Identification of unfolding domains in large proteins by their unfolding rates

Advances in Hydrogen/Deuterium Exchange Mass Spectrometry and the Pursuit of Challenging Biological Systems

Solution-phase hydrogen/deuterium exchange (HDX) coupled to mass spectrometry (MS) is a widespread tool for structural analysis across academia and the biopharmaceutical industry. By monitoring the exchangeability of backbone amide protons, HDX-MS can reveal information about higher-order structure and dynamics throughout a protein, can track protein folding pathways, map interaction sites, and assess conformational states of protein samples. The combination of the versatility of the hydrogen/deuterium exchange reaction with the sensitivity of mass spectrometry has enabled the study of extremely challenging protein systems, some of which cannot be suitably studied using other techniques. Improvements over the past three decades have continually increased throughput, robustness, and expanded the limits of what is feasible for HDX-MS investigations. To provide an overview for researchers seeking to utilize and derive the most from HDX-MS for protein structural analysis, we summarize the fundamental principles, basic methodology, strengths and weaknesses, and the established applications of HDX-MS while highlighting new developments and applications.

High-resolution HDX-MS reveals distinct mechanisms of RNA recognition and activation by RIG-I and MDA5

RIG-I and MDA5 are the major intracellular immune receptors that recognize viral RNA species and undergo a series of conformational transitions leading to the activation of the interferon-mediated antiviral response. However, to date, full-length RLRs have resisted crystallographic efforts and a molecular description of their activation pathways remains hypothetical. Here we employ hydrogen/deuterium exchange coupled with mass spectrometry (HDX-MS) to probe the apo states of RIG-I and MDA5 and to dissect the molecular details with respect to distinct RNA species recognition, ATP binding and hydrolysis and CARDs activation. We show that human RIG-I maintains an auto-inhibited resting state owing to the intra-molecular HEL2i-CARD2 interactions while apo MDA5 lacks the analogous intra-molecular interactions and therefore adopts an extended conformation. Our work demonstrates that RIG-I binds and responds differently to short triphosphorylated RNA and long duplex RNA and that sequential addition of RNA and ATP triggers specific allosteric effects leading to RIG-I CARDs activation. We also present a high-resolution protein surface mapping technique that refines the cooperative oligomerization model of neighboring MDA5 molecules on long duplex RNA. Taken together, our data provide a high-resolution view of RLR activation in solution and offer new evidence for the molecular mechanism of RLR activation.

Dynamic conformations of nucleophosmin (NPM1) at a key monomer-monomer interface affect oligomer stability and interactions with granzyme B

Nucleophosmin (NPM1) is an abundant, nucleolar tumor antigen with important roles in cell proliferation and putative contributions to oncogenesis. Wild-type NPM1 forms pentameric oligomers through interactions at the amino-terminal core domain. A truncated form of NPM1 found in some hepatocellular carcinoma tissue formed an unusually stable oligomer and showed increased susceptibility to cleavage by granzyme B. Initiation of translation at the seventh methionine generated a protein (M7-NPM) that shared all these properties. We used deuterium exchange mass spectrometry (DXMS) to perform a detailed structural analysis of wild-type NPM1 and M7-NPM, and found dynamic conformational shifts or local “unfolding” at a specific monomer-monomer interface which included the β-hairpin “latch.” We tested the importance of interactions at the β-hairpin “latch” by replacing a conserved tyrosine in the middle of the β-hairpin loop with glutamic acid, generating Y67E-NPM. Y67E-NPM did not form stable oligomers and further, prevented wild-type NPM1 oligomerization in a dominant-negative fashion, supporting the critical role of the β-hairpin “latch” in monomer-monomer interactions. Also, we show preferential cleavage by granzyme B at one of two available aspartates (either D161 or D122) in M7-NPM and Y67E-NPM, whereas wild-type NPM1 was cleaved at both sites. Thus, we observed a correlation between the propensity to form oligomers and granzyme B cleavage site selection in nucleophosmin proteins, suggesting that a small change at an important monomer-monomer interface can affect conformational shifts and impact protein-protein interactions.

Analyzing protein dynamics using hydrogen exchange mass spectrometry

All cellular processes depend on the functionality of proteins. Although the functionality of a given protein is the direct consequence of its unique amino acid sequence, it is only realized by the folding of the polypeptide chain into a single defined three-dimensional arrangement or more commonly into an ensemble of interconverting conformations. Investigating the connection between protein conformation and its function is therefore essential for a complete understanding of how proteins are able to fulfill their great variety of tasks. One possibility to study conformational changes a protein undergoes while progressing through its functional cycle is hydrogen-(1)H/(2)H-exchange in combination with high-resolution mass spectrometry (HX-MS). HX-MS is a versatile and robust method that adds a new dimension to structural information obtained by e.g. crystallography. It is used to study protein folding and unfolding, binding of small molecule ligands, protein-protein interactions, conformational changes linked to enzyme catalysis, and allostery. In addition, HX-MS is often used when the amount of protein is very limited or crystallization of the protein is not feasible. Here we provide a general protocol for studying protein dynamics with HX-MS and describe as an example how to reveal the interaction interface of two proteins in a complex.

Hydrogen exchange mass spectrometry: are we out of the quicksand?

Although the use of hydrogen exchange (HX) mass spectrometry (MS) to study proteins and protein conformation is now over 20 years old, the perception lingers that it still has "issues." Is this method, in fact, still in the quicksand with many remaining obstacles to overcome? We do not think so. This critical insight addresses the "issues" and explores several broad questions including, have the limitations of HX MS been surmounted and has HX MS achieved "indispensable" status in the pantheon of protein structural analysis tools.

Probing protein interactions with hydrogen/deuterium exchange and mass spectrometry-a review

Assessing the functional outcome of protein interactions in structural terms is a goal of structural biology, however most techniques have a limited capacity for making structure-function determinations with both high resolution and high throughput. Mass spectrometry can be applied as a reader of protein chemistries in order to fill this void, and enable methodologies whereby protein structure-function determinations may be made on a proteome-wide level. Protein hydrogen/deuterium exchange (H/DX) offers a chemical labeling strategy suitable for tracking changes in "dynamic topography" and thus represents a powerful means of monitoring protein structure-function relationships. This review presents the exchange method in the context of interaction analysis. Applications involving interface detection, quantitation of binding, and conformational responses to ligation are discussed, and commentary on recent analytical developments is provided.

