.…”

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confidence: 99%

Ion mobility-mass spectrometry shows stepwise protein unfolding under alkaline conditions

et al. 2021

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“… The fact that proteins lacking basic residues favor the CRM over CEM reveals the limitations of using charge state signatures to assess the distribution of folded states . As a result, proteins with few ionizable groups may display diverging charging patterns upon unfolding. Previous studies have shown that point mutations can affect the CIU pattern of native-like protein ions by modulating their structure in solution. ,,, Our findings reveal that even identically folded proteins can exhibit different CIU fingerprints due to altered surface electrostatics during ESI. Because these differences arise from the locations of ESI charges, not from solution folding, care must be taken when using CIU data to probe solution structures. Gas-phase unfolding is routinely used to identify compounds that can stabilize protein complexes by occupying specific binding pockets. ,− We find that moving charged sites can have a dramatic effect on a protein’s conformation in the gas phase.…”

Section: Discussionmentioning

confidence: 52%

“… Previous studies have shown that point mutations can affect the CIU pattern of native-like protein ions by modulating their structure in solution. 9 , 15 , 54 , 55 Our findings reveal that even identically folded proteins can exhibit different CIU fingerprints due to altered surface electrostatics during ESI. Because these differences arise from the locations of ESI charges, not from solution folding, care must be taken when using CIU data to probe solution structures.…”

Section: Discussionmentioning

confidence: 74%

Charge Engineering Reveals the Roles of Ionizable Side Chains in Electrospray Ionization Mass Spectrometry

Abramsson

Sahin

Hopper

et al. 2021

JACS Au

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In solution, the charge of a protein is intricately linked to its stability, but electrospray ionization distorts this connection, potentially limiting the ability of native mass spectrometry to inform about protein structure and dynamics. How the behavior of intact proteins in the gas phase depends on the presence and distribution of ionizable surface residues has been difficult to answer because multiple chargeable sites are present in virtually all proteins. Turning to protein engineering, we show that ionizable side chains are completely dispensable for charging under native conditions, but if present, they are preferential protonation sites. The absence of ionizable side chains results in identical charge state distributions under native-like and denaturing conditions, while coexisting conformers can be distinguished using ion mobility separation. An excess of ionizable side chains, on the other hand, effectively modulates protein ion stability. In fact, moving a single ionizable group can dramatically alter the gas-phase conformation of a protein ion. We conclude that although the sum of the charges is governed solely by Coulombic terms, their locations affect the stability of the protein in the gas phase.

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Trajectory Taken by Dimeric Cu/Zn Superoxide Dismutase through the Protein Unfolding and Dissociation Landscape Is Modulated by Salt Bridge Formation

Cited by 10 publications

References 63 publications

Computational Strategies and Challenges for Using Native Ion Mobility Mass Spectrometry in Biophysics and Structural Biology

Computational Strategies and Challenges for Using Native Ion Mobility Mass Spectrometry in Biophysics and Structural Biology

Ion mobility-mass spectrometry shows stepwise protein unfolding under alkaline conditions

Charge Engineering Reveals the Roles of Ionizable Side Chains in Electrospray Ionization Mass Spectrometry

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