Local flexibility facilitates oxidization of buried methionine residues

In proteins, all amino acid residues are susceptible to oxidation by various reactive oxygen species (ROS), with methionine and cysteine residues being particularly sensitive to oxidation. Methionine oxidation is known to lead to destabilization and inactivation of proteins, and oxidatively modified proteins can accumulate during aging, oxidative stress, and in various age-related diseases. Although the efficiency of a given methionine oxidation can depend on its solvent accessibility (evaluated from a protein structure as the accessible surface area of the corresponding methionine residue), many experimental results on oxidation rate and oxidation sites cannot be unequivocally explained by the methionine solvent accessible surface area alone. In order to explore other possible mechanisms, we analyzed a set of seventy-one oxidized methionines contained in thirty-one proteins by various bioinformatics tools. In which, 41% of the methionines are exposed, 15% are buried but with various degree of flexibility, and the rest 44% are buried and structured. Buried but highly flexible methionines can be oxidized. Buried and less flexible methionines can acquire additional local structural flexibility from flanking regions to facilitate the oxidation. Oxidation of buried and structured methionine can also be promoted by the oxidation of neighboring methionine that is more exposed and/or flexible. Our data are consistent with the hypothesis that protein structural flexibility represents another important factor favoring the oxidation process.     

Site-specific methionine oxidation in calmodulin affects structural integrity and interaction with Ca2+/calmodulin-dependent protein kinase II

Methionine oxidation in the ubiquitous calcium signaling protein calmodulin (CaM) is known to disrupt downstream signaling and target CaM for proteasomal degradation. The susceptibility of CaM to oxidation in the different conformations that are sampled during calcium signaling is currently not well defined. Using an integrative mass spectrometry (MS) approach, applying both native MS and LC/MS/MS, we unravel molecular details of CaM methionine oxidation in the context of its interaction with the Ca(2+)/CaM-dependent protein kinase II (CaMKII). Sensitivity to methionine oxidation in CaM was found to vary according to the conformational state. Three methionine residues (Met71, 72, 145) show increased reactivity in calcium-saturated CaM (holo-CaM) compared to calcium-free CaM (apo-CaM), which has important consequences for oxidation-targeted proteasomal degradation. In addition, all four methionines in the C-terminal lobe (Met109, 124, 144 and 145) are found to be protected from oxidation in a peptide-based model of the CaMKII-bound conformation (cbp-CaM). We furthermore demonstrate that the oxidation of Met144 and 145 inhibits the interaction of CaM with CaMKII. cbp-CaM, in contrast to apo- and holo-CaM, maintains its ability to bind CaMKII under simulated conditions of oxidative stress and is also protected from oxidation-induced unfolding. Thus, we show that the susceptibility towards oxidation of specific residues in CaM is tightly linked to its signaling state and conformation, which has direct implications for calcium/CaM-CaMKII related signaling.     

Loss of conformational stability in calmodulin upon methionine oxidation.

We have used electrospray ionization mass spectrometry (ESI-MS), circular dichroism (CD), and fluorescence spectroscopy to investigate the secondary and tertiary structural consequences that result from oxidative modification of methionine residues in wheat germ calmodulin (CaM), and prevent activation of the plasma membrane Ca-ATPase. Using ESI-MS, we have measured rates of modification and molecular mass distributions of oxidatively modified CaM species (CaMox) resulting from exposure to H2O2. From these rates, we find that oxidative modification of methionine to the corresponding methionine sulfoxide does not predispose CaM to further oxidative modification. These results indicate that methionine oxidation results in no large-scale alterations in the tertiary structure of CaMox, because the rates of oxidative modification of individual methionines are directly related to their solvent exposure. Likewise, CD measurements indicate that methionine oxidation results in little change in the apparent alpha-helical content at 28 degrees C, and only a small (0.3 +/- 0.1 kcal mol(-1)) decrease in thermal stability, suggesting the disruption of a limited number of specific noncovalent interactions. Fluorescence lifetime, anisotropy, and quenching measurements of N-(1-pyrenyl)-maleimide (PMal) covalently bound to Cys26 indicate local structural changes around PMal in the amino-terminal domain in response to oxidative modification of methionine residues in the carboxyl-terminal domain. Because the opposing globular domains remain spatially distant in both native and oxidatively modified CaM, the oxidative modification of methionines in the carboxyl-terminal domain are suggested to modify the conformation of the amino-terminal domain through alterations in the structural features involving the interdomain central helix. The structural basis for the linkage between oxidative modification and these global conformational changes is discussed in terms of possible alterations in specific noncovalent interactions that have previously been suggested to stabilize the central helix in CaM.     

