Oligomerization of the cysteinyl-rich oligopeptidase EP24.15 is triggered by S-glutathionylation

Thimet oligopeptidase (EC 3.4.24.15; EP24.15) is a thiol-rich metallopeptidase ubiquitously distributed in mammalian tissues and involved in oligopeptide metabolism both within and outside cells. Fifteen Cys residues are present in the rat EP24.15 protein, seven are solvent accessible, and two are found inside the catalytic site cleft; no intraprotein disulfide is described. In the present investigation, we show that mammalian immunoprecipitated EP24.15 is S-glutathionylated. In vitro EP24.15 S-glutathionylation was demonstrated by the incubation of bacterial recombinant EP24.15 with oxidized glutathione concentration as low as 10 microM. The in vitro S-glutathionylation of EP24.15 was responsible for its oxidative oligomerization to dimer and trimer complexes. EP24.15 immunoprecipitated from cells submitted to oxidative challenge showed increased trimeric forms and decreased S-glutathionylation compared to immunoprecipitated protein from control cells. Our present data also show that EP24.15 maximal enzymatic activity is maintained by partial S-glutathionylation, a mechanism that apparently regulates the protein oligomerization. Present results raise the possibility of an unconventional property of protein S-glutathionylation, inducing oligomerization by interprotein thiol-disulfide exchange.     

Protein S-glutathiolation triggered by decomposed S-nitrosoglutathione

Recombinant human brain calbindin D(28K) (rHCaBP), human Cu,Zn-superoxide dismutase (HCuZnSOD), rabbit muscle glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and bovine serum albumin (BSA) were found to be S-glutathiolated in decomposed S-nitrosoglutathione (GSNO) solutions. Tryptic or Glu-C digestion and MALDI-TOF MS analyses of the digests are consistent with S-thiolation of Cys111 and Cys187 of HCuZnSOD and rHCaBP, respectively, upon exposure to decomposed GSNO. GAPDH activity analysis reveals that S-glutathiolation most likely occurs on the active site Cys149, and the single free Cys34 is assumed to be the site of S-glutathiolation in BSA. The yields of S-glutathiolation of rHCaBP, GAPDH, and BSA were much higher than those of HCuZnSOD. The latter is limited by the accessibility of Cys111 to the glutathiolating reagent in the HCuZnSOD dimer. Unlike decomposed GSNO, fresh GSNO, reduced glutathione (GSH), and oxidized glutathione (GSSG) are not efficient S-glutathiolating agents for the proteins examined here. On the basis of analysis by mass spectrometry and UV-visible absorption, GSNO decomposition in the dark at room temperature yields glutathione disulfide S-oxide [GS(O)SG], glutathione disulfide S-dioxide (GSO(2)SG), and GSSG as products. GS(O)SG is the efficient protein S-glutathiolating agent in GSNO solutions, not GSNO, which does not carry out efficient S-glutathiolation of rHCaBP, HCuZnSOD, or GAPDH in vitro. A hydrolysis pathway yielding GSOH and nitroxyl (HNO/NO(-)) as intermediates is proposed for GSNO decomposition in the dark. This is based on inhibition of GSNO breakdown by dimedone, a reagent specific for sulfenic acids, and on nitroxyl scavenging by metmyoglobin. The results presented here are contrary to numerous reports of protein S-thiolation by low-molecular weight S-nitrosothiols.     

Liquid chromatography-electrospray mass spectrometry study of cysteine-10 S-glutathiolation in recombinant glutathione S-transferase of Ochrobactrum anthropi

Glutathione S-transferase of Ochrobactrum anthropi (OaGST), a bacterium isolated from soils contaminated by xenobiotic pollutants, was recently purified, cloned and characterised in our laboratories. The recombinant OaGST (rOaGST), highly expressed in Escherichia coli, when purified by glutathione-affinity chromatography and then analysed by electrospray ionisation mass spectrometry (ESI-MS), has evidenced a disulphide bond with glutathione (S-glutathiolation), which was removable by reduction with 2-mercaptoethanol. Enzymatic digestion of rOaGST with endoproteinase Glu-C, followed by liquid chromatography (LC)-ESI-MS analyses of the peptide mixtures under both reducing and not reducing conditions, have shown that glutathione was covalently bound to the Cys10 residue of rOaGST. Furthermore, LC-ESI-MS analyses of overexpressed rOaGST in Escherichia coli crude extracts, with and without incubation with glutathione, have not shown any S-glutathiolation of the recombinant enzyme.     

