Determination of methionine sulfoxide in proteins: comparison of a gas-chromatographic and electrophoretic method

Two methods for the determination of methionine in proteins have been used to estimate the extent of methionine sulfoxide obtained upon exposure of proteins to oxidizing agents. Both methods are based on prior treatment with cyanogen bromide, which attacks methionines (but not the sulfoxide derivative) with the resultant formation of methyl thiocyanate and peptides. The amount of methyl thiocyanate is determined quantitatively by gas chromatography, while the number of peptides is ascertained by SDS-polyacrylamide gel electrophoresis. The gas chromatographic estimate of CH3SCN offers an accurate and precise method (down to nanogram values) for the quantitative determination of methionine sulfoxide in proteins. Due to its simplicity and the use of low-cost equipment, the electrophoretic method appears to be a valuable complement to the gas chromatographic method, and the two methods in conjunction provide novel results.     

Chromatographic separation of methionine,methionine sulphoxide,methionine sulphone,and their products of oral microbial metabolism

The metabolic pathways of methionine sulphoxide and methionine sulphone were investigated employing a combination of gas chromatography, thin-layer chromatography, paper chromatography, and radioactive methods of analyses. Gas chromatographic analysis demonstrated that methionine, methionine sulphoxide, and methionine sulphone all yielded qualitatively similar volatile sulphur compounds, namely, methyl mercaptan, dimethyl disulphide, and small amounts of dimethyl sulphide. The study indicated that the principal pathway of methionine sulphoxide and methionine sulphone metabolism is mediated via methionine which gives rise to methyl mercaptan, part of which is oxidized to dimethyl disulphide. Whereas methionine sulphoxide was readily reduced to methionine, the reduction of methionine sulphone proceeded at a considerably slower rate.     

CNBr/Formic Acid Reactions of Methionine- and Trifluoromethionine-Containing Lambda Lysozyme: Probing Chemical and Positional Reactivity and Formylation Side Reactions by Mass Spectrometry

The cyanogen bromide (CNBr)/formic acid cleavage reactions of wild-type and trifluoromethionine (TFM)-containing recombinant lambda lysozyme were studied utilizing ESI and MALDI mass spectrometry. Detailed analysis of the mass spectra of reverse-phase HPLC-purified cleavage fragments produced from treatment of the wild-type and labeled proteins with CNBr indicated cleavage solely of methionyl peptide bonds with no observation of cleavage at TFM. N-Acetyl-TFM was also found to be resistant to reaction with CNBr, in contrast to N-acetyl-methionine. The analysis also indicated differential reactivity among the three methionine positions in the wild-type enzyme. Additionally, formylation of intact enzyme as well as peptide fragments were observed and characterized and indicated that serine, threonine, as well as C-terminal homoserine side chains are partially formylated under standard cleavage protocols.     

Sorbitol dehydrogenase. The primary structure of the sheep-liver enzyme

The first primary structure for a sorbitol dehydrogenase has been determined by analysis of the tetrameric enzyme from sheep liver. The [14C]carboxymethylated protein was cleaved with CNBr and proteolytic enzymes. Peptides were purified by several methods, often utilizing exclusion chromatography for pre-fractionation and reverse-phase high-performance liquid chromatography for final purification. Different methods of sequence analysis complemented each other, mainly the manual dimethylaminoazobenzene isothiocyanate method and and the use of liquid-phase sequencer degradations. All eight major CNBr fragments were purified and form the basis of the work. Three minor CNBr fragments derived from an acid cleavage and from a partly resistant Met-Thr bond were also obtained, as well as evidence for a contaminating homologous polypeptide. Most of the tryptic peptides were purified, including all with methionine residues, thus overlapping the CNBr fragments. Combined, all data permit the deduction of a 354-residue amino acid sequence for the polypeptide chain of sorbitol dehydrogenase. The N terminus is acyl-blocked, the C terminus is formed by a proline residue, tryptophan is the least common residue (two, at positions 50 and 301) and there are 10 cysteine residues, including the residue previously shown to be especially reactive (at position 43). Similarities to 'long' alcohol dehydrogenases have functional implications.     

The primary structure of Lactobacillus casei thymidylate synthetase. I. The isolation of cyanogen bromide peptides 1 through 5 and the complete amino acid sequence of CNBr 1, 2, 3, and 5.