High-affinity and cooperative binding of oxidized calmodulin by methionine sulfoxide reductase

Methionines can play an important role in modulating protein-protein interactions associated with intracellular signaling, and their reversible oxidation to form methionine sulfoxides [Met(O)] in calmodulin (CaM) and other signaling proteins has been suggested to couple cellular redox changes to protein functional changes through the action of methionine sulfoxide reductases (Msr). Prior measurements indicate the full recovery of target protein activation upon the stereospecific reduction of oxidized CaM by MsrA, where the formation of the S-stereoisomer of Met(O) selectively inhibits the CaM-dependent activation of the Ca-ATPase. However, the physiological substrates of MsrA remain unclear, as neither the binding specificities nor affinities of protein targets have been measured. To assess the specificity of binding and its possible importance in the maintenance of CaM function, we have measured the kinetics of repair and the binding affinity between oxidized CaM and MsrA. Reduction of Met(O) in fully oxidized CaM by MsrA is sensitive to the protein fold, as repair of the intact protein is incomplete, with >6 Met(O) remaining in each CaM following MsrA reduction. In contrast, following proteolytic digestion, MsrA is able to fully reduce one-half of the oxidized methionines, indicating that surface-accessible Met(O) within folded proteins need not be substrates for MsrA repair. Mutation of the active site (i.e., C72S) in MsrA permitted equilibrium-binding measurements using both ensemble and single-molecule fluorescence correlation spectroscopy measurements. We observe cooperative binding of two MsrA to each CaMox with an apparent affinity (K = 70 +/- 10 nM) that is 3 orders of magnitude greater than the Michaelis constant (KM = 68 +/- 4 microM). The high-affinity and cooperative interaction between MsrA and CaMox suggests an important regulatory role of MsrA in the binding and reduction of Met(O) in functionally sensitive proteins, such that multiple MsrA proteins are recruited to simultaneously bind and reduce Met(O) in highly oxidized proteins. Given the suggested role of Met(O) in modulating reversible binding interactions between proteins associated with cellular signaling, these results indicate an ability of MsrA to selectively reduce Met(O) within highly surface-accessible sequences to maintain cellular function as part of an adaptive response to oxidative stress.     

Redox modulation of cellular signaling and metabolism through reversible oxidation of methionine sensors in calcium regulatory proteins

Adaptive responses associated with environmental stressors are critical to cell survival. Under conditions when cellular redox and antioxidant defenses are overwhelmed, the selective oxidation of critical methionines within selected protein sensors functions to down-regulate energy metabolism and the further generation of reactive oxygen species (ROS). Mechanistically, these functional changes within protein sensors take advantage of the helix-breaking character of methionine sulfoxide. The sensitivity of several calcium regulatory proteins to oxidative modification provides cellular sensors that link oxidative stress to cellular response and recovery. Calmodulin (CaM) is one such critical calcium regulatory protein, which is functionally sensitive to methionine oxidation. Helix destabilization resulting from the oxidation of either Met(144) or Met(145) results in the nonproductive association between CaM and target proteins. The ability of oxidized CaM to stabilize its target proteins in an inhibited state with an affinity similar to that of native (unoxidized) CaM permits this central regulatory protein to function as a cellular rheostat that down-regulates energy metabolism in response to oxidative stress. Likewise, oxidation of a methionine within a critical switch region of the regulatory protein phospholamban is expected to destabilize the phosphorylation-dependent helix formation necessary for the release of enzyme inhibition, resulting in a down-regulation of the Ca-ATPase in response to beta-adrenergic signaling in the heart. We suggest that under acute conditions, such as inflammation or ischemia, these types of mechanisms ensure minimal nonspecific cellular damage, allowing for rapid restoration of cellular function through repair of oxidized methionines by methionine sulfoxide reductases and degradation pathways after restoration of normal cellular redox conditions.     