Allosteric suppression of HIV-1 reverse transcriptase structural dynamics upon inhibitor binding

Efavirenz is a second-generation nonnucleoside reverse transcriptase inhibitor (NNRTI) and a common component of clinically approved anti-AIDS regimens. NNRTIs are noncompetitive inhibitors that bind in a hydrophobic pocket in the p66 subunit of reverse transcriptase (RT) ∼10 Å from the polymerase active site. Hydrogen exchange mass spectrometry (HXMS) shows that efavirenz binding reduces molecular flexibility in multiple regions of RT heterodimer in addition to the NNRTI binding site. Of the 47 peptic fragments monitored by HXMS, 15 showed significantly altered H/D exchange rates in the presence of efavirenz. The slow cooperative unfolding of a β-sheet in the NNRTI binding pocket, which was previously observed in unliganded RT, is dramatically suppressed by efavirenz. HXMS also defines an extensive network of allosterically coupled sites, including four distinct regions of allosteric stabilization, and one region of allosteric destabilization. The effects of efavirenz binding extend > 60 Å from the NNRTI binding pocket. Allosteric changes to the structural dynamics propagate to the thumb and connection subdomains and RNase H domain of the p66 subunit as well as the thumb and palm subdomains of the p51 subunit. These allosteric regions may represent potential new drug targets.

Investigating solution-phase protein structure and dynamics by hydrogen exchange mass spectrometry

By taking advantage of labeling methods such as hydrogen exchange (HX), many details about protein conformation, dynamics, and interactions can be revealed by mass spectrometry. In this unit, hydrogen exchange theory is discussed as it applies to HX-MS protocols, the practice of HX-MS including data analysis and interpretation is explained in detail, and recent advancements in technology which greatly increase the depth of information gained from the technique are highlighted.

The gramicidin dimer shows both EX1 and EX2 mechanisms of H/D exchange

We describe the use of H/D amide exchange and electrospray ionization mass spectrometry to study, in organic solvents, the pentadecapeptide gramicidin as a model for protein self association. In methanol-OD, all active H's in the peptide exchange for D within 5 min, indicating a monomer/dimer equilibrium that is shifted towards the fast-exchanging monomer. H/D exchange in n-propanol-OD, however, showed a partially protected gramicidin that slowly converts to a second species that exchanges nearly all the active hydrogens, indicating EX1 kinetics for the H/D exchange. We propose that this behavior is the result of the slower rate of unfolding in n-propanol compared with that in methanol. The rate constant for the unfolding of the dimer is the rate of disappearance of the partially protected species, and it agrees within a factor of two with a value reported in literature. The rate constant of dimer refolding can be determined from the ratio of the rate constant for unfolding and the affinity constant for the dimer, which we determined in an earlier study. The unfolding activation energy is 20 kcal mol(-1), determined by performing the exchange experiments as a function of temperature. To study gramicidin in an even more hydrophobic medium than n-propanol, we measured its H/D exchange kinetics in a phospholipids vesicle and found a different H/D amide exchange behavior. Gramicidin is an unusual peptide dimer that can exhibit both EX1 and EX2 mechanisms for its H/D exchange, depending on the solvent.

Noncooperative folding of subdomains in adenylate kinase

Conformational change is regulating the biological activity of a large number of proteins and enzymes. Efforts in structural biology have provided molecular descriptions of the interactions that stabilize the stable ground states on the reaction trajectories during conformational change. Less is known about equilibrium thermodynamic stabilities of the polypeptide segments that participate in structural changes and whether the stabilities are relevant for the reaction pathway. Adenylate kinase (Adk) is composed of three subdomains: CORE, ATPlid, and AMPbd. ATPlid and AMPbd are flexible nucleotide binding subdomains where large-scale conformational changes are directly coupled to catalytic activity. In this report, the equilibrium thermodynamic stabilities of Adk from both mesophilic and hyperthermophilic bacteria were investigated using solution state NMR spectroscopy together with protein engineering experiments. Equilibrium hydrogen to deuterium exchange experiments indicate that the flexible subdomains are of significantly lower thermodynamic stability compared to the CORE subdomain. Using site-directed mutagenesis, parts of ATPlid and AMPbd could be selectively unfolded as a result of perturbation of hydrophobic clusters located in these respective subdomains. Analysis of the perturbed Adk variants using NMR spin relaxation and C(alpha) chemical shifts shows that the CORE subdomain can fold independently of ATPlid and AMPbd; consequently, folding of the two flexible subdomains occurs independently of each other. Based on the experimental results it is apparent that the flexible subdomains fold into their native structure in a noncooperative manner with respect to the CORE subdomain. These results are discussed in light of the catalytically relevant conformational change of ATPlid and AMPbd.

Synthesis of biotin-tagged chemical cross-linkers and their applications for mass spectrometry

Chemical cross-linking combined with mass spectrometry (MS) has been used to elucidate protein structures and protein-protein interactions. However, heterogeneity of the samples and the relatively low abundance of cross-linked peptides make this approach challenging. As an effort to overcome this hurdle, we have synthesized lysine-reactive homobifunctional cross-linkers with the biotin in the middle of the linker and used them to enrich cross-linked peptides. The reaction of biotin-tagged cross-linkers with purified HIV-1 CA resulted in the formation of hanging and intramolecular cross-links. The peptides modified with biotinylated cross-linkers were effectively enriched and recovered using a streptavidin-coated plate and MS-friendly buffers. The enrichment of modified peptides and removal of the dominantly unmodified peptides simplify mass spectra and their analyses. The combination of the high mass accuracy of Fourier transform ion cyclotron resonance (FT-ICR) MS and the tandem mass spectrometric (MS/MS) capability of the linear ion trap allows us to unambiguously identify the cross-linking sites and additional modification, such as oxidation.