Thymidylate synthetase from Lactobacillus casei was S-carboxymethylated and degraded by treatment with cyanogen bromide. Although the protein contains 6 methionine residues, only 5 cyanogen bromide peptides were obtained due to the presence of 1 methionine on the NH2 terminus and another adjacent to a threonine residue which was resistant to cleavage. The peptides were isolated by differential extraction, first with ammonium acetate, then pyridine acetate, and finally the residue was solubilized with 50% acetic acid. Each peptide was further purified to homogeneity by Bio-Gel chromatography. The size of the peptides from the amino to carboxyl end of the enzyme subunit was CNBr 1, 4,100; CNBr 2, 10,300; CNBr 3, 8,100; CNBr 4, 11,800; CNBr 5, 2,200. The sum of the amino acid residues of the peptides is equal to the sum of the residues in an enzyme subunit, indicating that all of the CNBr peptides have been isolated. The CNBr-resistant methionine was located in CNBr 2 and the 5-fluoro-2'-deoxyuridine 5'-monophosphate binding site in CNBr 4. The holoenzyme molecular weight, based on the residue weights of the amino acids in the two equivalent subunits, is equal to 73,176. The complete sequence of each of the CNBr peptides, except for CNBr 4, which is presented in the following paper, is described.     

Crystal structure of the Escherichia coli peptide methionine sulphoxide reductase at 1.9 A resolution

BACKGROUND: Peptide methionine sulphoxide reductases catalyze the reduction of oxidized methionine residues in proteins. They are implicated in the defense of organisms against oxidative stress and in the regulation of processes involving peptide methionine oxidation/reduction. These enzymes are found in numerous organisms, from bacteria to mammals and plants. Their primary structure shows no significant similarity to any other known protein. RESULTS: The X-ray structure of the peptide methionine sulphoxide reductase from Escherichia coli was determined at 3 A resolution by the multiple wavelength anomalous dispersion method for the selenomethionine-substituted enzyme, and it was refined to 1.9 A resolution for the native enzyme. The 23 kDa protein is folded into an alpha/beta roll and contains a large proportion of coils. Among the three cysteine residues involved in the catalytic mechanism, Cys-51 is positioned at the N terminus of an alpha helix, in a solvent-exposed area composed of highly conserved amino acids. The two others, Cys-198 and Cys-206, are located in the C-terminal coil. CONCLUSIONS: Sequence alignments show that the overall fold of the peptide methionine sulphoxide reductase from E. coli is likely to be conserved in many species. The characteristics observed in the Cys-51 environment are in agreement with the expected accessibility of the active site of an enzyme that reduces methionine sulphoxides in various proteins. Cys-51 could be activated by the influence of an alpha helix dipole. The involvement of the two other cysteine residues in the catalytic mechanism requires a movement of the C-terminal coil. Several conserved amino acids and water molecules are discussed as potential participants in the reaction.     

Dimethyl sulphoxide reduction by micro-organisms.

Dimethyl sulphoxide (DMSO) was reduced to dimethyl sulphide by a wide variety of micro-organism, including prokaryotes and eukaryotes, aerobes and anaerobes. Dimethyl sulphone was not reduced by any of the organisms tested. Cell-free extracts of Escherichia coli reduced DMSO using reduced pyridine nucleotides as electron donors. Activity was greater in anaerobically grown cells than in those grown aerobically. Two other sulphoxides, methionine sulphoxide and tetramethylene sulphoxide, substantially inhibited DMSO reduction by extracts. Mutants of E. coli, which were unable to reduce biotin sulphoxide to biotin, were tested for their ability to reduce DMSO in whole cells and extracts. These mutants were in four different gene loci, bisA to bisD. DMSO reductase activity of the mutants was generally less than that of the wild-type strain, and activity depended upon the gene locus involved, the growth medium and the growth conditions. Only the bisA mutant had very low activity under all conditions. All of the bis mutants were able to grow using methionine sulphoxide as a sulphur source, indicating that biotin sulphoxide and methionine sulphoxide are reduced by different enzyme systems. DMSO may be reduced by both of these enzyme systems.     