Comparing the effect on protein stability of methionine oxidation versus mutagenesis: steps toward engineering oxidative resistance in proteins.

The biological activity of some proteins is known to be sensitive to oxidative damage caused by a variety of oxidants. The model protein staphylococcal nuclease was used to explore the effect on protein structural stability of oxidizing methionine to the sulfoxide form. These effects were compared with the effects of substituting methionines with isoleucine and leucine, a potential strategy for stabilizing proteins against oxidative damage. Wild-type nuclease and various mutants were oxidized with hydrogen peroxide. Stabilities of both oxidized and unoxidized proteins were determined by guanidine hydrochloride denaturation. Oxidation destabilized the wild-type protein by over 4 kcal/mol. This large loss of stability supports the idea that in some cases loss of biological activity is linked to disruption of the protein native state. Comparison of mutant protein's stability losses upon oxidation showed that methionines 65 and 98 had a much greater destabilizing effect when oxidized than methionines 26 or 32. While substitution of methionine 98 carried as great an energetic penalty as oxidation, substitution at position 65 was less disruptive than oxidation. Thus a simple substitution mutagenesis strategy to protect a protein against oxidative destabilization is practical for some methionine residues.     

In vitro methionine oxidation of Escherichia coli-derived human stem cell factor: effects on the molecular structure, biological activity, and dimerization.

The effect of oxidation of the methionine residues of Escherichia coli-derived recombinant human stem cell factor (huSCF) to methionine sulfoxide on the structure and activity of SCF was examined. Oxidation was performed using hydrogen peroxide under acidic conditions (pH 5.0). The kinetics of oxidation of the individual methionine residues was determined by quantitation of oxidized and unoxidized methionine-containing peptides, using RP-HPLC of Asp-N endoproteinase digests. The initial oxidation rates for Met159, Met-1, Met27, Met36, and Met48 were 0.11 min-1, 0.098 min-1, 0.033 min-1, 0.0063 min-1, and 0.00035 min-1, respectively, when SCF was incubated in 0.5% H2O2 at room temperature. Although oxidation of these methionines does not affect the secondary structure of SCF, the oxidation of Met36 and Met48 affects the local structure as indicated by CD and fluorescence spectroscopy. The 295-nm Trp peak in the near-UV CD is decreased upon oxidation of Met36, and lost completely following the oxidation of Met48, indicating that the Trp44 environment is becoming significantly less rigid than it is in native SCF. Consistent with this result, the fluorescence spectra revealed that Trp44 becomes more solvent exposed as the methionines are oxidized, with the hydrophobicity of the Trp44 environment decreasing significantly. The oxidations of Met36 and Met48 decrease biological activity by 40% and 60%, respectively, while increasing the dissociation rate constant of SCF dimer by two- and threefold. These results imply that the oxidation of Met36 and Met48 affects SCF dimerization and tertiary structure, and decreases biological activity.     

Diastereoselective protein methionine oxidation by reactive oxygen species and diastereoselective repair by methionine sulfoxide reductase

Recent studies have shown that the "calcium-sensor" protein calmodulin (CaM) suffers an age-dependent oxidation of methionine (Met) to methionine sulfoxide (MetSO) in vivo. However, MetSO did not accumulate on the Met residues that show the highest solvent-exposure. Hence, the pattern of Met oxidation in vivo may give hints as to which reactive oxygen species and oxidation mechanisms participate in the oxidation of this important protein. Here, we have exposed CaM under a series of different reaction conditions (pH, [Ca(2+)], [KCl]) to various biologically relevant reactive oxygen species and oxidizing systems (peroxides, HOCl, peroxynitrite, singlet oxygen, metal-catalyzed oxidation, and peroxidase-catalyzed oxidation) to investigate whether one of these systems would lead to an oxidation pattern of CaM similar to that observed in vivo. However, generally, these oxidizing conditions led to a preferred or exclusive oxidation of the C-terminal Met residues, in contrast to the oxidation pattern of CaM observed in vivo. Hence, none of the employed oxidizing conditions was able to mimic the age-dependent oxidation of CaM in vivo, indicating that other, yet unidentified oxidation mechanisms may be important in vivo. Some oxidizing species showed a quite-remarkable diastereoselectivity for the formation of either L-Met-D-SO or L-Met-L-SO. Diastereoselectivity was dependent on the nature of the oxidizing species but was less a function of the location of the target Met residue in the protein. In contrast, diastereoselective reduction of L-Met-D-SO by protein methionine sulfoxide reductase (pMSR) was efficient regardless of the position of the L-Met-D-SO residue in the protein and the presence or absence of calcium. With only the L-Met-D-SO diastereomer being a substrate for pMSR, any preferred formation of L-Met-L-SO in vivo may cause the accumulation of MetSO unless the oxidized protein is substrate for (accelerated) protein turnover.     