Quantification of oxidative posttranslational modifications of cysteine thiols of p21ras associated with redox modulation of activity using isotope-coded affinity tags and mass spectrometry

p21ras GTPase is the protein product of the most commonly mutated human oncogene and has been identified as a target for reactive oxygen and nitrogen species. Posttranslational modification of reactive thiols, by reversible S-glutathiolation and S-nitrosation, and potentially also by irreversible oxidation, may have significant effects on p21ras activity. Here we used an isotope-coded affinity tag (ICAT) and mass spectrometry to quantitate the reversible and irreversible oxidative posttranslational thiol modifications of p21ras caused by peroxynitrite (ONOO(-)) or glutathione disulfide (GSSG). The activity of p21ras was significantly increased after exposure to GSSG, but not to ONOO(-). The results of LC-MS/MS analysis of tryptic peptides of p21ras treated with ONOO(-) showed that ICAT labeling of Cys(118) was decreased by 47%, whereas Cys(80) was not significantly affected and was thereby shown to be less reactive. The extent of S-glutathiolation of Cys(118) by GSSG was 53%, and that of the terminal cysteines was 85%, as estimated by the decrease in ICAT labeling. The changes in ICAT labeling caused by GSSG were reversible by chemical reduction, but those caused by peroxynitrite were irreversible. The quantitative changes in thiol modification caused by GSSG associated with increased activity demonstrate the potential importance of redox modulation of p21ras.     

Mechanism of the severe inhibition of tetrachlorohydroquinone dehalogenase by its aromatic substrates

Tetrachlorohydroquinone (TCHQ) dehalogenase catalyzes the conversion of TCHQ to 2,6-dichlorohydroquinone during degradation of pentachlorophenol by Sphingobium chlorophenolicum. TCHQ dehalogenase is a member of the glutathione S-transferase superfamily. Members of this superfamily typically catalyze nucleophilic attack of glutathione upon an electrophilic substrate to form a glutathione conjugate and contain a single glutathione binding site in each monomer of the typically dimeric enzyme. TCHQ dehalogenase, in contrast to most members of the superfamily, is a monomer and uses 2 equiv of glutathione to catalyze a more complex reaction. The first glutathione is involved in formation of a glutathione conjugate, while the second is involved in the final step of the reaction, a thiol-disulfide exchange reaction that regenerates the free enzyme and forms GSSG. TCHQ dehalogenase is severely inhibited by its aromatic substrates, TCHQ and trichlorohydroquinone (TriCHQ). TriCHQ acts as a noncompetitive inhibitor of the thiol-disulfide exchange reaction required to regenerate the free form of the enzyme. In addition, dissociation of the GSSG product is inhibited by TriCHQ. The thiol-disulfide exchange reaction is the rate-limiting step in the reductive dehalogenation reaction under physiological conditions.     

Increasing the reactivity of an artificial dithiol-disulfide pair through modification of the electrostatic milieu

The thiol-disulfide exchange reaction plays a central role in the formation of disulfide bonds in newly synthesized proteins and is involved in many aspects of cellular metabolism. Because the thiolate form of the cysteine residue is the key reactive species, its electrostatic milieu is thought to play a key role in determining the rates of thiol disulfide exchange reactions. While modest reactivity effects have previously been seen in peptide model studies, here, we show that introduction of positive charges can have dramatic effects on disulfide bond formation on a structurally restricted surface. We have studied properties of vicinal cysteine residues in proteins using a model system based on redox-sensitive yellow fluorescent protein (rxYFP). In this system, the formation of a disulfide bond between two cysteines Cys149 and Cys202 is accompanied by a 2.2-fold decrease in fluorescence. Introduction of positively charged amino acids in the proximity of the two cysteines resulted in an up to 13-fold increase in reactivity toward glutathione disulfide. Determination of the individual pK(a) values of the cysteines showed that the observed increase in reactivity was caused by a decrease in the pK(a) value of Cys149, as well as favorable electrostatic interactions with the negatively charged reagents. The results presented here show that the electrostatic milieu of cysteine thiols in proteins can have substantial effects on the rates of the thiol-disulfide exchange reactions.     