G.L.C. of the O-trimethylsilyl derivatives of hexuronic acids

The free acids, sodium salts, and lactones of several hexuronic acids have been studied as their O-trimethylsilyl derivatives by gas-liquid chromatography using SE-30 and XE-60 liquid phases. Silylation was best performed in methyl sulphoxide. The equilibrium between the various forms of a hexuronic acid in methyl sulphoxide was also studied by g.l.c. following silylation. The hexamethyldisilazane used in the silylation disturbed the equilibrium attained in the solvent, but this was overcome by premixing the hexamethyldisilazane with chlorotrimethylsilane. Methyl sulphoxide and the silylating reagents gave a two-phase system in which the derivative was favourably partitioned into the upper layer. Partition coefficients and stabilities of the derivatives were measured, and a g.l.c. method for the analysis of the hexuronic acids was thereby developed. The oximes of the hexuronic acids were studied as alternative derivatives for g.l.c., and their equilibrium compositions and g.l.c. retention times are recorded.     

Structure-function relationship in an archaebacterial methionine sulphoxide reductase B

Oxidation of methionine to methionine sulphoxide (MetSO) may lead to loss of molecular integrity and function. This oxidation can be 'repaired' by methionine sulphoxide reductases (MSRs), which reduce MetSO back to methionine. Two structurally unrelated classes of MSRs, MSRA and MSRB, show stereoselectivity towards the S and the R enantiomer of the sulphoxide respectively. Interestingly, these enzymes were even maintained throughout evolution in anaerobic organisms. Here, the activity and the nuclear magnetic resonance (NMR) structure of MTH711, a zinc containing MSRB from the thermophilic, methanogenic archaebacterium Methanothermobacter thermoautotrophicus, are described. The structure appears more rigid as compared with similar MSRBs from aerobic and mesophilic organisms. No significant structural differences between the oxidized and the reduced MTH711 state can be deduced from our NMR data. A stable sulphenic acid is formed at the catalytic Cys residue upon oxidation of the enzyme with MetSO. The two non-zinc-binding cysteines outside the catalytic centre are not necessary for activity of MTH711 and are not situated close enough to the active-site cysteine to serve in regenerating the active centre via the formation of an intramolecular disulphide bond. These findings imply a reaction cycle that differs from that observed for other MSRBs.     

Characterization of a strawberry late-expressed and fruit-specific peptide methionine sulphoxide reductase

We have cloned and characterized a cDNA clone, called Fapmsr , coding for a putative peptide methionine sulphoxide [Met(O)] reductase (PMSR, EC 1.8.4.6) from strawberry fruits ( Fragaria x ananassa ). This gene is involved in the repair of inactive peptides and proteins caused for the oxidation of methionine residues to Met(O). Expression of the Fapmsr was only detected in the receptacles of red mature fruits and not in young or immature fruits nor in other plant tissues such as flowers, leaves, runners, roots or achenes. Expression of the Fapmsr gene was activated in green immature fruits when achenes were removed from receptacles, and this was prevented by the application of exogenous auxins such as naphthaleneacetic acid. The enzyme produced and purified by cloning the strawberry cDNA in frame with the C-terminal sequence of the glutathione S-transferase gene can reduce free Met(O) to methionine as analysed by reverse phase high performance liquid chromatography. We have also set up a PMSR protection assay that demonstrates that this enzyme can protect in vivo against the damage produced by the addition of H₂O₂.     

N-Terminal Protein Characterization by Mass Spectrometry after Cyanogen Bromide Cleavage using Combined Microscale Liquid- and Solid-Phase Derivatization

A sample preparation method for protein N-terminal peptide isolation from cyanogen bromide (CNBr) protein digests has been developed. In this strategy, the CNBr cleavage was preceded by protein α- and ε-amine acetylation and carboxyamidomethylation in a one-pot reaction scheme. The peptide mixture was adsorbed on ZipTip_C18 pipette tips for reaction of the newly generated N-termini with sulfosuccinimidyl-2-(biotinamido) ethyl-1, 3-dithiopropionate. In the subsequent steps, the peptides were exposed in situ to hydroxylamine for reversal of potential hydroxyl group acylation, followed by reductive release of the disulfide-linked biotinamido moiety from the derivatives. The selectively thiol group-functionalized internal and C-terminal peptides were reversibly captured by covalent chromatography on activated thiol-sepharose, leaving the N-terminal fragment in the flow-through fraction. The use of the reversed-phase support as a venue for postcleavage serial modification proved instrumental to ensure throughput and completeness of derivatization. By this sequence of solid-phase reactions, the N-terminal peptide could be recognized uniquely in the MALDI-mass spectra of unfractionated digests by its unaltered mass signature. The use of the sample preparation method was demonstrated with low-picomole amounts of model protein. The N-terminal CNBr fragments were retrieved selectively from the affinity support. The sample preparation method provides for robustness and simplicity of operation using standard equipment available in most biological laboratories and is anticipated to be readily expanded to gel-separated proteins.     