Mediating molecular recognition by methionine oxidation: conformational switching by oxidation of methionine in the carboxyl-terminal domain of calmodulin

The C-terminus of calmodulin (CaM) functions as a sensor of oxidative stress, with oxidation of methionine 144 and 145 inducing a nonproductive association of the oxidized CaM with the plasma membrane Ca(2+)-ATPase (PMCA) and other target proteins to downregulate cellular metabolism. To better understand the structural underpinnings and mechanism of this switch, we have engineered a CaM mutant (CaM-L7) that permits the site-specific oxidation of M144 and M145, and we have used NMR spectroscopy to identify structural changes in CaM and CaM-L7 and changes in the interactions between CaM-L7 and the CaM-binding sequence of the PMCA (C28W) due to methionine oxidation. In CaM and CaM-L7, methionine oxidation results in nominal secondary structural changes, but chemical shift changes and line broadening in NMR spectra indicate significant tertiary structural changes. For CaM-L7 bound to C28W, main chain and side chain chemical shift perturbations indicate that oxidation of M144 and M145 leads to large tertiary structural changes in the C-terminal hydrophobic pocket involving residues that comprise the interface with C28W. Smaller changes in the N-terminal domain also involving residues that interact with C28W are observed, as are changes in the central linker region. At the C-terminal helix, (1)H(alpha), (13)C(alpha), and (13)CO chemical shift changes indicate decreased helical character, with a complete loss of helicity for M144 and M145. Using (13)C-filtered, (13)C-edited NMR experiments, dramatic changes in intermolecular contacts between residues in the C-terminal domain of CaM-L7 and C28W accompany oxidation of M144 and M145, with an essentially complete loss of contacts between C28W and M144 and M145. We propose that the inability of CaM to fully activate the PMCA after methionine oxidation originates in a reduced helical propensity for M144 and M145, and results primarily from a global rearrangement of the tertiary structure of the C-terminal globular domain that substantially alters the interaction of this domain with the PMCA.     

Redox proteomics of protein-bound methionine oxidation

We here present a new method to measure the degree of protein-bound methionine sulfoxide formation at a proteome-wide scale. In human Jurkat cells that were stressed with hydrogen peroxide, over 2000 oxidation-sensitive methionines in more than 1600 different proteins were mapped and their extent of oxidation was quantified. Meta-analysis of the sequences surrounding the oxidized methionine residues revealed a high preference for neighboring polar residues. Using synthetic methionine sulfoxide containing peptides designed according to the observed sequence preferences in the oxidized Jurkat proteome, we discovered that the substrate specificity of the cellular methionine sulfoxide reductases is a major determinant for the steady-state of methionine oxidation. This was supported by a structural modeling of the MsrA catalytic center. Finally, we applied our method onto a serum proteome from a mouse sepsis model and identified 35 in vivo methionine oxidation events in 27 different proteins.     