Dynamics of glyphosate-induced conformational changes of Mycobacterium tuberculosis 5-enolpyruvylshikimate-3-phosphate synthase (EC 2.5.1.19) determined by hydrogen-deuterium exchange and electrospray mass spectrometry

The enzyme 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) catalyzes the reaction between shikimate 3-phosphate and phosphoenolpyruvate to form 5-enolpyruvylshikimate 3-phosphate, an intermediate in the shikimate pathway, which leads to the biosynthesis of aromatic amino acids. EPSPS exists in an open conformation in the absence of substrates and/or inhibitors and in a closed conformation when bound to the substrate and/or inhibitor. In the present report, the H/D exchange properties of EPSPS from Mycobacterium tuberculosis ( Mt) were investigated for both enzyme conformations using ESI mass spectrometry and circular dichroism (CD). When the conformational changes identified by H/D exchanges were mapped on the 3-D structure, it was observed that the apoenzyme underwent extensive conformational changes due to glyphosate complexation, characterized by an increase in the content of alpha-helices from 40% to 57%, while the beta-sheet content decreased from 30% to 23%. These results indicate that the enzyme underwent a series of rearrangements of its secondary structure that were accompanied by a large decrease in solvent access to many different regions of the protein. This was attributed to the compaction of 71% of alpha-helices and 57% of beta-sheets as a consequence of glyphosate binding to the enzyme. Apparently, MtEPSPS undergoes a series of inhibitor-induced conformational changes, which seem to have caused synergistic effects in preventing solvent access to the core of molecule, especially in the cleft region. This may be part of the mechanism of inhibition of the enzyme, which is required to prevent the hydration of the substrate binding site and also to induce the cleft closure to avoid entrance of the substrates.

Folding and assembly of large macromolecular complexes monitored by hydrogen-deuterium exchange and mass spectrometry

Recent advances in protein mass spectrometry (MS) have enabled determinations of hydrogen deuterium exchange (HDX) in large macromolecular complexes. HDX-MS became a valuable tool to follow protein folding, assembly and aggregation. The methodology has a wide range of applications in biotechnology ranging from quality control for over-expressed proteins and their complexes to screening of potential ligands and inhibitors. This review provides an introduction to protein folding and assembly followed by the principles of HDX and MS detection, and concludes with selected examples of applications that might be of interest to the biotechnology community.

Scope and utility of hydrogen exchange as a tool for mapping landscapes

The ability to determine conformational parameters of protein-folding landscapes is critical for understanding the link between conformation, function, and disease. Monitoring hydrogen exchange (HX) of labile protons at equilibrium enables direct extraction of thermodynamic or kinetic landscape parameters in two limiting extremes. Here, we establish a quantitative framework for relating HX behavior to landscape. We use this framework to demonstrate that the range of predicted global HX behavior for the majority of a set of characterized two-state proteins under near-native conditions does not readily span between both extremes. For most, stability may be quantitatively determined under physiological conditions, with semiquantitative boundaries on kinetics additionally determined using modest experimental perturbations to shift HX behavior. The framework and relationships derived in the simple context of two-state global folding highlight the importance of understanding HX across the entire continuum of behavior, in order to apply HX to map landscapes.

The folding energy landscape of the dimerization domain of Escherichia coli Trp repressor: a joint experimental and theoretical investigation

Enhanced structural insights into the folding energy landscape of the N-terminal dimerization domain of Escherichia coli tryptophan repressor, [2-66]2 TR, were obtained from a combined experimental and theoretical analysis of its equilibrium folding reaction. Previous studies have shown that the three intertwined helices in [2-66]2 TR are sufficient to drive the formation of a stable dimer for the full-length protein, [2-107]2 TR. The monomeric and dimeric folding intermediates that appear during the folding reactions of [2-66]2 TR have counterparts in the folding mechanism of the full-length protein. The equilibrium unfolding energy surface on which the folding and dimerization reactions occur for [2-66]2 TR was examined with a combination of native-state hydrogen exchange analysis, pepsin digestion and matrix-assisted laser/desorption mass spectrometry performed at several concentrations of protein and denaturant. Peptides corresponding to all three helices in [2-66]2 TR show multi-layered protection patterns consistent with the relative stabilities of the dimeric and monomeric folding intermediates. The observation of protection exceeding that offered by the dimeric intermediate in segments from all three helices implies that a segment-swapping mechanism may be operative in the monomeric intermediate. Protection greater than that expected from the global stability for a single amide hydrogen in a peptide from the C-helix possibly and another from the A-helix may reflect non-random structure, possibly a precursor for segment swapping, in the urea-denatured state. Native topology-based model simulations that correspond to a funnel energy landscape capture both the monomeric and dimeric intermediates suggested by the HX MS data and provide a rationale for the progressive acquisition of secondary structure in their conformational ensembles.

Hydrogen exchange mass spectrometry for the analysis of protein dynamics

Hydrogen exchange coupled to mass spectrometry (MS) has become a valuable analytical tool for the study of protein dynamics. By combining information about protein dynamics with more classical functional data, a more thorough understanding of protein function can be obtained. In many cases, protein dynamics are directly related to specific protein functions such as conformational changes during enzyme activation or protein movements during binding. The method is made possible because labile backbone hydrogens in a protein will exchange with deuterium atoms when the protein is placed in a D2O solution. The subsequent increase in protein mass over time is measured with high-resolution MS. The location of the deuterium incorporation is determined by monitoring deuterium incorporation in peptic fragments that are produced after the labeling reaction. In this review, we will summarize the general principles of the method, discuss the latest variations on the experimental protocol that probe different types of protein movements, and review other recent work and improvements in the field.

Domain study of bacteriophage p22 coat protein and characterization of the capsid lattice transformation by hydrogen/deuterium exchange

Viral capsids are dynamic structures which undergo a series of structural transformations to form infectious viruses. The dsDNA bacteriophage P22 is used as a model system to study the assembly and maturation of icosahedral dsDNA viruses. The P22 procapsid, which is the viral capsid precursor, is assembled from coat protein with the aid of scaffolding protein. Upon DNA packaging, the capsid lattice expands and becomes a stable virion. Limited proteolysis and biochemical experiments indicated that the coat protein consists of two domains connected by a flexible loop. To investigate the properties and roles of the sub-domains, we have cloned them and initiated structure and function studies. The N-terminal domain, which is made up of 190 amino acid residues, is largely unstructured in solution, while the C-terminal domain, which consists of 239 amino acid residues, forms a stable non-covalent dimer. The N-terminal domain adopts additional structure in the context of the C-terminal domain which might form a platform on which the N-terminal domain can fold. The local dynamics of the coat protein in both procapsids and mature capsids was monitored by hydrogen/deuterium exchange combined with mass spectrometry. The exchange rate for C-terminal domain peptides was similar in both forms. However, the N-terminal domain was more flexible in the empty procapsid shells than in the mature capsids. The flexibility of the N-terminal domain observed in the solution persisted into the procapsid form, but was lost upon maturation. The loop region connecting the two domains exchanged rapidly in the empty procapsid shells, but more slowly in the mature capsids. The global stabilization of the N-terminal domain and the flexibility encoded in the loop region may be a key component of the maturation process.