Identification of ubiquinone-50 as the major methylated nonpolar lipid in human monocytes. Regulation of its biosynthesis via methionine-dependent pathways and relationship to superoxide production

Human blood monocytes incorporated the methyl group from methionine into their neutral lipids. The major methylated product was identified as ubiquinone-50 in monocytes, lymphocytes, and a variety of human tumor cell lines by several analytical procedures including TLC or high performance liquid chromatography and as ubiquinone-45 in a mouse tumor cell line. Up to three methyl groups were shown to be derived from methionine by mass spectrometry. The rate of synthesis of ubiquinone-50 by monocytes as assessed by measuring labeled methyl group incorporation was shown to be linear over a 3-h period. Degradation of ubiquinone proceeded slowly; 80% of the labeled compound persisted after 18 h. The dependence of ubiquinone-50 synthesis upon methionine concentration was established in monocytes, with an estimated apparent Km for methionine of about 20 microM. The tumor promoter, tetradecanoate phorbol acetate, a potent stimulator of superoxide anion (O2-) production in phagocytic cells, inhibited ubiquinone-50 synthesis at nanomolar concentrations in monocytes, but not in lymphocytes, under conditions where oxidation of methionine takes place. Degradation of the labeled ubiquinone was unaffected. Formylmethionylleucyl-phenylalanine, a chemoattractant peptide which stimulates O2- production in phagocytic cells, also inhibited ubiquinone-50 synthesis. The degree of inhibition by either stimulus was increased when the methionine concentration in the medium was low. These findings demonstrate that in human monocytes ubiquinone-50 biosynthesis is regulable and that methionine concentration modulates both its rate of synthesis and the inhibitory effects of two stimuli of O2- production.     

Myeloperoxidase-catalyzed incorporation of amines into proteins: role of hypochlorous acid and dichloramines

Myeloperoxidase-catalyzed oxidation of chloride (Cl-) to hypochlorous acid (HOCl) resulted in formation of mono- and dichloramine derivatives (RNHCl and RNCl2) of primary amines. The RNCl2 derivatives could undergo a reaction that resulted in incorporation of the R moiety into proteins. The probable mechanism was attack of RNCl2 or an intermediate formed in the decomposition of RNCl2 on histidine, tyrosine, and cystine residues and on lysine residues at high pH. Incorporation of radioactivity from labeled amines into stable, high molecular weight derivatives of proteins was measured by acid or acetone precipitation and by gel chromatography and electrophoresis. Whereas formation of RNCl2 was favored at low pH, the subsequent incorporation reaction was favored at high pH. Up to several hours were required for the maximum amount of incorporation, which was less than 10% of the label in RNCl2. For the amines tested, incorporation was in the order histamine greater than 1,2-diaminoethane greater than putrescine greater than taurine greater than lysine greater than glucosamine greater than leucine greater than methylamine. Initiation of the reaction required HOCl, and oxidized forms of bromide, iodide, or thiocyanate did not substitute. Inhibitors of incorporation fell into three classes. First, ammonia or amines competed with the labeled amine for reaction with HOCl, so that larger amounts of HOCl were required. Second, readily oxidized substances such as sulfhydryl or diketo compounds or thioethers (methionine) reduced RNCl2. Third, certain compounds competed with protein as the acceptor for the incorporation reaction. The amount required to block incorporation into protein depended on protein concentration. Among these inhibitors were imidazole compounds (histidine), phenols (tyrosine), and disulfides (glutathione disulfide, GSSG). Low yields of derivatives of histidine, tyrosine, and GSSG were detected by thin-layer chromatography. Acid-precipitable derivatives were obtained by reacting RNCl2 with polyhistidine or polytyrosine, and to a lesser extent with polylysine at high pH, but not with other poly(amino acids). Precipitable derivatives were also obtained by incubating MPO-containing extracts from leukocyte granules with hydrogen peroxide, Cl-, and labeled amines. The extracts were found to have a high content of substances with primary amino groups, which competed for incorporation. The results account for oxidative incorporation of amines into proteins in leukocytes and provide evidence that HOCl and nitrogen-chlorine (N-Cl) derivatives are formed in these cells. The characteristics of the incorporation reaction suggest that it would not contribute significantly to the antimicrobial activity of myeloperoxidase (MPO). Nevertheless, the reaction may provide a sensitive method for studying MPO action in vivo.     