Glutathionylation of trypanosomal thiol redox proteins

Trypanosomatids, the causative agents of several tropical diseases, lack glutathione reductase and thioredoxin reductase but have a trypanothione reductase instead. The main low molecular weight thiols are trypanothione (N(1),N(8)-bis-(glutathionyl)spermidine) and glutathionyl-spermidine, but the parasites also contain free glutathione. To elucidate whether trypanosomes employ S-thiolation for regulatory or protection purposes, six recombinant parasite thiol redox proteins were studied by ESI-MS and MALDI-TOF-MS for their ability to form mixed disulfides with glutathione or glutathionylspermidine. Trypanosoma brucei mono-Cys-glutaredoxin 1 is specifically thiolated at Cys(181). Thiolation of this residue induced formation of an intramolecular disulfide bridge with the putative active site Cys(104). This contrasts with mono-Cys-glutaredoxins from other sources that have been reported to be glutathionylated at the active site cysteine. Both disulfide forms of the T. brucei protein were reduced by tryparedoxin and trypanothione, whereas glutathione cleaved only the protein disulfide. In the glutathione peroxidase-type tryparedoxin peroxidase III of T. brucei, either Cys(47) or Cys(95) became glutathionylated but not both residues in the same protein molecule. T. brucei thioredoxin contains a third cysteine (Cys(68)) in addition to the redox active dithiol/disulfide. Treatment of the reduced protein with GSSG caused glutathionylation of Cys(68), which did not affect its capacity to catalyze reduction of insulin disulfide. Reduced T. brucei tryparedoxin possesses only the redox active Cys(32)-Cys(35) couple, which upon reaction with GSSG formed a disulfide. Also glyoxalase II and Trypanosoma cruzi trypanothione reductase were not sensitive to thiolation at physiological GSSG concentrations.     

The utility of N,N-biotinyl glutathione disulfide in the study of protein S-glutathiolation

Glutathione disulfide (GSSG) accumulates in cells under an increased oxidant load, which occurs during neurohormonal or metabolic stimulation as well as in many disease states. Elevated GSSG promotes protein S-glutathiolation, a reversible post-translational modification, which can directly alter or regulate protein function. We developed novel strategies for the study of protein S-glutathiolation that involved the simple synthesis of N,N-biotinyl glutathione disulfide (biotin-GSSG). Biotin-GSSG treatment of cells mimics a defined component of oxidative stress, namely a shift in the glutathione redox couple to the oxidized disulfide state. This induces widespread protein S-glutathiolation, which was detected on non-reducing Western blots probed with streptavidin-horseradish peroxidase and imaged using confocal fluorescence microscopy and ExtrAvidin-FITC. S-Glutathiolated proteins were purified using streptavidin-agarose and identified using proteomic methods. We conclude that biotin-GSSG is a useful tool in the investigation of protein S-glutathiolation and offers significant advantages over conventional methods or antibody-based strategies. These novel approaches may find widespread utility in the study of disease or redox signaling models where GSSG accumulation occurs.     

Shear-induced disulfide bond formation regulates adhesion activity of von Willebrand factor

von Willebrand factor (VWF) is the largest multimeric adhesion ligand circulating in blood. Its adhesion activity is related to multimer size, with the ultra-large forms freshly released from the activated endothelial cells being most active, capable of spontaneously binding to platelets. In comparison, smaller plasma forms circulating in blood bind platelets only under high fluid shear stress or induced by modulators. The structure-function relationships that distinguish the two types of VWF multimers are not known. In this study, we demonstrate that some of the plasma VWF multimers contain surface-exposed free thiols. Physiological and pathological levels of shear stresses (50 and 100 dynes/cm(2)) promote the formation of disulfide bonds utilizing these free thiols. The shear-induced thiol-disulfide exchange increases VWF binding to platelets. The thiol-disulfide exchange involves some or all of nine cysteine residues (Cys(889), Cys(898), Cys(2448), Cys(2451), Cys(2490), Cys(2491), Cys(2453), Cys(2528), and Cys(2533)) in the D3 and C domains as determined by mass spectrometry of the tryptic VWF peptides. These results suggest that the thiol-disulfide state may serve as an important structural determinant of VWF adhesion activity and can be modified by fluid shear stress.     