An Obligatory Intermediate Controls the Folding of the α-Subunit of Tryptophan Synthase, a TIM Barrel Protein

The proposed kinetic folding mechanism of the alpha-subunit of tryptophan synthase (alphaTS), a TIM barrel protein, displays multiple unfolded and intermediate forms which fold through four parallel pathways to reach the native state. To obtain insight into the secondary structure that stabilizes a set of late, highly populated kinetic intermediates, the refolding of urea-denatured alphaTS from Escherichia coli was monitored by pulse-quench hydrogen exchange mass spectrometry. Following dilution from 8 M urea, the protein was pulse-labeled with deuterium, quenched with acid and mass analyzed by electrospray ionization mass spectrometry (ESI-MS). Hydrogen bonds that form prior to the pulse of deuterium offer protection against exchange and, therefore, retain protons at the relevant amide bonds. Consistent with the proposed refolding model, an intermediate builds up rapidly and decays slowly over the first 100 seconds of folding. ESI-MS analysis of the peptic fragments derived from alphaTS mass-labeled and quenched after two seconds of refolding indicates that the pattern of protection of the backbone amide hydrogens in this transient intermediate is very similar to that observed previously for the equilibrium intermediate of alphaTS highly populated at 3 M urea. The protection observed in a contiguous set of beta-strands and alpha-helices in the N terminus implies a significant role for this sub-domain in directing the folding of this TIM barrel protein.

Protein conformations, interactions, and H/D exchange

Modern mass spectrometry (MS) is well known for its exquisite sensitivity in probing the covalent structure of macromolecules, and for that reason, it has become the major tool used to identify individual proteins in proteomics studies. This use of MS is now widespread and routine. In addition to this application of MS, a handful of laboratories are developing and using a methodology by which MS can be used to probe protein conformation and dynamics. This application involves using MS to analyze amide hydrogen/deuterium (H/D) content from exchange experiments. Introduced by Linderstøm-Lang in the 1950s, H/D exchange involves using (2)H labeling to probe the rate at which protein backbone amide protons undergo chemical exchange with the protons of water. With the advent of highly sensitive electrospray ionization (ESI)-MS, a powerful new technique for measuring H/D exchange in proteins at unprecedented sensitivity levels also became available. Although it is still not routine, over the past decade the methodology has been developed and successfully applied to study various proteins and it has contributed to an understanding of the functional dynamics of those proteins.

Multi-state Unfolding of the Alpha Subunit of Tryptophan Synthase, a TIM Barrel Protein: Insights into the Secondary Structure of the Stable Equilibrium Intermediates by Hydrogen Exchange Mass Spectrometry

The urea-induced unfolding of the alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli, an eight-stranded (beta/alpha)(8) TIM barrel protein, has been shown to involve two stable equilibrium intermediates, I1 and I2, well populated at approximately 3 M and 5 M urea, respectively. The characterization of the I1 intermediate by circular dichroism (CD) spectroscopy has shown that I1 retains a significant fraction of the native ellipticity; the far-UV CD signal for the I2 species closely resembles that of the fully unfolded form. To obtain detailed insight into the disruption of secondary structure in the urea-induced unfolding process, a hydrogen exchange-mass spectrometry study was performed on alphaTS. The full-length protein was destabilized in increasing concentration of urea, the amide hydrogen atoms were pulse-labeled with deuterium, the labeled samples were quenched in acid and the products were analyzed by electrospray ionization mass spectrometry. Consistent with the CD results, the I1 intermediate protects up to approximately 129 amide hydrogen atoms against exchange while the I2 intermediate offers no protection. Electrospray ionization mass spectrometry analysis of the peptic fragments derived from alphaTS labeled at 3 M urea indicates that most of the region between residues 12-130, which constitutes the first four beta strands and three alpha helices, (beta/alpha)(1-3)beta(4), is structured. The (beta/alpha)(1-3)beta(4) module appears to represent the minimum sub-core of stability of the I1 intermediate. A 4+2+2 folding model is proposed as a likely alternative to the earlier 6+2 folding mechanism for alphaTS.

Equilibrium and Kinetic Folding of Rabbit Muscle Triosephosphate Isomerase by Hydrogen Exchange Mass Spectrometry

Unfolding and refolding of rabbit muscle triosephosphate isomerase (TIM), a model for (betaalpha)8-barrel proteins, has been studied by amide hydrogen exchange/mass spectrometry. Unfolding was studied by destabilizing the protein in guanidine hydrochloride (GdHCl) or urea, pulse-labeling with 2H2O and analyzing the intact protein by HPLC electrospray ionization mass spectrometry. Bimodal isotope patterns were found in the mass spectra of the labeled protein, indicating two-state unfolding behavior. Refolding experiments were performed by diluting solutions of TIM unfolded in GdHCl or urea and pulse-labeling with 2H2O at different times. Mass spectra of the intact protein labeled after one to two minutes had three envelopes of isotope peaks, indicating population of an intermediate. Kinetic modeling indicates that the stability of the folding intermediate in water is only 1.5 kcal/mol. Failure to detect the intermediate in the unfolding experiments was attributed to its low stability and the high concentrations of denaturant required for unfolding experiments. The folding status of each segment of the polypeptide backbone was determined from the deuterium levels found in peptic fragments of the labeled protein. Analysis of these spectra showed that the C-terminal half folds to form the intermediate, which then forms native TIM with folding of the N-terminal half. These results show that TIM folding fits the (4+4) model for folding of (betaalpha)8-barrel proteins. Results of a double-jump experiment indicate that proline isomerization does not contribute to the rate-limiting step in the folding of TIM.

Mass Spectrometric Approaches Using Electrospray Ionization Charge States and Hydrogen-Deuterium Exchange for Determining Protein Structures and Their Conformational Changes

Electrospray ionization (ESI) mass spectrometry (MS) is a powerful analytical tool for elucidating structural details of proteins in solution especially when coupled with amide hydrogen/deuterium (H/D) exchange analysis. ESI charge-state distributions and the envelopes of charges they form from proteins can provide an abundance of information on solution conformations that is not readily available through other biophysical techniques such as near ultraviolet circular dichroism (CD) and tryptophan fluorescence. The most compelling reason for the use of ESI-MS over nuclear magnetic resonance (NMR) for measuring H/D after exchange is that larger proteins and lesser amounts of samples can be studied. In addition, MS can provide structural details on transient or folding intermediates that may not be accessible by CD, fluorescence, and NMR because these techniques measure the average properties of large populations of proteins in solution. Correlations between measured H/D and calculated parameters that are often available from crystallographic data can be used to extend the range of structural details obtained on proteins. Molecular dynamics and energy minimization by simulation techniques such as assisted model building with energy refinement (AMBER) force field can be very useful in providing structural models of proteins that rationalize the experimental H/D exchange results. Charge-state envelopes and H/D exchange information from ESI-MS data used complementarily with NMR and CD data provides the most powerful approach available to understanding the structures and dynamics of proteins in solution.

