Quantitative microspectrophotometrical determination of protein thiols and disulfides with 2,2'-dihydroxy-6,6'-dinaphthyldisulfide (DDD). The variety of DDD-staining methods demonstrated on Ehrlich ascites tumor cells

2,2'-dihydroxy-6,6'-dinaphthyldisulfide (DDD) reacts with both protein thiol groups and with protein disulfides (N?hammer 1977). By varying the pH of the DDD-reaction, as well as the reaction times, the complex reaction became specific with respect to the histochemical demonstration of protein-SH groups. Furthermore, the application of the histochemical DDD-reaction following quantitative blockade of the protein-SH groups enabled the demonstration of distinctive DDD-reactive disulfides. The specificity and the extent of the different histochemical DDD-staining methods were investigated by comparing macroscopically determined values of the protein-SH-contents, and the contents of the different kinds of disulfides in Ehrlich-ascites-tumor cells (EATC) (Modig 1968; Hofer 1975), with microspectrometrical values determined with the MCN-method of N?hammer et al. (1981), and with microspectrometrical values measured on EATC after staining with the modified DDD-methods. Also, the method for the histochemical demonstration of protein-SH with DDD after the reduction of the disulfides with thioglycolate was investigated and conditions were found by which the protein-SH content could be determined quantitatively with DDD and Fast blue B after the reduction of the disulfides. With the aid of the MCN-method (N?hammer et al. 1981), the intracellular disulfide interchange reaction was investigated, leading to pH-dependent changes of the SH-SS-ratio of fixed cells during their incubation in aqueous media. In addition the possibility of protein loss during the long incubation times of the fixed cells in the DDD-solutions was investigated. For the quantitative microscpecrometrical determination of the protein content of EATC the so-called tetrazonium-coupling method, optimized by N?hammer (1978) and calibrated by N?hammer et al. (1981), was used.     

Quantitative microspectrophotometrical determination of protein thiols and disulfides with 2,2′-dihydroxy-6,6′-dinaphthyldisulfide (DDD)

Summary 2,2-dihydroxy-6,6-dinaphthyldisulfide (DDD) reacts with both protein thiol groups and with protein disulfides (Nöhammer 1977). By varying the pH of the DDD-reaction, as well as the reaction times, the complex reaction became specific with respect to the histochemical demonstration of protein-SH groups. Furthermore, the application of the histochemical DDD-reaction following quantitative blockade of the protein-SH groups enabled the demonstration of distinctive DDD-reactive disulfides. The specifity and the extent of the different histochemical DDD-staining methods were investigated by comparing macroscopically determined values of the protein-SH-contents, and the contents of the different kinds of disulfides in Ehrlich-ascites-tumor cells (EATC) (Modig 1968; Hofer 1975), with microspectrometrical values determined with the MCN-method of Nöhammer et al. (1981), and with microspectrometrical values measured on EATC after staining with the modified DDD-methods. Also, the method for the histochemical demonstration of protein-SH with DDD after the reduction of the disulfides with thioglycolate was investigated and conditions were found by which the protein-SH content could be determined quantitatively with DDD and Fast blue B after the reduction of the disulfides. With the aid of the MCN-method (Nöhammer et al. 1981), the intracellular disulfide interchange reaction was investigated, leading to pH-dependent changes of the SH-SS-ratio of fixed cells during their incubation in aqueous media. In addition the possibility of protein loss during the long incubation times of the fixed cells in the DDD-solutions was investigated. For the quantitative microscpecrometrical determination of the protein content of EATC the so-called tetrazonium-coupling method, optimized by Nöhmmer (1978) and calibrated by Nöhammer et al. (1981), was used.Dedicated to Prof. Dr. E. Ziegler on the occasion of his 70^th birthday     

Protein-thiol substitution or protein dethiolation by thiol/disulfide exchange reactions: the albumin model