Oxidation and S-nitrosylation of cysteines in human cytosolic and mitochondrial glutaredoxins: effects on structure and activity

Glutathione (GSH) is the major intracellular thiol present in 1-10-mm concentrations in human cells. However, the redox potential of the 2GSH/GSSG (glutathione disulfide) couple in cells varies in association with proliferation, differentiation, or apoptosis from -260 mV to -200 or -170 mV. Hydrogen peroxide is transiently produced as second messenger in receptor-mediated growth factor signaling. To understand oxidation mechanisms by GSSG or nitric oxide-related nitrosylation we studied effects on glutaredoxins (Grx), which catalyze GSH-dependent thiol-disulfide redox reactions, particularly reversible glutathionylation of protein sulfhydryl groups. Human Grx1 and Grx2 contain Cys-Pro-Tyr-Cys and Cys-Ser-Tyr-Cys active sites and have three and two additional structural Cys residues, respectively. We analyzed the redox state and disulfide pairing of Cys residues upon GSSG oxidation and S-nitrosylation. Cytosolic/nuclear Grx1 was partly inactivated by both S-nitrosylation and oxidation. Inhibition by nitrosylation was reversible under anaerobic conditions; aerobically it was stronger and irreversible, indicating inactivation by nitration. Oxidation of Grx1 induced a complex pattern of disulfide-bonded dimers and oligomers formed between Cys-8 and either Cys-79 or Cys-83. In addition, an intramolecular disulfide between Cys-79 and Cys-83 was identified, predicted to have a profound effect on the three-dimensional structure. In contrast, mitochondrial Grx2 retains activity upon oxidation, did not form disulfide-bonded dimers or oligomers, and could not be S-nitrosylated. The dimeric iron sulfur cluster-coordinating inactive form of Grx2 dissociated upon nitrosylation, leading to activation of the protein. The striking differences between Grx1 and Grx2 reflect their diverse regulatory functions in vivo and also adaptation to different subcellular localization.     

A trade-off between catalytic power and substrate inhibition in TCHQ dehalogenase

Tetrachlorohydroquinone (TCHQ) dehalogenase is profoundly inhibited by its aromatic substrates, TCHQ and trichlorohydroquinone (TriCHQ). Surprisingly, mutations that change Ile12 to either Ser or Ala give an enzyme that shows no substrate inhibition. We have previously shown that TriCHQ is a noncompetitive inhibitor of the thiol-disulfide exchange reaction between glutathione and ESSG, a covalent adduct between Cys13 and glutathione formed during dehalogenation of the substrate. Substrate inhibition of the thiol-disulfide exchange reaction is less severe in the I12S and I12A mutant enzymes, primarily due to weaker binding of TriCHQ to ESSG. These mutations also result in a decrease in the rate of dehalogenation. Because the rate-limiting step in the I12S and I12A enzymes is dehalogenation, rather than the thiol-disulfide exchange reaction, the relatively modest inhibition of the thiol-disulfide exchange reaction does not affect the overall rate of turnover.     

Redox regulation of a soybean tyrosine-specific protein phosphatase

Plant protein tyrosine phosphatases (PTPs) are important in regulating cellular responses to redox change through their reversible inactivation under oxidative conditions. Studies on the soybean (Glycine max) GmPTP have shown that, compared with its mammalian counterparts, the plant enzyme is relatively insensitive to inactivation by H2O2 but hypersensitive (k(inact) = 559 M(-1) s(-1)) to S-glutathionylation (thiolation) promoted by the presence of oxidized glutathione (GSSG). Through a combination of chemical and mutational modification studies, three of the seven cysteine residues of GmPTP have been identified by mass spectrometry as being able to inactivate the enzyme when thiolated by GSSG or alkylated with iodoacetamide. Conserved Cys 266 was shown to be essential for catalysis but surprisingly resistant to S-modification, whereas the regulatory Cys 78 and Cys 176 were readily thiolated and/or alkylated. Mutagenesis of these cysteines showed that all three residues were in proximity of each other, regulating each's reactivity to S-modifying agents. Through a combination of protein modification and kinetic experiments, we conclude that the inactivation of GmPTP by GSSG is regulated at two levels. Cys 176 appears to be required to promote the formation of the reduced form of Cys 266, which is otherwise unreactive. When thiolated, Cys 176 immediately inactivates the enzyme, and this is followed by the thiolation of Cys 78, which undergoes a slow disulfide exchange with Cys 266 giving rise to a Cys 78-Cys 266 disulfide. We speculate that this two-tiered protection is required for regulation of GmPTP under highly oxidizing conditions.     