Cyanogen bromide cleavage of proteins in sodium dodecyl sulphate/polyacrylamide gels. Diagonal peptide mapping of proteins from epidermis.

A two-dimensional electrophoretic procedure employing CNBr has been devised for the analysis of proteins in sodium dodecyl sulphate/polyacrylamide gels. The technique allows the detection of an unusual class of epidermal proteins that lack methionine. The proteins have been identified by this method in newborn mouse, rat, and rabbit, because they are stable in the presence of CNBr and consequently lie on a diagonal. Adult human epidermis also contains CNBr-stable proteins, but in lesser amounts than in the newborn rabbit or newborn rodents. The methionine-containing proteins (i.e., the keratins) are degraded by CNBr into a series of unique and characteristics peptides which lie below the diagonal. Inter- and intra-species similarities and differences exist between the individual keratins, depending on the number and distribution of their methionine residues. The peptide-map patterns for the rodent and lagomorph proteins are more similar to each other than to that for the human proteins. The maps for rat and rabbit skin proteins are the most similar. We conclude that the epidermal keratins are a closely related, yet individually distinct, group of proteins that are found in conjunction with a class of proteins that lack methionine. The latter proteins are related to the histidine-rich basic protein, an epidermal structural protein that aggregates with keratin filaments.     

Development and applications of in-gel CNBr/tryptic digestion combined with mass spectrometry for the analysis of membrane proteins

Hydrophobic membrane proteins often have complex functions and are thus of great interest. However, their analysis presents a challenge because they are not readily soluble in polar solvents and often undergo aggregation. We present a sequential CNBr and trypsin in-gel digestion method combined with mass spectrometry for membrane protein analysis. CNBr selectively cleaves methionine residues. But due to the low number of methionines in proteins, CNBr cleavage produces a small number of large peptide fragments with MWs typically >2000, which are difficult to extract from gel pieces. To produce a larger number of smaller peptides than that obtained by using CNBr alone, we demonstrate that trypsin can be used to further digest the sample in gel. The use of n-octyl glucoside (n-OG) to enhance the digestion efficiency and peptide recovery was also studied. We demonstrate that the sensitivity of this membrane protein identification method is in the tens of picomole regime, which is compatible to the Coomassie staining gel-spot visualization method, and is more sensitive than other techniques reported in the literature. This CNBr/trypsin in-gel digestion method is also found to be very reproducible and has been successfully applied for the analysis of complex protein mixtures extracted from biological samples. The results are presented from a study of the analysis of bacteriorhodopsin, nitrate reductase 1 gamma chain, and a complex protein mixture extracted from the endoplasmic recticulum membrane of mouse liver.     

A proteomics approach to identify the ubiquitinated proteins in mouse heart

There is a growing need for the large-scale identification of the ubiquitinated proteins and ubiquitin attachment sites. As part of this effort, we generated a transgenic mouse expressing a tagged ubiquitin in the heart. We found that the majority of ubiquitinated proteins in mouse heart are insoluble in detergent-free buffer and were chemically cleaved after methionine with CNBr. CNBr cleaved the proteins into smaller polypeptides while preserving the ubiquitin chains. Ubiquitin-conjugated polypeptides were then purified under denaturing conditions, digested with Lys-C and trypsin, and analyzed by liquid chromatography-tandem mass spectrometry. We identified 121 proteins that were ubiquitinated in mouse heart, and we detected 33 ubiquitination sites in 21 of the proteins. Components of cardiac muscle and many mitochondrial proteins were identified as substrates for ubiquitination, strongly suggesting that proteins related to major heart functions such as contraction and energy production are under continuous quality control by the ubiquitin system.     

