Royston Quintyn

Surface-Induced Dissociation of Homotetramers with D2 Symmetry Yields their Assembly Pathways and Characterizes the Effect of Ligand Binding

Understanding of protein complex assembly and the effect of ligand binding on their native topologies is integral to discerning how alterations in their architecture can affect function. Probing the disassembly pathway may offer insight into the mechanisms through which various subunits self-assemble into complexes. Here, a gas-phase dissociation method, surface-induced dissociation (SID) coupled with ion mobility (IM), was utilized to determine whether disassembly pathways are consistent with the assembly of three homotetramers and to probe the effects of ligand binding on conformational flexibility and tetramer stability. The results indicate that the smaller interface in the complex is initially cleaved upon dissociation, conserving the larger interface, and suggest that assembly of a D2 homotetramer from its constituent monomers occurs via a C2 dimer intermediate. In addition, we demonstrate that ligand-mediated changes in tetramer SID dissociation behavior are dependent on where and how the ligand binds.

Interfacial residues promote an optimal alignment of the catalytic center in human soluble guanylate cyclase: heterodimerization is required but not sufficient for activity.

Soluble guanylate cyclase (sGC) plays a central role in the cardiovascular system and is a drug target for the treatment of pulmonary hypertension. While the three-dimensional structure of sGC is unknown, studies suggest that binding of the regulatory domain to the catalytic domain maintains sGC in an autoinhibited basal state. The activation signal, binding of NO to heme, is thought to be transmitted via the regulatory and dimerization domains to the cyclase domain and unleashes the full catalytic potential of sGC. Consequently, isolated catalytic domains should show catalytic turnover comparable to that of activated sGC. Using X-ray crystallography, activity measurements, and native mass spectrometry, we show unambiguously that human isolated catalytic domains are much less active than basal sGC, while still forming heterodimers. We identified key structural elements regulating the dimer interface and propose a novel role for residues located in an interfacial flap and a hydrogen bond network as key modulators of the orientation of the catalytic subunits. We demonstrate that even in the absence of the regulatory domain, additional sGC domains are required to guide the appropriate conformation of the catalytic subunits associated with high activity. Our data support a novel regulatory mechanism whereby sGC activity is tuned by distinct domain interactions that either promote or inhibit catalytic activity. These results further our understanding of heterodimerization and activation of sGC and open additional drug discovery routes for targeting the NO–sGC–cGMP pathway via the design of small molecules that promote a productive conformation of the catalytic subunits or disrupt inhibitory domain interactions.

Surface-Induced Dissociation Mass Spectra as a Tool for Distinguishing Different Structural Forms of Gas-Phase Multimeric Protein Complexes.

One attractive feature of ion mobility mass spectrometry (IM-MS) lies in its ability to provide experimental collision cross section (CCS) measurements, which can be used to distinguish different conformations that a protein complex may adopt during its gas-phase unfolding. However, CCS values alone give no detailed information on subunit structure within the complex. Consequently, structural characterization typically requires molecular modeling, which can have uncertainties without experimental support. One method of obtaining direct experimental evidence on the structures of these intermediates is utilizing gas-phase activation techniques that can effectively dissociate the complexes into substructures while preserving the native topological information. The most commonly used activation method, collision-induced dissociation (CID) with low-mass target gases, typically leads to unfolding of monomers of a protein complex. Here, we describe a method that couples IM-MS and surface-induced dissociation (SID) to dissociate the source-activated precursors of three model protein complexes: C-reactive protein (CRP), transthyretin (TTR), and concanavalin A (Con A). The results of this study confirm that CID involves the unfolding of the protein complex via several intermediates. More importantly, our experiments also indicate that retention of similar CCS between different intermediates does not guarantee retention of structure. Although CID spectra (at a given collision energy) of source-activated, mass-selected precursors do not distinguish between native-like, collapsed, and expanded forms of a protein complex, dissociation patterns and/or average charge states of monomer products in SID of each of these forms are unique.

A dimer interface mutation in glyceraldehyde 3-phosphate dehydrogenase regulates its binding to AU-rich RNA.