嗜酸氧化亚铁硫杆菌的谷胱甘肽还原酶的结构模建和底物分子对接

极端环境微生物嗜酸氧化亚铁硫杆菌的谷胱甘肽还原酶(GR)可能在它的抵抗极端酸性,有毒和氧化性的生物浸出环境中发挥至关重要的作用.通过同源模建技术和分子动力学模拟,它的一个三维结构被构建,优化和检验了.获得的结构被进一步用于搜索绑定位点,跟辅因子黄素腺嘌呤二核苷酸(FAD)和底物谷胱甘肽(GSSG)进行分子柔性对接,并以此识别关健残基.对接结果显示,位于活性残基Cys42和Cys47之间的二硫键夹在FAD的活性位点和底物GSSG的二硫键之间.它们之间的距离非常靠近,这跟底物反应机理的初始步骤的情况十分一致.相互作用能表明8个酶中残基Cys42,Cys47,GIu443B,Glu444B,His438B,Ser14,Thr447B和Lys51是固定或激活GSSG的关键残基,这跟以前的实验事实相吻合.此外,根据相互作用能我们还新发现7个重要残基(Arg449B,Pro439B,Thr440B,Thr310,Va143,Gly46 and Va148).所有这些残基在其它物种中的相应物中也都是保守的.这些结果有助于进一步的实验研究和理解其催化机理,进而揭示这种细菌的抗毒机理,服务于工业应用.     

Redox regulation of yeast flavin-containing monooxygenase

The flavin-dependent monooxygenase from yeast (yFMO) oxidizes biological thiols such as cysteine, cysteamine, and glutathione. The enzyme makes a major contribution to the pools of oxidized thiols that, together with reduced glutathione from glutathione reductase, create the optimum cellular redox environment. We show that the activity of yFMO, as a soluble enzyme or in association with the ER membrane of microsomal fractions, is correlated with the redox potential. The enzyme is active under conditions normally found in the cytoplasm, but is inhibited as GSSG accumulates to give a redox potential similar to that found in the lumen of the ER. Site-directed mutations show that Cys 353 and Cys 339 participate in the redox regulation. Cys 353 is the principal residue in the redox-sensitive switch. We hypothesize that it may initiate formation of a mixed disulfide that is partially inhibitory to yFMO. The mixed disulfide may exchange with Cys 339 to form an intramolecular disulfide bond that is fully inhibitory.     

Molecular basis and structural insight of vascular K(ATP) channel gating by S-glutathionylation

The vascular ATP-sensitive K(+) (K(ATP)) channel is targeted by a variety of vasoactive substances, playing an important role in vascular tone regulation. Our recent studies indicate that the vascular K(ATP) channel is inhibited in oxidative stress via S-glutathionylation. Here we show evidence for the molecular basis of the S-glutathionylation and its structural impact on channel gating. By comparing the oxidant responses of the Kir6.1/SUR2B channel with the Kir6.2/SUR2B channel, we found that the Kir6.1 subunit was responsible for oxidant sensitivity. Oxidant screening of Kir6.1-Kir6.2 chimeras demonstrated that the N terminus and transmembrane domains of Kir6.1 were crucial. Systematic mutational analysis revealed three cysteine residues in these domains: Cys(43), Cys(120), and Cys(176). Among them, Cys(176) was prominent, contributing to >80% of the oxidant sensitivity. The Kir6.1-C176A/SUR2B mutant channel, however, remained sensitive to both channel opener and inhibitor, which indicated that Cys(176) is not a general gating site in Kir6.1, in contrast to its counterpart (Cys(166)) in Kir6.2. A protein pull-down assay with biotinylated glutathione ethyl ester showed that mutation of Cys(176) impaired oxidant-induced incorporation of glutathione (GSH) into the Kir6.1 subunit. In contrast to Cys(176), Cys(43) had only a modest contribution to S-glutathionylation, and Cys(120) was modulated by extracellular oxidants but not intracellular GSSG. Simulation modeling of Kir6.1 S-glutathionylation suggested that after incorporation to residue 176, the GSH moiety occupied a space between the slide helix and two transmembrane helices. This prevented the inner transmembrane helix from undergoing conformational changes necessary for channel gating, retaining the channel in its closed state.     