Human complement component C1s. Partial sequence determination of the heavy chain and identification of the peptide bond cleaved during activation

Human C1s proenzyme (Mr 83 000) was isolated by a rapid two-stage method involving affinity chromatography of C1 on IgG-Sepharose and isolation of subcomponent C1s by ion-exchange chromatography on DEAE-Sephacel. Single-chain C1s proenzyme was activated to two-chain C1s with self-activated C1r. After reduction and S-carboxamidomethylation the heavy chain of C1s (Mr 57 000) was isolated by ion exchange chromatography on DEAE-Sephacel. Cleavage of C1s heavy chain with CNBr yielded five fragments whose N-terminal sequences were determined. The alignment of the fragments within the heavy chain was established by tryptic peptides containing methionine. C1s heavy chain comprises about 470 amino acid residues and 42% of its sequence was determined. An intrachain sequence homology and a homology to the alpha 2 chain of human haptoglobin were identified. The C-terminal CNBr fragment comprising 44 amino acid residues was completely sequenced. From BNPS-skatole cleavage of reduced and alkylated C1s proenzyme a fragment was isolated which overlaps the C1s heavy and light chain parts and which contains the peptide bond cleaved during activation. The results show that this is an Arg-Ile bond and that under standard conditions of activation no peptide material is liberated from this portion of the molecule. The sequence data and homology to two-chain serine proteases indicate a single interchain disulfide bond in C1s.     

Analysis of erythrocyte protein methyl esters by two-dimensional gel electrophoresis under acidic separating conditions

A two-dimensional polyacrylamide gel electrophoresis system which is suitable for the analysis of protein methylation reactions in cells incubated with L-[methyl-3H]methionine is described. The procedure separates proteins under primarily acidic conditions by isoelectric focusing in the first dimension and by sodium dodecyl sulfate electrophoresis at pH 2.4 in the second dimension. The low pH is essential for preserving protein [3H]methyl esters, but it limits the effective separating range of this system to proteins with isoelectric points between 4 and 8. With this system, we have shown that most, if not all, erythrocyte membrane and cytosolic proteins can act as substoichiometric methyl acceptors for an intracellular S-adenosylmethionine-dependent carboxyl methyltransferase and that protein carboxyl methylation reactions may be the major methyl transfer reaction in erythrocytes. These results are most consistent with the generation of protein substrate sites for the carboxyl methyltransferase by spontaneous deamidation and racemization reactions.     

Proteins induced by sulfate limitation in Escherichia coli, Pseudomonas putida, or Staphylococcus aureus.

Two-dimensional gel electrophoresis of proteins from Escherichia coli, Pseudomonas putida, and Staphylococcus aureus, grown with methionine or one of a variety of organosulfates and organosulfonates as the sole source of sulfur, showed expression of specific sets of 7 to 14 proteins which were not observed during growth with sulfate or cysteine for all three species or with thiocyanate for P. putida and S. aureus. Under the same conditions, arylsulfatase activity in P. putida and S. aureus was seen to increase by up to 140-fold, suggesting that the proteins induced under these conditions may be involved in sulfur metabolism. We propose that these proteins are members of a sulfate starvation-induced stimulon.     

Effect of oxidation on the properties of apolipoproteins A-I and A-II

Purified apolipoprotein A-I has been separated by reversed-phase high performance liquid chromatography (HPLC) into multiple peaks and these peaks have been characterized. One peak, apoA-Ib had a relatively longer retention time on HPLC but its retention time could be shortened by treatment by hydrogen peroxide. CNBr cleavage studies indicated that the differences in apoA-Ib and in its oxidation product, apoA-Ia, were due to the different oxidation states of methionine. This phenomenon was also observed in apoA-II, where methionine oxidation produced two more forms of this apolipoprotein in addition to the native form. These isomers were found to have different secondary structures and affinities for lipid. Model peptide analogs of the amphipathic helix with the same sequence but with methionine and methionine sulfoxide at the nonpolar face of the amphipathic helix were synthesized and studied. It was found that the lipid affinities of these synthetic peptide isomers were very different. They also differed in their secondary structures as studied by circular dichroism (CD). We propose that methionine oxidation introduces hydrophilic residues at the nonpolar face of the amphipathic helical domains of these apolipoproteins and, therefore, alters their secondary structure and lipid affinity.