Dethiolation experiments of thiolated albumin with thionitrobenzoic acid and thiols (glutathione, cysteine, homocysteine) were carried out to understand the role of albumin in plasma distribution of thiols and disulfide species by thiol/disulfide (SH/SS) exchange reactions. During these experiments we observed that thiolated albumin underwent thiol substitution (Alb-SS-X+RSH<-->Alb-SS-R+XSH) or dethiolation (Alb-SS-X+XSH<-->Alb-SH+XSSX), depending on the different pK(a) values of thiols involved in protein-thiol mixed disulfides (Alb-SS-X). It appeared in these reactions that the compound with lower pK(a) in mixed disulfide was a good leaving group and that the pK(a) differences dictated the kind of reaction (substitution or dethiolation). Thionitrobenzoic acid, bound to albumin by mixed disulfide (Alb-TNB), underwent rapid substitution after thiol addition, forming the corresponding Alb-SS-X (peaks at 0.25-1 min). In turn, Alb-SS-X were dethiolated by the excess nonprotein SH groups because of the lower pK(a) value in mixed disulfide with respect to that of other thiols. Dethiolation of Alb-SS-X was accompanied by formation of XSSX and Alb-SH up to equilibrium levels at 35 min, which were different for each thiol. Structures by molecular simulation of thiolated albumin, carried out for understanding the role of sulfur exposure in mixed disulfides in dethiolation process, evidenced that the sulfur exposure is important for the rate but not for determining the kind of reaction (substitution or dethiolation). Our data underline the contribution of SH/SS exchanges to determine levels of various thiols as reduced and oxidized species in human plasma.     

Levels of sulfhydryls and disulfides in proteins from Neurospora crassa conidia and mycelia

Proteins extracted with 6 M guanidine at 90 degrees C from conidia (asexual spores) of Neurospora crassa contained ca. 25% more total protein thiol and a fivefold-higher content of disulfide bonds than proteins extracted from mycelia, as determined by labeling with iodo[14C]acetic acid. The total thiol content was 88 mumol/g of protein in conidia and 70 mumol/g of protein in mycelia. The level of protein disulfide was 18.5 mumol/g of protein in conidia and 3.5 mumol/g of protein in mycelia, by the iodo[14C]acetic acid labeling method. Confirmatory results were obtained with 5'5-dithio-bis-2-nitrobenzoic acid titration of protein thiol groups in 1% sodium dodecyl sulfate as well as by amino acid analysis of cysteic acid derivatives. Buffer-extracted proteins from conidia, but not mycelia, were found to contain enriched levels of protein thiols and disulfides per gram of protein as compared with guanidine hydrochloride extracts. It was demonstrated that the high disulfide content of crude conidial extracts was not due to measurable levels of mixed disulfides formed between protein sulfhydryl groups and cysteine. During germination of the conidia, the high disulfide levels of the conidial proteins remained constant. These data suggest that, unlike the disulfides of glutathione, the bulk of conidial protein disulfides were not reduced, excreted, or extensively degraded during germination.     

Mass spectrometric analysis of nitroxyl-mediated protein modification: comparison of products formed with free and protein-based cysteines

Although biologically active, nitroxyl (HNO) remains one of the most poorly studied NO(x). Protein-based thiols are suspected targets of HNO, forming either a disulfide or sulfinamide (RSONH2) through an N-hydroxysulfenamide (RSNHOH) addition product. Electrospray ionization mass spectrometry (ESI-MS) is used here to examine the products formed during incubation of thiol proteins with the HNO donor, Angeli's salt (AS; Na2N2O3). Only the disulfide, cystine, was formed in incubates of 15 mM free Cys with equimolar AS at pH 7.0-7.4. In contrast, the thiol proteins (120-180 microM), human calbindin D(28k) (HCalB), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and bovine serum albumin (BSA) gave four distinct types of derivatives in incubates containing 0.9-2.5 mM AS. Ions at M + n x 31 units were detected in the ESI mass spectra of intact HCalB (n = 1-5) and GAPDH (n = 2), indicating conversion of thiol groups on these proteins to RSONH2 (+31 units). An ion at M + 14 dominated the mass spectrum of BSA, and intramolecular sulfinamide cross-linking of Cys34 to one of its neighboring Lys or Arg residues would account for this mass increase. Low abundant M + 14 adducts were observed for HCalB, which additionally formed mixed disulfides when free Cys was present in the AS incubates. Cys149 and Cys153 formed an intramolecular disulfide in the AS/GAPDH incubates. Since AS also produces nitrite above pH 5 (HN2O3(-) --> HNO + NO2(-)), incubation with NaNO2 served to confirm that protein modification was HNO-mediated, and prior blocking with the thiol-specific reagent, N-ethylmaleimide, demonstrated that thiols are the targets of HNO. The results provide the first systematic characterization of HNO-mediated derivatization of protein thiols.     