Tertiary structural rearrangements upon oxidation of Methionine145 in calmodulin promotes targeted proteasomal degradation

The selectivity underlying the recognition of oxidized calmodulin (CaM) by the 20S proteasome in complex with Hsp90 was identified using mass spectrometry. We find that degradation of oxidized CaM (CaMox) occurs in a multistep process, which involves an initial cleavage that releases a large N-terminal fragment (A1-F92) as well as multiple smaller carboxyl-terminus peptides ranging from 17 to 26 amino acids in length. These latter small peptides are enriched in methionine sulfoxides (MetO), suggesting a preferential degradation around MetO within the carboxyl-terminal domain. To confirm the specificity of CaMox degradation and to identify the structural signals underlying the preferential recognition and degradation by the proteasome/Hsp90, we have investigated how the oxidation of individual methionines affect the degradation of CaM using mutants in which all but selected methionines in CaM were substituted with leucines. Substitution of all methionines with leucines except Met144 and Met145 has no detectable effect on the structure of CaM, permitting a determination of how site-specific substitutions and the oxidation of Met144 and Met145 affects the recognition and degradation of CaM by the proteasome/Hsp90. Comparable rates of degradation are observed upon the selective oxidation of Met144 and Met145 in CaM-L7 relative to that observed upon oxidation of all nine methionines in wild-type CaM. Substitution of leucines for either Met144 or Met145 promotes a limited recognition and degradation by the proteasome that correlates with decreases in the helical content of CaM. The specific oxidation of Met144 has little effect on rates of proteolytic degradation by the proteasome/Hsp90 or the structure of CaM. In contrast, the specific oxidation of Met145 results in both large increases in the rate of degradation by the proteasome/Hsp90 and significant circular dichroic spectral shape changes that are indicative of changes in tertiary rather than secondary structure. Thus, tertiary structural changes resulting from the site-specific oxidation of a single methionine (i.e., Met145) promote the degradation of CaM by the proteasome/Hsp90, suggesting a mechanism to regulate cellular metabolism through the targeted modulation of CaM abundance in response to oxidative stress.     

Oxidation of methionine residues in antithrombin. Effects on biological activity and heparin binding

Commercially available human plasma-derived preparations of the serine protease inhibitor antithrombin (AT) were shown to contain low levels of oxidation, and we sought to determine whether oxidation might be a means of regulating the protein's inhibitory activity. A recombinant form of AT, with similarly low levels of oxidation as purified, was treated with hydrogen peroxide in order to study the effect of oxidation, specifically methionine oxidation, on the biochemical properties of this protein. AT contains two adjacent methionine residues near the reactive site loop cleaved by thrombin (Met314 and Met315) and two exposed methionines that border on the heparin binding region of AT (Met17 and Met20). In forced oxidations with hydrogen peroxide, the methionines at 314 and 315 were found to be the most susceptible to oxidation, but their oxidation did not affect either thrombin-inhibitory activity or heparin binding. Methionines at positions 17 and 20 were significantly oxidized only at higher concentrations of peroxide, at which point heparin affinity was decreased. However at saturating heparin concentrations, activity was only marginally decreased for these highly oxidized samples of AT. Structural studies indicate that highly oxidized AT is less able to undergo the complete conformational change induced by heparin, most probably due to oxidation of Met17. Since this does not occur in less oxidized, and presumably more physiologically relevant, forms of AT such as those found in plasma preparations, oxidation does not appear to be a means of controlling AT activity.     

Calorimetry and mass spectrometry study of oxidized calmodulin interaction with target and differential repair by methionine sulfoxide reductases

Calmodulin is known to be a target for oxidation, which leads to conversion of methionine residues to methionine sulfoxides. Previously, we reported that both methionine sulfoxide reductases MsrA and MsrB were able to reduce methionine sulfoxide residues in oxidized calmodulin. In the present study, we have made use of the interaction between calmodulin and RS20, a peptide model for calmodulin targets, to probe the structural consequences of oxidation and mode of repair both by MsrA and MsrB. Isothermal titration calorimetry and differential scanning calorimetry showed that oxidized calmodulin interacts with RS20 via its C-terminal domain only, resulting in a non-productive complex. As shown by spectrofluorometry, oxidized calmodulin treated with MsrA exhibited native binding affinity for RS20. In contrast, MsrB-treatment of oxidized calmodulin resulted in 10-fold reduced affinity. Mass spectrometry revealed that the sulfoxide derivative of methionine residue 124 was differentially repaired by MsrA and MsrB. This provided a basis for rationalizing the difference in binding affinities of oxidized calmodulin reported above, since Met124 residue had been shown to be critical for interaction with some targets. This study provides the first evidence that in an oxidized polypeptide chain MetSO residues might be differentially repaired by the two Msr enzymes.     