DOI 10.1074/jbc.A114.618165 A dimer interface mutation in glyceraldehyde 3-phosphate dehydrogenase regulates its binding to AU-rich RNA. Michael R. White, Mohd M. Khan, Daniel Deredge, Christina R. Ross, Royston Quintyn, Beth E. Zucconi, Vicki H. Wysocki, Patrick L. Wintrode, Gerald M. Wilson, and Elsa D. Garcin PAGE 1780: The charge state distributions shown for the mass spectra peaks in Fig. 7B were not correct. The correct charge state distributions are shown in the revised Fig. 7B. This correction does not affect the results or conclusions of this work. THE JOURNAL OF BIOLOGICAL CHEMISTRY VOL. 290, NO. 7, p. 4129, February 13, 2015

Ligand binding and unfolding of tryptophan synthase revealed by ion mobility-tandem mass spectrometry employing collision and surface induced dissociation

Understanding protein tertiary and quaternary structures is crucial to a better understanding of their biological functions. Here we illustrate for tryptophan synthase that tandem mass spectrometry (MS/MS) reveals not only protein subunit architectures, but also protein unfolding behavior when coupled with ion mobility (IM). In the present study, we verified the subunit arrangement with surface induced dissociation (SID). We are able to correlate experimental results by IM with those obtained in unfolding simulations for the hetero-tetramer Tryptophan Synthase (TS) protein complex by identifying the presence of at least three stable intermediates (I1, I2, and I3) during the unfolding process in collision induced dissociation (CID). We illustrate that the unfolding of the TS complex is likely due to the initial unfolding of an α-monomer subunit, followed by the unfolding of the second α-monomers. We also illustrate the ability of this combination of techniques to not only identify conformational changes of TS upon addition of D,L-α-glycerol phosphate (GP), but also to determine the location of the ligand, which is buried within the α-monomer of the TS.

Surface-Induced Dissociation of Protein Complexes in a Hybrid Fourier Transform Ion Cyclotron Resonance Mass Spectrometer

Mass spectrometry continues to develop as a valuable tool in the analysis of proteins and protein complexes. In protein complex mass spectrometry studies, surface-induced dissociation (SID) has been successfully applied in quadrupole time-of-flight (Q-TOF) instruments. SID provides structural information on noncovalent protein complexes that is complementary to other techniques. However, the mass resolution of Q-TOF instruments can limit the information that can be obtained for protein complexes by SID. Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) provides ultrahigh resolution and ultrahigh mass accuracy measurements. In this study, an SID device was designed and successfully installed in a hybrid FT-ICR instrument in place of the standard gas collision cell. The SID-FT-ICR platform has been tested with several protein complex systems (homooligomers, a heterooligomer, and a protein-ligand complex, ranging from 53 to 85 kDa), and the results are consistent with data previously acquired on Q-TOF platforms, matching predictions from known protein interface information. SID fragments with the same m/z but different charge states are well-resolved based on distinct spacing between adjacent isotope peaks, and the addition of metal cations and ligands can also be isotopically resolved with the ultrahigh mass resolution available in FT-ICR.

Localization of Protein Complex Bound Ligands by Surface-Induced Dissociation High-Resolution Mass Spectrometry

Surface-induced dissociation (SID) is a powerful means of deciphering protein complex quaternary structures due to its capability of yielding dissociation products that reflect the native structures of protein complexes in solution. Here we explore the suitability of SID to locate the ligand binding sites in protein complexes. We studied C-reactive protein (CRP) pentamer, which contains a ligand binding site within each subunit, and cholera toxin B (CTB) pentamer, which contains a ligand binding site between each adjacent subunit. SID dissects ligand-bound CRP into subcomplexes with each subunit carrying predominantly one ligand. In contrast, SID of ligand-bound CTB results in the generation of subcomplexes with a ligand distribution reflective of two subunits contributing to each ligand binding site. SID thus has potential application in localizing sites of small ligand binding for multisubunit protein-ligand complexes.