Optimization of conditions for studies of protein unfolding by hydrogen exchange/mass spectrometry

Understanding the forces driving protein folding and aggregation is an essential step in developing means for controlling these important processes. Amide hydrogen exchange, coupled with mass spectrometry, has become an important method for studying protein unfolding and refolding. To extend procedures developed to study unfolding of relatively soluble proteins to less soluble, aggregation-prone proteins requires special considerations. This publication describes a general strategy developed using yeast transaldolase, which aggregates easily under conditions required to study its unfolding. Results presented here show that reducing the protein concentration to the nanomolar range is essential for managing aggregation of transaldolase. In addition, the present results point to use of relatively high concentrations of denaturants and short incubation times to minimize aggregation. These results also show how amide hydrogen exchange, coupled with mass spectrometry, can be used to study soluble aggregates.

Hydrogen/deuterium exchange mass spectrometry of actin in various biochemical contexts

Hydrogen/deuterium exchange mass spectrometry (H/D MS) of monomeric actin (G-actin), polymeric actin (F-actin), phalloidin-bound F-actin and G-actin complexed with DNase I provides new insights into the architecture of F-actin and the effects of phalloidin and DNase I binding. Although the overall pattern of deuteration change supports the gross features of the Holmes F-actin model, two important differences were observed. Most significantly, no change in deuteration was observed in the critical "hydrophobic plug" region, suggesting this feature may not be present. Polymerization also produced deuteration increases for peptide fragments containing the ATP phosphate-binding loops, suggesting G-actin transitions to a more "open" conformation upon polymerization. However, polymerization produced decreases in deuteration mainly localized to the "inner", filament-axis side as predicted by the Holmes model. Mapping the phalloidin-induced decreases in F-actin deuteration onto the Lorenz binding site produced a single common patch straddling two monomers across the 1-start helix contact, again consistent with the Holmes architecture. Finally, both DNase I and phalloidin were able to alter the deuteration of regions distal to their respective binding sites. These results highlight the great opportunities for H/D MS to exploit high-resolution structures for detailed studies of the organization and dynamics of complex molecular assemblies.

Protein analysis by hydrogen exchange mass spectrometry

Mass spectrometry has provided a powerful method for monitoring hydrogen exchange of protein backbone amides with deuterium from solvent. In comparison to popular NMR approaches, mass spectrometry has the advantages of higher sensitivity, wider coverage of sequence, and the ability to analyze larger proteins. Proteolytic fragmentation of proteins following the exchange reaction provides moderate structural resolution, in some cases enabling measurements from single amides. The technique has provided new insight into protein-protein and protein-ligand interfaces, as well as conformational changes during protein folding or denaturation. In addition, recent studies illustrate the utility of hydrogen exchange mass spectrometry toward detecting protein motions relevant to allostery, covalent modifications, and enzyme function.

Mapping temperature-induced conformational changes in the Escherichia coli heat shock transcription factor sigma 32 by amide hydrogen exchange

Stress conditions such as heat shock alter the transcriptional profile in all organisms. In Escherichia coli the heat shock transcription factor, sigma 32, out-competes upon temperature up-shift the housekeeping sigma-factor, sigma 70, for binding to core RNA polymerase and initiates heat shock gene transcription. To investigate possible heat-induced conformational changes in sigma 32 we performed amide hydrogen (H/D) exchange experiments under optimal growth and heat shock conditions combined with mass spectrometry. We found a rapid exchange of around 220 of the 294 amide hydrogens at 37 degrees C, indicating that sigma 32 adopts a highly flexible structure. At 42 degrees C we observed a slow correlated exchange of 30 additional amide hydrogens and localized it to a helix-loop-helix motif within domain sigma 2 that is responsible for the recognition of the -10 region in heat shock promoters. The correlated exchange is shown to constitute a reversible unfolding with a half-life of about 30 min due to a temperature-dependent decrease in stabilization energy. We propose that this gradual decrease in stabilization energy of domain sigma 2 with increasing temperatures facilitates the unfolding of sigma 32 by the AAA+ protease FtsH thereby decreasing its half-life. Taken together our data show that the sigma 2 domain of sigma 32 can act as a thermosensor, which might be important for the heat shock regulation.

Protein-folding kinetics and mechanisms studied by pulse-labeling and mass spectrometry

The "protein-folding problem" refers to the question of how and why a denatured polypeptide chain can spontaneously fold into a compact and highly ordered conformation. The classical description of this process in terms of reaction pathways has been complemented by models that describe folding as a biased conformational diffusion on a multidimensional energy landscape. The identification and characterization of short-lived intermediates provide important insights into the mechanism of folding. Pulsed hydrogen/deuterium exchange (HDX) methods are among the most powerful tools for studying the properties of kinetic intermediates. Analysis of pulse-labeled proteins by mass spectrometry (MS) provides information that is complementary to that obtained in nuclear magnetic resonance (NMR) studies; NMR data represent an average of entire protein ensembles, whereas MS can detect co-existing protein species. MS-based pulse-labeling experiments can distinguish between folding scenarios that involve parallel pathways, and those where folding is channeled through obligatory intermediates. The proteolytic digestion/MS technique provides spatially resolved information on the HDX pattern of folding intermediates. This method is especially important for proteins that are too large to be studied by NMR. Although traditional pulsed HDX protocols are based on quench-flow techniques, it is also possible to use electrospray (ESI) MS to analyze the reaction mixture on-line and "quasi-instantaneously" after labeling. This approach allows short-lived protein conformations to be studied by their HDX level, their ESI charge-state distribution, and their ligand-binding state. Covalent labeling of free cysteinyl residues provides an alternative approach to pulsed HDX experiments. Another promising development is the use of synchrotron X-rays to induce oxidation at specific sites within a protein for studying their solvent accessibility during folding.