Tryptophan fluorescence of calmodulin binding domain peptides interacting with calmodulin containing unnatural methionine analogues

The interactions between the abundant methionine residues of the calcium regulatory protein calmodulin (CaM) and several of its binding targets were probed using fluorescence spectroscopy. Tryptophan steady-state fluorescence from peptides encompassing the CaM-binding domains of the target proteins myosin light chain kinase (MLCK), cyclic nucleotide phosphodiesterase (PDE) and caldesmon site A and B (CaD A, CaD B), and the model peptide melittin showed Ca(2+)-dependent blue-shifts in their maximum emission wavelength when complexed with wild-type CaM. Blue-shifts were also observed for complexes in which the CaM methionine residues were replaced by selenomethionine, norleucine and ethionine, and when a quadruple methionine to leucine C-terminal mutant of CaM was studied. Quenching of the tryptophan fluorescence intensity was observed with selenomethionine, but not with norleucine or ethionine substituted protein. Fluorescence quenching studies with added potassium iodide (KI) demonstrate that the non-native proteins limit the solvent accessibility of the Trp in the MLCK peptide to levels close to that of the wild-type CaM-MLCK interaction. Our results show that the methionine residues from CaM are highly sensitive to the target peptide in question, confirming the importance of their role in binding interactions. In addition, we provide evidence that the nature of binding in the CaM-CaD B complex is unique compared with the other complexes studied, as the Trp residue of this peptide remains partially solvent exposed upon binding to CaM.     

Diastereoselective reduction of protein-bound methionine sulfoxide by methionine sulfoxide reductase.

Methionine sulfoxide (MetSO) in calmodulin (CaM) was previously shown to be a substrate for bovine liver peptide methionine sulfoxide reductase (pMSR, EC 1.8.4.6), which can partially recover protein structure and function of oxidized CaM in vitro. Here, we report for the first time that pMSR selectively reduces the D-sulfoxide diastereomer of CaM-bound L-MetSO (L-Met-D-SO). After exhaustive reduction by pMSR, the ratio of L-Met-D-SO to L-Met-L-SO decreased to about 1:25 for hydrogen peroxide-oxidized CaM, and to about 1:10 for free MetSO. The accumulation of MetSO upon oxidative stress and aging in vivo may be related to incomplete, diastereoselective, repair by pMSR.     

Stereospecific oxidation of calmodulin by methionine sulfoxide reductase A

Methionine sulfoxide reductase A has long been known to reduce S-methionine sulfoxide, both as a free amino acid and within proteins. Recently the enzyme was shown to be bidirectional, capable of oxidizing free methionine and methionine in proteins to S-methionine sulfoxide. A feasible mechanism for controlling the directionality has been proposed, raising the possibility that reversible oxidation and reduction of methionine residues within proteins is a redox-based mechanism for cellular regulation. We undertook studies aimed at identifying proteins that are subject to site-specific, stereospecific oxidation and reduction of methionine residues. We found that calmodulin, which has nine methionine residues, is such a substrate for methionine sulfoxide reductase A. When calmodulin is in its calcium-bound form, Met77 is oxidized to S-methionine sulfoxide by methionine sulfoxide reductase A. When methionine sulfoxide reductase A operates in the reducing direction, the oxidized calmodulin is fully reduced back to its native form. We conclude that reversible covalent modification of Met77 may regulate the interaction of calmodulin with one or more of its many targets.     

Identification of oxidized methionine residues in peptides containing two methionine residues by derivatization and matrix-assisted laser desorption/ionization mass spectrometry

Oxidation of methionine residues in peptides and proteins occurs in vivo or may be an artifact resulting from purification steps. We present a three step method for the localization of methionine sulfoxides in peptides with two methionine residues. In the first step, the N-terminus as well as other reactive side chain functions are blocked by acetylation. The resulting protected peptides are cleaved by cyanogen bromide. The cleavage does not occur at methionine sulfoxide but only at reduced methionine residues forming new amino termini. The newly formed amino group is then derivatized with a bromine containing compound in the last step of the procedure. The resulting peptide can easily be identified by matrix-assisted laser desorption/ionization-time of flight mass spectrometry using both the characteristic isotope pattern of the halogen and the metastable loss of methanesulfenic acid from oxidized residues. This procedure allows the unequivocal localization of oxidized methionines even in complex peptide mixtures.     