Determination of Reduced, Protein-Unbound, and Total Concentrations of N-Acetyl- -cysteine and -Cysteine in Rat Plasma by Postcolumn Ligand Substitution High-Performance Liquid Chromatography

A high-performance liquid chromatographic assay was developed for the quantitative determination of the sulfur-containing amino acids N-acetyl- -cysteine (NAC) and -cysteine (Cys) in rat plasma. The thiols were separated by reverse-phase ion-pair chromatography, and the column eluent was continuously mixed with an iodoplatinate-containing solution. The substitution of sulfur of the thiol compound with iodide was quantitatively determined by measuring changes in the absorption at 500 nm. The low-molecular-weight disulfides and mixed disulfide conjugates of thiols with proteins were entirely reduced to the original reduced compounds by dithiothreitol. By reducing these two types of disulfides separately during sample pretreatment, the reduced, protein-unbound, and total thiol concentrations could also be determined. Validation testing was performed, and no problems were encountered. The limit of detection was approximately 20 pmol of thiol on the column. The present method was used to measure the plasma concentrations of NAC and Cys in the rat after a bolus intravenous administration of NAC, focusing on disulfide formation. The binding of NAC to protein through mixed disulfide formation proceeds in a time-dependent and reversible manner. Moreover, this “stable” covalent binding might limit total drug elimination, while the unbound NAC is rapidly eliminated. Consequently, the analytical method described in this study is very useful for the determination of plasma NAC and Cys, including disulfide conjugates derived from them.     

Histophotometric quantification of protein and reactive proteinthiols in invasive carcinomas of the skin

Frozen sections cut from 14 samples of invasive carcinomas of the skin were stained with Amido black for protein determination and with dihydroxydinaphthyldisulphide fast blue to quantify reactive protein thiols (PSHr) and were then analysed microphotometrically. It was found that all of the samples exhibited significant reductions in protein levels (49%-74%) and PSHr levels (32%-53%) as compared to normal epidermis. Thus, the content of proteins of PSHr groups was 1.7 times greater in the malignant tissue examined than in normal epidermis. These results are in accordance with those previously obtained in basal-cell epitheliomas.     

Determination of homocysteine, penicillamine, and their symmetrical and mixed disulfides by liquid chromatography with electrochemical detection

A method for the determination of D-penicillamine, homocysteine, homocystine, penicillamine-homocysteine mixed disulfide, and penicillamine disulfide in human plasma and urine is described. The method involves separation of the various thiols and disulfides by high-performance liquid chromatography with detection by a dual Hg/Au amalgam electrochemical detector. D-Penicillamine and homocysteine are detected at the downstream electrode; the disulfides are first reduced to thiols at the upstream electrode and then the thiols are detected at the downstream electrode. Hydrodynamic voltammograms were measured for the various thiols and disulfides to determine optimum settings for the electrochemical detector, and the effect of mobile phase parameters on retention times was studied to optimize the separation. A convenient method for the preparation of calibration solutions of penicillamine-homocysteine mixed disulfide by thiol/disulfide exchange with standardization of the solution by H NMR spectroscopy is described. Detection limits are below the concentrations of homocystine and penicillamine-homocysteine mixed disulfide reported to be present in the plasma and urine, respectively, of homocystinuric patients under treatment with D-penicillamine.     

Assay of thiols and disulfides based on the reversibility of N-ethylmaleimide alkylation of thiols combined with electrolysis

A simple and specific method for analyzing thiols and disulfides on the basis of the reversibility of N-ethylmaleimide (NEM) alkylation of thiols is described. When the adduct of NEM and glutathione (GSH) was electrolyzed at neutral pH, all of the GSH was recovered. When the adduct was exposed to pH 11.0 for 15 min at 30°C before electrolysis, GSH was not detected. The same behavior was observed after protein thiols reacted with NEM. This pH-dependent production of thiol from the adduct was used to assay GSH and oxidized glutathione in yeast cells, to assay sulfhydryl groups and disulfide bonds in authentic proteins, and to protect thiols from oxidation during enzymatic digestion of protein. This method is useful for assay of thiols and disulfides of both small and large molecules and can be used to identify labile thiols in biological samples that are oxidized during extraction procedures.     