The temperature dependence of activity and structure for the most prevalent mutant aldolase B associated with hereditary fructose intolerance

Hereditary fructose intolerance (HFI) is an autosomal recessive disorder in humans which is caused by mutations in the aldolase B gene. The most common HFI allele encodes an enzyme with an A149P substitution (AP-aldolase). A lysis method suitable for aggregation-prone proteins overexpressed in bacteria was developed. The enzyme's structure and function is investigated as a function of temperature. Near-UV CD shows a qualitative difference in tertiary structure, whereas far-UV CD shows no difference in overall secondary structure, although both show increased temperature sensitivity for AP-aldolase compared to that seen with wild-type aldolase B. AP-aldolase exists as a dimer at all temperatures tested, unlike the tetrameric wild-type enzyme, thus providing a possible explanation for the loss in thermostability. AP-aldolase has sixfold lower activity than wild type at 10 degrees C, which decreases substantially at higher temperature. In addition to disruptions at the catalytic center, the kinetic constants toward different substrates suggest that there is a disruption at the C1-phosphate-binding site, which is not sensitive to temperature. The implications of these structural alterations are discussed with regard to the HFI disease.

The equilibrium unfolding pathway of a (beta/alpha)8 barrel

The (beta/alpha)(8) barrel is the most commonly occurring fold among enzymes. A key step towards rationally engineering (beta/alpha)(8) barrel proteins is to understand their underlying structural organization and folding energetics. Using misincorporation proton-alkyl exchange (MPAX), a new tool for solution structural studies of large proteins, we have performed a native-state exchange analysis of the prototypical (beta/alpha)(8) barrel triosephosphate isomerase. Three cooperatively unfolding subdomains within the structure are identified, as well as two partially unfolded forms of the protein. The C-terminal domain coincides with domains reported to exist in four other (beta/alpha)(8) barrels, but the two N-terminal domains have not been observed previously. These partially unfolded forms may represent sequential intermediates on the folding pathway of triosephosphate isomerase. The methods reported here should be applicable to a variety of other biological problems involving protein conformational changes.

Structural features of interferon-gamma aggregation revealed by hydrogen exchange

Using hydrogen-deuterium exchange (HX) and electrospray ionization mass spectrometry, we have investigated the stability and structural changes of recombinant human interferon-gamma (IFN-gamma) during aggregation induced by guanidine hydrochloride (GdnHCl) and potassium thiocyanate. First, HX labeling was initiated after the amorphous aggregates were formed to probe the tertiary structure of the aggregated state. Second, labeling was performed at low protein concentrations to assess stability under aggregation prone conditions. In 1 M GdnHCl, the stability of IFN-gamma was greatly reduced and much less protection from HX in solution was observed. Exchange under these conditions was slower in helix C than in the rest of the protein. Aggregates formed in 1 M GdnHCl showed a HX pattern consistent with a partially unfolded state with an intact helix C. Although aggregates formed in 0.3 M KSCN exhibited a HX pattern similar to those formed in GdnHCl, the solution phase HX pattern in 0.3 M KSCN was surprisingly comparable to that of the native state. Varying the aggregation time before performing HX revealed that KSCN first precipitated native protein and then facilitated partial unfolding of the precipitated protein. These results show that helix C, which forms the hydrophobic core of the IFN-gamma dimer, is highly protected from HX under native conditions, is more stable in GdnHCl than the rest of the protein and remains intact in both GdnHCl- and KSCN-induced aggregates. This suggests that native-state HX patterns may presage regions of the protein susceptible to unfolding during aggregation.

High resolution, high-throughput amide deuterium exchange-mass spectrometry (DXMS) determination of protein binding site structure and dynamics: utility in pharmaceutical design

Mass spectrometry-based peptide amide deuterium exchange techniques have proven to be increasingly powerful tools with which protein structure and function can be studied, and are unparalleled in their ability to probe sub-molecular protein dynamics. Despite this promise, the methodology has remained labor-intensive and time consuming, with substantial limitations in comprehensiveness (the extent to which target protein sequence is covered with measurable peptide fragments) and resolution (the degree to which exchange measurements can be ascribed to particular amides). I have developed and integrated a number of improvements to these methodologies into an automated high throughput, high resolution system termed Deuterium Exchange Mass Spectrometry (DXMS). With DXMS, complete sequence coverage and single-amide (amino acid) resolution are now rapidly accomplished. DXMS is designed to work well with large proteins and when only small amounts of material are available for study. Studies can be performed upon a receptor-ligand pair as they exist on or within a living cell (in vivo) without prior purification, allowing effective in situ study of integral membrane protein receptors. We have ambitious initiatives underway to make DXMS widely available both for basic academic research studies and commercial drug discovery efforts. In this paper I present an overview of DXMS technology and highlight some of the benefits it will provide in drug discovery and basic proteomics research.

Identification of the interface of a large protein-protein complex using H/D exchange and Fourier transform ion cyclotron resonance mass spectrometry

An infrared multiphoton dissociation (IRMPD) spectrum, obtained by Fourier transform ion cyclotron resonance mass spectrometry (FTICRMS), was used to dissociate and to identify fragment ions from recombinant human interleukin-6 (IL-6; 21 KDa). The entire sequence was assigned by a single IRMPD experiment, and the observed fragment ions reflected the IL-6 secondary structure. This method was combined with H/D off-exchange to identify IL-6 and anti-human IL-6 mouse monoclonal antibody MH166 (150-kDa) binding sites in the IL-6 molecule. To facilitate the data analysis, the protein complex formation and the hydrogen exchange were performed with an immobilized antibody. Quenching of the hydrogen exchange reaction and collection of the deuterated IL-6 were performed by elution under acidic conditions to measure the mass spectrum directly. IL-6 was dissociated by using IRMPD, and the interface of IL-6 bound to anti-IL-6 antibody MH166 was determined to analyze the deuterium incorporation level of each fragment ion. Thus, two discontinuous regions, Leu 126-Lys 131 and Asp 160-Met 184, were identified as the antibody binding sites. These regions are adjacent to each other on the tertiary structures determined by NMR and X-ray analyses.