Oxidation of either methionine 351 or methionine 358 in alpha 1-antitrypsin causes loss of anti-neutrophil elastase activity

Hydrogen peroxide is a component of cigarette smoke known to be essential for inactivation of alpha(1)-antitrypsin, the primary inhibitor of neutrophil elastase. To establish the molecular basis of the inactivation of alpha(1)-antitrypsin, we determined the sites oxidized by hydrogen peroxide. Two of the nine methionines were particularly susceptible to oxidation. One was methionine 358, whose oxidation was known to cause loss of anti-elastase activity. The other, methionine 351, was as susceptible to oxidation as methionine 358. Its oxidation also resulted in loss of anti-elastase activity, an effect not previously recognized. The equal susceptibility of methionine 358 and methionine 351 to oxidation was confirmed by mass spectrometry. To verify this finding, we produced recombinant alpha(1)-antitrypsins in which one or both of the susceptible methionines were mutated to valine. M351V and M358V were not as rapidly inactivated as wild-type alpha1-antitrypsin, but only the double mutant M351V/M358V was markedly resistant to oxidative inactivation. We suggest that inactivation of alpha(1)-antitrypsin by oxidation of either methionine 351 or 358 provides a mechanism for regulation of its activity at sites of inflammation.     

Oxidation of methionine in proteins: roles in antioxidant defense and cellular regulation

The roles of methionine residues in proteins have not been well defined, but a review of available studies leads to the conclusion that methionine, like cysteine, functions as an antioxidant and as a key component of a system for regulation of cellular metabolism. Methionine is readily oxidized to methionine sulfoxide by many reactive species. The oxidation of surface exposed methionines thus serves to protect other functionally essential residues from oxidative damage. Methionine sulfoxide reductases have the potential to reduce the residue back to methionine, increasing the scavenging efficiency of the system. Reversible covalent modification of amino acids in proteins provides the mechanistic basis for most systems of cellular regulation. Interconversion of methionine and methionine sulfoxide can function to regulate the biological activity of proteins, through alteration in catalytic efficiency and through modulation of the surface hydrophobicity of the protein.     

Identification of oxidized methionine sites in erythrocyte membrane protein by liquid chromatography/electrospray ionization mass spectrometry peptide mapping

In this study, we used peptide mapping combined with liquid chromatography/electrospray ionization mass spectrometry (LC/ESI MS) to examine the methionine oxidation of band 3 of erythrocyte membrane protein. Initially, we identified the methionine sites oxidized by chloramine T (N-chloro-p-toluenesulfoamide), a hydrophilic reagent. There were three oxidized methionines (Met 559, Met 741, and Met 909) in band 3, and these methionines were located in a hydrophilic region determined by previous topological studies of band 3. In addition, we found that C12E8, a polyoxyethylene detergent, leads to the oxidation of methionines in a transmembrane segment in band 3, and this oxidation occurs in a C12E8 preincubation time-dependent manner. In a previous study, it was found that peroxides accumulate in a polyoxyethylene detergent. Thus, our method enabled the direct and quantitative detection of protein damage due to detergent peroxides. Furthermore, we examined methionine oxidation in the presence of 4,4'-dinitrostilbene-2,2'-disulfonic acid (DNDS) or diethyl pyrocarbonate (DEPC), which induced either an outward or an inward conformation in band 3, respectively. Our results indicated that the location of Met 741 was associated with the band 3 conformation induced by band 3-mediated anion transport. In conclusion, we found that methionine oxidation can be applied to examine membrane protein structures as follows: (1) for topological studies of membrane proteins, (2) for assessing the quality of proteins in detergent solubilization studies, and (3) for the detection of conformational changes in membrane proteins.