A mechanistic investigation of the thiol-disulfide exchange step in the reductive dehalogenation catalyzed by tetrachlorohydroquinone dehalogenase

Tetrachlorohydroquinone dehalogenase catalyzes the reductive dehalogenation of tetrachloro- and trichlorohydroquinone to give 2,6-dichlorohydroquinone in the pathway for degradation of pentachlorophenol by Sphingobium chlorophenolicum. Previous work has suggested that this enzyme may have originated from a glutathione-dependent double bond isomerase such as maleylacetoacetate isomerase or maleylpyruvate isomerase. While some of the elementary steps in these two reactions may be similar, the final step in the dehalogenation reaction, a thiol-disulfide exchange reaction that removes glutathione covalently bound to Cys13, certainly has no counterpart in the isomerization reaction. The thiol-disulfide exchange reaction does not appear to have been evolutionarily optimized. There is little specificity for the thiol; many thiols react at high rates. TCHQ dehalogenase binds the glutathione involved in the thiol-disulfide exchange reaction very poorly and does not alter its pK(a) in order to improve its nucleophilicity. Remarkably, single-turnover kinetic studies show that the enzyme catalyzes this step by approximately 10000-fold. This high reactivity requires an as yet unidentified protonated group in the active site.     

Changes in the glutathione thiol-disulfide status of Neurospora crassa conidia during germination and aging.

Improved methods were developed for the determination of reduced glutathione (GSH), glutathione disulfide (GSSG), and protein-glutathione disulfide (PSSG) and applied to determine the glutathione status at various stages of the asexual life cycle for the band strain of Neurospora crassa. The GSH-GSSG ratio in freshly harvested dry conidia was found to be about 150 but decreased to around 6 when dryconidia were aged (stored) for 10 days after harvest. When conidia were germinated, this ratio increased to about 300 during the first 10 min of the 6-h germination process. In mycelia, during log-phase growth, the ratio was about 10-3. Changes in the ratio occurred primarily through changes in the GSSG content, which ranges from about 0.023 (mycelia) to 2(10-day aged conidia) mumol per g (dry weight) of residue, whereas GSH levels varied by a factor of about two. The PSSG content varied from 0.02 (mycelia) to 0.6 (10-day aged conidia) mumol per g (dry weight) of residue and generally paralleled the GSSG content. The results demonstrate the potential importance of thiol-disulfide reactions as a mechanism for the control of physiological properties associated with dormancy, and the observed changes in GSSG level are found to be compatible with the view that GSSG plays a role in the regulation of protein synthesis through control of polysome formation.     

Cysteine reactivity in Thermoanaerobacter brockii alcohol dehydrogenase.

The free cysteine residues in the extremely thermophilic Thermoanaerobacter brockii alcohol dehydrogenase (TBADH) were characterized using selective chemical modification with the stable nitroxyl biradical bis(1-oxy-2,2,5,5-tetramethyl-3-imidazoline-4-yl)disulfide, via a thiol-disulfide exchange reaction and with 2[14C]iodoacetic acid, via S-alkylation. The respective reactions were monitored by electron paramagenetic resonance (EPR) and by the incorporation of the radioactive label. In native TBADH, the rapid modification of one cysteine residue per subunit by the biradical and the concomitant loss of catalytic activity was reversed by DTT. NADP protected the enzyme from both modification and inactivation by the biradical. RPLC fingerprint analysis of reduced and S-carboxymethylated lysyl peptides from the radioactive alkylated enzyme identified Cys 203 as the readily modified residue. A second cysteine residue was rapidly modified with both modification reagents when the catalytic zinc was removed from the enzyme by o-phenanthroline. This cysteine residue, which could serve as a putative ligand to the active-site zinc atom, was identified as Cys 37 in RPLC. The EPR data suggested a distance of < or 10 A between Cys 37 and Cys 203. Although Cys 283 and Cys 295 were buried within the protein core and were not accessible for chemical modification, the two residues were oxidized to cystine when TBADH was heated at 75 degrees C, forming a disulfide bridge that was not present in the native enzyme, without affecting either enzymatic activity or thermal stability. The status of these cysteine residues was verified by site directed mutagenesis.     