Formation of disulfide bonds between glutathione and membrane sh groups in human erythrocytes

In erythrocytes treated with the SH-oxidizing agent, diamide, mixed disulfide bonds between membrane proteins and GSH are formed involving 20% of the membrane SH groups. To study the distribution of these mixed disulfides over the membrane protein fractions, intracellular GSH was labelled biosynthetically with [2-³H]glycine prior to diamide treatment of the cells and the radioactivity of defined membrane peptide fractions determined. Mixed disulfides preferentially occur in the extrinsic protein, spectrin (six SH groups), in addition to the formation of peptide disulfides. Intrinsic proteins are much less reactive: only one SH group of the major intrinsic protein (band 3) reacts with GSH, which accounts for previously observed impossibility to dimerize band 3 via disulfide bonds in intact cells. The labelling method described offers a promising strategy to label and map exposed endofacial SH groups of membrane proteins with a physiological, impermeable marker, GSH.In ghosts treated with diamide and GSH the number of mixed disulfides formed is greater than in erythrocytes. Polymerization of spectrin via intermolecular disulfide bridges is suppressed, while intramolecular disulfides are still formed, providing a means for the analysis of spectrin structure.The diamide-induced mixed membrane-GSH disulfides are readily reduced by GSH. This suggests, that GSH may also be able to reduce mixed disulfides formed in the erythrocyte membrane under oxidative stress in vivo. The reversible formation of mixed disulfides may serve to protect sensitive membrane structures against irreversible oxidative damage.     

Distribution of oxidized and reduced forms of glutathione and cysteine in rat plasma

The distribution of the glutathionyl moiety between reduced and oxidized forms in rat plasma was markedly different than that for the cysteinyl moiety. Most of the glutathionyl moiety was present as mixed disulfides with cysteine and protein whereas most of the cysteinyl moiety was present as cystine. Seventy percent of total glutathione equivalents was bound to proteins in disulfide linkage. The distribution of glutathione equivalents in the acid-soluble fraction was 28.0% as glutathione, 9.5% as glutathione disulfide, and 62.6% as the mixed disulfide with the cysteinyl moiety. In contrast, 23% of total cysteine equivalents was protein-bound. The distribution of cysteine equivalents in the acid-soluble fraction was 5.9% as cysteine, 83.1% as cystine, and 10.8% as the mixed disulfide with the glutathionyl moiety. A first-order decline in glutathione occurred upon in vitro incubation of plasma and was due to increased formation of mixed disulfides of glutathione with cysteine and protein. This indicates that plasma thiols and disulfides are not at equilibrium, but are in a steady-state maintained in part by transport of these compounds between tissues during the inter-organ phase of their metabolism. The large amounts of protein-bound glutathione and cysteine provide substantial buffering which must be considered in analysis of transient changes in glutathione and cysteine. In addition, this buffering may protect against transient thiol-disulfide redox changes which could affect the structure and activity of plasma and plasma membrane proteins.     

Histophotometric quantification of protein and reactive proteinthiols in invasive carcinomas of the skin

Summary Frozen sections cut from 14 samples of invasive carcinomas of the skin were stained with Amido black for protein determination and with dihydroxydinaphthyldisulphide fast blue to quantify reactive protein thiols (PSH_r) and were then analysed microphotometrically. It was found that all of the samples exhibited significant reductions in protein levels (49%–74%) and PSH_r levels (32%–53%) as compared to normal epidermis. Thus, the content of proteins of PSH_r groups was 1.7 times greater in the malignant tissue examined than in normal epidermis.These results are in accordance with those previously obtained in basal-cell epitheliomas.     

Changes in protein and nonprotein thiol contents in bladder, kidney and liver of mice by the pesticide sodium-o-phenylphenol and their possible role in cellular toxicity.

Acute treatment of mice with Na-o-phenylphenol or phenylbenzoquinone, an electrophilic metabolite of o-phenylphenol, resulted in differential depletion of contents of protein and nonprotein thiols in bladder, kidney and liver. Maximum decrease in the levels of protein and nonprotein reduced thiols was observed in bladder (by both agents) and was followed by kidney (by both agents) and liver (phenylbenzoquinone only). The reason for this differential changes in reduced thiol contents remains to be understood. The content of protein and nonprotein disulfides was higher in bladder of mice treated with Na-o-phenylphenol compared to that observed in untreated mice bladder. Phenyl 2,5'-p-benzoquinone mediated in vivo depletion of nonprotein and protein thiols suggests that Na-o-phenylphenol treatment may decrease in vivo thiols via the formation of phenylbenzoquinone. Increased disulfide formation is considered to represent an index of oxidative stress produced by chemical. Increases in the level of protein and nonprotein disulfides in bladder suggest as observed in this study that administration of Na-o-phenylphenol to mice produced oxidative stress in bladder. Products of redox cycling of xenobiotics are known to cause cellular toxicity via altering the homeostasis of thiol status. Therefore, it is concluded that decreases in protein thiol contents either via alkylation and/or oxidation of sulfhydryl groups of proteins and increases in disulfide contents presumably by products of redox cycling of Na-o-phenylphenol may play a role in Na-o-phenylphenol-induced cellular toxicity.     