Unfolding of apomyoglobin helices by synchrotron radiolysis and mass spectrometry

The synchrotron X-ray protein radiolysis technique is based on a quantitative determination of the extent and the site of millisecond radiolytic oxidation of amino-acid side chains by mass spectrometry. The amino acids most susceptible to radiolytic oxidation are cysteine, methionine, phenylalanine, tyrosine, tryptophan, proline, histidine, and leucine. These residues serve as reactive markers within a protein structure that can be used to monitor changes in solvent accessibility during folding or as part of macromolecular interactions. To monitor the unfolding, the extent of radiolytic products of side chains of reactive amino acids is quantitatively measured by mass spectrometry as a function of the denaturant concentration following proteolysis. This approach provides site-specific unfolding isotherms for various segments of a protein without the use of mutation or labeling techniques. Application of this technique to the equilibrium urea unfolding of apomyoglobin at pH 7.8 has demonstrated the cooperative unfolding of helices A to C consistent with midpoints, DeltaG, and m values derived from fluorescence data. The G helix, in contrast, showed a local unfolding behavior. The similarity of the thermodynamic data derived by this synchrotron-based method for helix A (containing two oxidizable tryptophan residues) to that of the fluorescence data indicates that the limited oxidation of proteins by exposure to X-rays on millisecond timescales does not alter the structure of apomyglobin. This supports the viability of the method for the study of protein folding and the mapping of protein interaction sites.

Influence of the oligomeric state of yeast hexokinase isozymes on inactivation and unfolding by urea

The effect of the association-dissociation equilibrium on the urea-induced inactivation and unfolding of the yeast hexokinase isoforms, PI and PII, showed that these enzymes are more stable as dimers. For the monomeric PII, the inactivation and unfolding processes occurred in parallel. However, inactivation precedes the unfolding of monomeric PI or dimeric PI and PII. The unfolding transitions are biphasic for PI indicating stable intermediates, whereas for the PII isoform the unfolding occurs in a single step. Our data suggests that although PI and PII present a 78% identity in their amino acid sequences, they probably have distinct inactivation and unfolding by urea behavior.

Hydrogen-deuterium exchange as a probe of folding and assembly in viral capsids

The dynamics of proteins within large cellular assemblies are important in the molecular transformations that are required for macromolecular synthesis, transport, and metabolism. The capsid expansion (maturation) accompanying DNA packaging in the dsDNA bacteriophage P22 represents an experimentally accessible case of such a transformation. A novel method, based on hydrogen-deuterium exchange was devised to investigate the dynamics of capsid expansion. Mass spectrometric detection of deuterium incorporation allows for a sensitive and quantitative determination of hydrogen-deuterium exchange dynamics irrespective of the size of the assembly. Partial digestion of the exchanged protein with pepsin allows for region-specific assignment of the exchange. Procapsids and mature capsids were probed under native and slightly denaturing conditions. These experiments revealed regions that exhibit different degrees of flexibility in the procapsid and in the mature capsid. In addition, exchange and deuterium trapping during the process of expansion itself was observed and allowed for the identification of segments of the protein subunit that become buried or stabilized as a result of expansion. This approach may help to identify residues participating in macromolecular transformations and uncover novel patterns and hierarchies of interactions that determine functional movements within molecular machines.

Rate and equilibrium constants for protein unfolding and refolding determined by hydrogen exchange-mass spectrometry

Studies of protein unfolding and refolding may help us understand the more general problem of protein folding. Recent studies from this laboratory demonstrated that the unfolding and refolding of a large protein, rabbit muscle aldolase (M(r) 157 kDa), can be studied by combining amide hydrogen exchange and mass spectrometry. Results of these studies indicated that aldolase has three unfolding domains which likely unfold sequentially. Urea was used to increase the populations of partially unfolded states which were labeled with deuterium following a brief exposure to D(2)O. Electrospray ionization mass spectra of both the intact protein and its peptic fragments had multiple envelopes of isotope peaks from which the populations of unfolded forms were determined. The present study extends the previous investigations to include different urea concentrations and kinetic modeling of data taken as the system approaches equilibrium. Analysis of these results gives rate and equilibrium constants describing the unfolding and refolding processes characteristic of aldolase destabilized in urea. The change in solvent-accessible surface, which has been used as a reaction coordinate for protein folding, is estimated from the dependence of the equilibrium and rate constants on the concentration of urea.

Unfolding dynamics of a beta-sheet protein studied by mass spectrometry

The unfolding dynamics of cellular retinoic acid-binding protein I (CRABP I), an 18 kDa predominantly beta-sheet protein, were studied by monitoring the hydrogen-deuterium (H-D) exchange reaction under various solution conditions. A bimodal charge state distribution was observed when a denaturing agent was added to the protein aqueous solution. These two populations exhibit different kinetics of H-D exchange, with the high charge state ions undergoing very rapid isotope exchange, while the low charge state protein ions exchange cooperatively but at much slower rates. Transiently populated intermediate states were detected indirectly using hydrogen exchange measurement in aqueous solution at various pHs. At pH 2.5 and room temperature, three distinct populations of CRABP I ions exist over an extended period of time, each corresponding to a specific degree of backbone amide hydrogen atom protection. Mass spectral data are complementary to hydrogen exchange measurements by NMR, since the former samples a much faster time-scale of dynamic events in solution.

Hydrogen exchange demonstrates three domains in aldolase unfold sequentially

Rabbit muscle aldolase is a homotetramer in which the subunits have a classical alpha/beta-barrel structure and Mr 39,212 Da. We have previously reported that aldolase incubated in 3 M urea has three unfolding domains distinguished by their different unfolding rates. The unfolding rates of these domains were determined from isotope patterns in the mass spectra of peptic fragments derived from aldolase incubated in 3 M urea and pulse labeled in (2)H2O. The present study extends this investigation to more thoroughly characterize the structures of these unfolding intermediates. Mass spectra of intact monomers had four envelopes of isotope peaks corresponding to four structural forms of aldolase. Analysis of the present results suggests that these structural forms consist of native aldolase and three forms that have one to three domains unfolded. The molecular masses of these four structural forms indicate that there are 107 residues in each of the three unfolding domains of aldolase. Present results also show that aldolase remains a tetramer in 4 M urea, even though hydrogen exchange and circular dichroism indicate that it has lost most of its secondary and tertiary structure. The abundances of unfolded domains, which were determined from mass spectra of either intact aldolase or its peptic fragments, were used to determine the abundances of specific, partially unfolded forms of aldolase. Kinetic modeling of the abundances of these structures suggests that these structures are formed sequentially as aldolase unfolds in urea.