Modulating effect of thiol-disulfide status on [14C]aminopyrine accumulation in the isolated parietal cell

Thiol-oxidizing agents were found to stimulate [14C] aminopyrine accumulation, a reliable index of acid secretory function of isolated canine parietal cells. Glutathione is the predominant intracellular free thiol; thus, its oxidation status largely determines the thiol-disulfide status of the cell by thiol-disulfide interchange reactions. Three agents which alter glutathione oxidation status by different mechanisms were applied to parietal cells in vitro to investigate whether enhanced formation of GSSG alters acid secretory function. The agents studied were diamide (which nonenzymatically oxidizes GSH to GSSG), tert-butyl hydroperoxide (an organic peroxide specifically reduced by glutathione peroxidase, thereby generating GSSG for GSH), and 1,3-bis(2-chloroethyl)-1-nitrosourea (an inhibitor of NADPH:GSSG reductase, which presumably allows the accumulation of GSSG). Each of these agents stimulated aminopyrine accumulation in a dose-dependent fashion. Simple depletion of GSH by diethyl maleate or 2-cyclohexene-1-one did not stimulate aminopyrine accumulation. Likewise, enhanced aminopyrine accumulation occurred at diamide concentrations which did not cause significant depletion of total cellular glutathione. The thiol-reducing agent, dithiothreitol, prevented enhanced aminopyrine accumulation by 1,3-bis(2-chloroethyl)-1-nitrosourea and tert-butyl hydroperoxide. These observations support the hypothesis that thiol-disulfide interchange reactions involving GSSG modulate the acid secretory function of the isolated parietal cell.     

Stability and structure-forming properties of the two disulfide bonds of alpha-conotoxin GI

alpha-Conotoxin GI is a 13 residue snail toxin peptide cross-linked by Cys2-Cys7 and Cys3-Cys13 disulfide bridges. The formation of the two disulfide bonds by thiol/disulfide exchange with oxidized glutathione (GSSG) has been characterized. To characterize formation of the first disulfide bond in each of the two pathways by which the two disulfide bonds can form, two model peptides were synthesized in which Cys3 and Cys13 (Cono-1) or Cys2 and Cys7 (Cono-2) were replaced by alanines. Equilibrium constants were determined for formation of the single disulfide bonds of Cono-1 and Cono-2, and an overall equilibrium constant was measured for formation of the two disulfide bonds of alpha-conotoxin GI in pH 7.00 buffer and in pH 7. 00 buffer plus 8 M urea using concentrations obtained by HPLC analysis of equilibrium thiol/disulfide exchange reaction mixtures. The results indicate a modest amount of cooperativity in the formation of the second disulfide bond in both of the two-step pathways by which alpha-conotoxin GI folds into its native structure at pH 7.00. However, when considered in terms of the reactive thiolate species, the results indicate substantial cooperativity in formation of the second disulfide bond. The solution conformational and structural properties of Cono-1, Cono-2, and alpha-conotoxin GI were studied by 1H NMR to identify structural features which might facilitate formation of the disulfide bonds or are induced by formation of the disulfide bonds. The NMR data indicate that both Cono-1 and Cono-2 have some secondary structure in solution, including some of the same secondary structure as alpha-conotoxin GI, which facilitates formation of the second disulfide bond by thiol/disulfide exchange. However, both Cono-1 and Cono-2 are considerably less structured than alpha-conotoxin GI, which indicates that formation of the second disulfide bond to give the Cys2-Cys7, Cys3-Cys13 pairing induces considerable structure into the backbone of the peptide.