tert-Butylhydroperoxide-induced toxicity in isolated hepatocytes: contribution of thiol oxidation and lipid peroxidation

Incubation of isolated rat hepatocytes with tert-butylhydroperoxide resulted in marked cytotoxicity preceded by intracellular glutathione depletion and extensive lipid peroxidation. Addition of antioxidants delayed, but did not prevent, this toxicity. A significant decrease in protein-free sulfhydryl groups also occurred in the presence of tert-butylhydroperoxide; direct oxidation of protein thiols and mixed disulfide formation with glutathione were responsible for this decrease. The involvement of protein thiol depletion in tert-butylhydroperoxide-induced cytotoxicity is suggested by our observation that administration of dithiothreitol, which caused re-reduction of the oxidized sulfhydryl groups and mixed disulfides, efficiently protected the cells from toxicity. Moreover, depletion of intracellular glutathione by pretreatment of the hepatocytes with diethyl maleate accelerated and enhanced the depletion of protein thiols induced by tert-butylhydroperoxide and potentiated cell toxicity even in the absence of lipid peroxidation.     

YajL, the prokaryotic homolog of the Parkinsonism-associated protein DJ-1, protects cells against protein sulfenylation

YajL is the closest Escherichia coli homolog of the Parkinsonism-associated protein DJ-1, a multifunctional oxidative stress response protein whose biochemical function remains unclear. We recently described the oxidative-stress-dependent aggregation of proteins in yajL mutants and the oxidative-stress-dependent formation of mixed disulfides between YajL and members of the thiol proteome. We report here that yajL mutants display increased protein sulfenic acids levels and that formation of mixed disulfides between YajL and its protein substrates in vivo is inhibited by the sulfenic acid reactant dimedone, suggesting that YajL preferentially forms disulfides with sulfenylated proteins. YajL (but not YajL(C106A)) also forms mixed disulfides in vitro with the sulfenylated form of bovine serum albumin. The YajL-serum albumin disulfides can be subsequently reduced by glutathione or dihydrolipoic acid. We also show that DJ-1 can form mixed disulfides with sulfenylated E. coli proteins and with sulfenylated serum albumin. These results suggest that YajL and possibly DJ-1 function as covalent chaperones involved in the detection of sulfenylated proteins by forming mixed disulfides with them and that these disulfides are subsequently reduced by low-molecular-weight thiols.     

Role of thiamine thiol form in nitric oxide metabolism

In alkaline media the thiamine cyclic form is converted into a thiol form (pK(a) 9.2) with an opened thiazole ring. The thiamine thiol form releases nitric oxide from S-nitrosoglutathione (GSNO). Thiamine disulfide, mixed thiamine disulfide with glutathione, and nitric oxide are produced in the reaction. Free glutathione was recorded in small amounts. The concentration of formed nitric oxide agreed well with the concentration of degraded GSNO. The concentration of released nitric oxide was determined under anaerobic conditions spectrophotometrically by production of nitrosohemoglobin. In air, the release of nitric oxide was recorded by the production of nitrite or the oxidation of oxyhemoglobin to methemoglobin. The concentration of the thiol form in the body under physiological pH values (7.2-7.4) did not exceed 1.5-2.0%. We believe that due to the exchange reactions between the thiamine thiol form and S-nitrosocysteine protein residues, nitric oxide can be released and mixed thiamine-protein disulfides are formed. The mixed thiamine disulfides (including thiamine ester disulfides) as well as the thiamine disulfide form are quite easily reduced by low molecular weight thiols to form the thiamine cyclic form with a closed thiazole ring. A possible role of the thiamine thiol form in releasing deposited nitric oxide from low-molecular-weight S-nitrosothiols and protein S-nitrosothiols and in regulation of blood flow in the vascular bed is discussed.     

Effects of the aminonucleoside of puromycin on kidney cortex sulfhydryl and disulfide-containing components and their respective oxidoreductase activities.