The hydrogen exchange core and protein folding

A database of hydrogen-deuterium exchange results has been compiled for proteins for which there are published rates of out-exchange in the native state, protection against exchange during folding, and out-exchange in partially folded forms. The question of whether the slow exchange core is the folding core (Woodward C, 1993, Trends Biochem Sci 18:359-360) is reexamined in a detailed comparison of the specific amide protons (NHs) and the elements of secondary structure on which they are located. For each pulsed exchange or competition experiment, probe NHs are shown explicitly; the large number and broad distribution of probe NHs support the validity of comparing out-exchange with pulsed-exchange/competition experiments. There is a strong tendency for the same elements of secondary structure to carry NHs most protected in the native state, NHs first protected during folding, and NHs most protected in partially folded species. There is not a one-to-one correspondence of individual NHs. Proteins for which there are published data for native state out-exchange and theta values are also reviewed. The elements of secondary structure containing the slowest exchanging NHs in native proteins tend to contain side chains with high theta values or be connected to a turn/loop with high theta values. A definition for a protein core is proposed, and the implications for protein folding are discussed. Apparently, during folding and in the native state, nonlocal interactions between core sequences are favored more than other possible nonlocal interactions. Other studies of partially folded bovine pancreatic trypsin inhibitor (Barbar E, Barany G, Woodward C, 1995, Biochemistry 34:11423-11434; Barber E, Hare M, Daragan V, Barany G, Woodward C, 1998, Biochemistry 37:7822-7833), suggest that developing cores have site-specific energy barriers between microstates, one disordered, and the other(s) more ordered.

Comparison of continuous and pulsed labeling amide hydrogen exchange/mass spectrometry for studies of protein dynamics

In contrast to the rigid structures portrayed by X-ray diffraction, proteins in solution display constant motion which leads to populations that are momentarily unfolded. To begin to understand protein dynamics, we must have experimental methods for determining rates of folding and unfolding, as well as for identifying structures of folding and unfolding intermediates. Amide hydrogen exchange has become an important tool for such measurements. When urea is used to stabilize unfolded forms of proteins, the refolding rates may become slower than the rates of isotope exchange. In such cases, the intermolecular distribution of deuterium among the entire population of molecules may become bimodal, giving rise to a bimodal distribution of isotope peaks in mass spectra of the protein or its peptic fragments. When the protein is exposed continuously to D2O, the relative intensities of the two envelopes of isotope peaks give an integrated account of populations participating in the folding/unfolding process. However, when the protein is exposed only briefly to D2O, the relative intensities of the two envelopes of isotope peaks give an instantaneous measure of the folded/unfolded populations. Application of these two labeling methods to a large protein, aldolase, is described along with a discussion of specific parameters required to optimize these experiments.

Matrix-assisted laser desorption ionization hydrogen/deuterium exchange studies to probe peptide conformational changes

Hydrogen/deuterium (H/D) exchange chemistry monitored by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry is used to study solution phase conformational changes of bradykinin, alpha-melanocyte stimulating hormone, and melittin as water is added to methanol-d4, acetonitrile, and isopropanol-d8 solutions. The results are interpreted in terms of a preference for the peptides to acquire more compact conformations in organic solvents as compared to the random conformations. Our interpretation is supported by circular dichroism spectra of the peptides in the same solvent systems and by previously published structural data for the peptides. These results demonstrate the utility of MALDI-TOF as a method to monitor the H/D exchange chemistry of peptides and investigations of solution-phase conformations of biomolecules.

Applications of mass spectrometry to signal transduction

Advances in mass spectrometry instrumentation, protocols for sample handling, and computational methods provide powerful new approaches to solving problems in analytical biochemistry. This review summarizes recent work illustrating ways in which mass spectrometry has been used to address questions relevant to signal transduction. Rather than encompass all of the instruments or methodologies that might be brought to bear on these problems, we present an overview of commonly used techniques, promising new methodologies, and some applications.

Electrospray-assisted modification of proteins: a radical probe of protein structure

A new approach is described to probe the structure of proteins through their reactivity with oxygen-containing radicals. Radical-induced oxidative modification of proteins is achieved within an electrospray ion source using oxygen as a reactive nebulizer gas at high needle voltages. This method facilitates the rapid oxidation of proteins as the molecules emerge from the electrospray needle tip. Electrospray mass spectra of both ubiquitin and lysozyme reveal that over 50% of the protein can be modified under these conditions. The radical-induced oxidative modification of amino acid side chains is correlated with their solvent accessibility to obtain information on a protein's higher-order structure. The oxidation sites in hen lysozyme have been identified by proteolysis of the condensed protein solution and tandem mass spectrometry (MS/MS). Oxidation of tryptophan at positions 62 and 123 occurs exclusively over all other tryptophan residues, consistent with the relative solvent accessibilities of the residue side chains based on the NMR structure of the protein. Radical-induced oxidative modification of cysteine (Cys), methionine (Met), tryptophan (Trp), phenylalanine (Phe), tyrosine (Tyr), proline (Pro), histidine (His), and leucine (Leu) residues is also reported, providing sufficient reactive markers to span a protein sequence. This facile oxidation process could be applied to investigate the molecular mechanism by which reactive oxygen species interact with a particular protein domain as a means to investigate the onset of certain diseases.

Electrospray-assisted modification of proteins: a radical probe of protein structure

A new approach is described to probe the structure of proteins through their reactivity with oxygen-containing radicals. Radical-induced oxidative modification of proteins is achieved within an electrospray ion source using oxygen as a reactive nebulizer gas at high needle voltages. This method facilitates the rapid oxidation of proteins as the molecules emerge from the electrospray needle tip. Electrospray mass spectra of both ubiquitin and lysozyme reveal that over 50% of the protein can be modified under these conditions. The radical-induced oxidative modification of amino acid side chains is correlated with their solvent accessibility to obtain information on a protein's higher-order structure. The oxidation sites in hen lysozyme have been identified by proteolysis of the condensed protein solution and tandem mass spectrometry (MS/MS). Oxidation of tryptophan at positions 62 and 123 occurs exclusively over all other tryptophan residues, consistent with the relative solvent accessibilities of the residue side chains based on the NMR structure of the protein. Radical-induced oxidative modification of cysteine (Cys), methionine (Met), tryptophan (Trp), phenylalanine (Phe), tyrosine (Tyr), proline (Pro), histidine (His), and leucine (Leu) residues is also reported, providing sufficient reactive markers to span a protein sequence. This facile oxidation process could be applied to investigate the molecular mechanism by which reactive oxygen species interact with a particular protein domain as a means to investigate the onset of certain diseases.