Comparative study of glutathione reductase and of mixed disulfide reducing activity assayed with a bovine serum albumin-glutathione substrate in kidney cortex of normal and of aminonucleoside-nephrotic rats reveals significantly higher activities in the latter. Total acid-soluble sulfhydryl and reduced glutathione (GSH) were also found to be significantly higher in kidney cortex of the aminonucleoside-treated rats. Neither total mixed disulfides nor mixed disulfides in which glutathione is covalently bound by disulfide linkage to kidney cortex protein are significantly altered by the nephrosis-producing aminonucleoside.     

Detection of reversible protein thiol modifications in tissues

Oxidation/reduction reactions of protein thiol groups (PSH) have been implicated in many physiological and pathological processes. Although many new techniques for separation and identification of modified cysteinyl residues in proteins have been developed, critical assessment of reagents and sample processing often are overlooked. We carefully compared the effectiveness of N-ethylmaleimide (NEM), iodoacetamide (IAM), and iodoacetic acid (IAA) in alkylating protein thiols and found that NEM required less reagent (125 vs. 1000 mol:mol excess), required less time (4 min vs. 4h), and was more effective at lower pHs (4.3 vs. 8.0) in comparison with IAM and IAA. The relative efficacy of dithiothreitol (DTT) and tris(2-carboxyethyl)phosphine (TCEP) for reducing protein disulfides suspended in NaPO(4) buffer or MeOH was assessed, and no differences in total normalized fluorescence were detected at the concentrations tested (10-100mM); however, individual band resolution appeared better in samples reduced with DTT in MeOH. In addition, we found that oxidation ex vivo was minimized in tissue samples that were homogenized in aqueous buffers containing excess molar quantities of NEM compared with samples homogenized in MeOH containing NEM. Using NEM for thiol alkylation, DTT for disulfide reduction, and mBBr for labeling the reduced disulfide and fluorimetric detection, we were able to generate an in-gel standard curve and quantitate total disulfide contents within biological samples as well as to identify changes in specific protein bands by scanning densitometry. We demonstrated that reagents and techniques we have identified for disulfide detection in complex samples are also applicable to two-dimensional electrophoresis separations.     

Structural disulfide bonds in the Bacillus thuringiensis subsp. israelensis protein crystal.

We examined disulfide bonds in mosquito larvicidal crystals produced by Bacillus thuringiensis subsp. israelensis. Intact crystals contained 2.01 X 10(-8) mol of free sulfhydryls and 3.24 X 10(-8) mol of disulfides per mg of protein. Reduced samples of alkali-solubilized crystals resolved into several proteins, the most prominent having apparent molecular sizes of 28, 70, 135, and 140 kilodaltons (kDa). Nonreduced samples contained two new proteins of 52 and 26 kDa. When reduced, both the 52- and 26-kDa proteins were converted to 28-kDa proteins. Furthermore, both bands reacted with antiserum prepared against reduced 28-kDa protein. Approximately 50% of the crystal proteins could be solubilized without disulfide cleavage. These proteins were 70 kDa or smaller. Solubilization of the 135- and 140-kDa proteins required disulfide cleavage. Incubation of crystals at pH 12.0 for 2 h cleaved 40% of the disulfide bonds and solubilized 83% of the crystal protein. Alkali-stable disulfides were present in both the soluble and insoluble portions. The insoluble pellet contained 12 to 14 disulfides per 100 kDa of protein and was devoid of sulfhydryl groups. Alkali-solubilized proteins contained both intrachain and interchain disulfide bonds. Despite their structural significance, it is unlikely that disulfide bonds are involved in the formation or release of the larvicidal toxin.     

Assay of thiols and disulfides based on the reversibility of N-ethylmaleimide alkylation of thiols combined with electrolysis.

A simple and specific method for analyzing thiols and disulfides on the basis of the reversibility of N-ethylmaleimide (NEM) alkylation of thiols is described. When the adduct of NEM and glutathione (GSH) was electrolyzed at neutral pH, all of the GSH was recovered. When the adduct was exposed to pH 11.0 for 15 min at 30 degrees C before electrolysis, GSH was not detected. The same behavior was observed after protein thiols reacted with NEM. This pH-dependent production of thiol from the adduct was used to assay GSH and oxidized glutathione in yeast cells, to assay sulfhydryl groups and disulfide bonds in authentic proteins, and to protect thiols from oxidation during enzymatic digestion of protein. This method is useful for assay of thiols and disulfides of both small and large molecules and can be used to identify labile thiols in biological samples that are oxidized during extraction procedures.