S-thiolation of creatine kinase and glycogen phosphorylase b initiated by partially reduced oxygen species

S-thiolation of cardiac creatine kinase and skeletal muscle glycogen phosphorylase b was initiated by reduced oxygen species in reaction mixtures containing reduced glutathione. Both proteins were extensively modified at similar rates under conditions in which the oxidation of glutathione was inadequate to cause S-thiolation by thiol-disulfide exchange. Creatine kinase was both S-thiolated and non-reducibly oxidized at the same time at low glutathione concentration. The amount of each modification was decreased by adding additional reduced glutathione, and with adequate glutathione oxidation was prevented while S-thiolation was still very active. S-thiolation of glycogen phosphorylase b was not significantly affected by glutathione concentration and non-reducible oxidation of glycogen phosphorylase b was not observed. These experiments suggest that oxyradical or H2O2-initiated processes may be an important mechanism of protein S-thiolation during oxidative stress, and that the cellular concentration of glutathione may be an important factor in S-thiolation of different proteins. Both creatine kinase and glycogen phosphorylase b competed favorably with ferricytochrome c for superoxide anion in the standard xanthine oxidase system for the generation of oxyradicals and H2O2. These proteins were as effective as ascorbate and much more effective than reduced glutathione in this regard. Ascorbate was also an effective inhibitor of oxyradical-initiated S-thiolation of creatine kinase, suggesting a role of superoxide anion in protein S-thiolation. Other experiments showed that both catalase and superoxide dismutase could partially inhibit protein S-thiolation. Thus, reduced oxygen species may react with protein sulfhydryls resulting in S-thiolation by a mechanism that involves the reaction of an activated protein thiol with reduced glutathione.     

The mechanisms of reduction of protein mixed disulfides (dethiolation) in cardiac tissue

Dethiolation of proteins (reduction of protein mixed disulfides) by NADPH-dependent and glutathione (GSH)-dependent enzymes, and by nonenzymatic reaction with GSH, was studied by electrofocusing methodology with glycogen phosphorylase b and creatine kinase as substrates. Phosphorylase b was not rapidly dethiolated by reduced glutathione alone, but a cardiac extract catalyzed rapid dethiolation by both an NADPH-dependent and a GSH-dependent process. In contrast, creatine kinase was actively dethiolated by GSH. This GSH-dependent dethiolation was not enhanced by a soluble extract of bovine heart. Creatine kinase was also not dethiolated by an NADPH-dependent process. Partial purification of the phosphorylase dethiolases showed that the NADPH-dependent dethiolase had both a high-molecular-weight and a low-molecular-weight component The properties of these components were similar to those of thioredoxin and thioredoxin reductase. These two components were sensitive to inhibition by phenylarsine oxide and inhibition was reversed by addition of a dithiol. In contrast, GSH-dependent dethiolation required a single component of low molecular weight. This process was less sensitive to phenylarsine oxide inhibition. These studies show that two cytosolic proteins, phosphorylase b and creatine kinase, were dethiolated by different mechanisms. Phosphorylase b was dethiolated by both NADPH-dependent and GSH-dependent enzymes found in a soluble extract of bovine heart. In contrast, creatine kinase was rapidly dethiolated nonenzymatically by GSH alone.     

Reduction (dethiolation) of protein mixed-disulfides; distribution and specificity of dethiolating enzymes and N,N'-bis(2-chlorethyl)-N-nitrosourea inhibition of an NADPH-dependent cardiac dethiolase

The S-thiolated proteins phosphorylase b (Phb) and carbonic anhydrase III (CAIII) were prepared with [3H]glutathione in a reaction initiated with diamide. These substrates were used to measure the rate of reduction (dethiolation) of protein mixed-disulfides by enzymes with properties similar to those of thioredoxin and glutaredoxin. This enzyme activity is termed a dethiolase since the identities of the enzymes are still unknown. The dethiolation of either S-[3H]glutathiolated Phb or S-[3H]glutathiolated CAIII was employed in tissue assays and for study of two partially purified dethiolases from cardiac tissue. NADPH-dependent dethiolase activity was most abundant except in rat liver and muscle. Total dethiolase activity was approximately 10-fold higher in neutrophils, 3T3-L1 cells, and Escherichia coli than in other sources. Rat skeletal muscle had 3- to 4-fold higher dethiolase activity than rat heart or liver. These data indicate that protein dethiolase activity is ubiquitous and that normal expression of the two dethiolase activities varies considerably. A partially purified cardiac NADPH-dependent dethiolase acted on Phb approximately 1.5 times faster than CAIII, and a glutathione (GSH)-dependent dethiolase acted on Phb 3 times faster than CAIII. The Km for glutathione for the GSH-dependent dethiolase was 15 microM with Phb as substrate and 10 microM with CAIII. Thus, the GSH-dependent dethiolase is probably not affected by normal changes in the cardiac glutathione content (normally approximately 3 mM). Partially purified cardiac NADPH-dependent dethiolase was inactivated by BCNU (N,N'-bis(2-chloroethyl)-N-nitrosourea) and the GSH-dependent dethiolase was unaffected under similar conditions. In a soluble extract from bovine heart, 200 microM BCNU inhibited NADPH-dependent dethiolase by more than 60% but did not affect GSH-dependent activity. These results demonstrate that BCNU is a selective inhibitor of the NADPH-dependent dethiolase.     

A thin-gel isoelectric focusing method for quantitation of protein S-thiolation

A thin-gel isoelectric focusing method has been developed for analysis of protein S-thiolation (formation of mixed disulfides with low molecular weight thiols). The method is rapid and it can be used with 3 to 5 micrograms of a pure protein, or 15 to 20 micrograms of tissue extract protein. It is possible to detect a modification of the protein sulfhydryl by either charged or uncharged thiols, and to determine the quantity of different S-thiolated protein species in a modified sample. The method was used to quantitate the amount of S-thiolation of phosphorylase b in a reaction with oxidized glutathione that produced four S-thiolated forms of the enzyme. The method was also used to detect S-thiolation of two proteins in a cardiac tissue extract treated with diamide. One of the protein bands was shown to be S-thiolated with both cysteine and glutathione, while the other band was S-thiolated only with glutathione.     

S-thiolation of cytoplasmic cardiac creatine kinase in heart cells treated with diamide

Two methods for quantitation of protein S-thiolation, by isoelectric focusing or by enzyme activity, were used for studying S-thiolation of cytoplasmic cardiac creatine kinase. With these methods, creatine kinase was identified as a major S-thiolated protein in both bovine and rat heart. In rat heart cell cultures, creatine kinase became 10% S-thiolated during a 10 min incubation with 0.2 mM diamide. This enzyme became S-thiolated more slowly than other heart cell proteins and it also dethiolated more slowly. Two sequential additions of diamide at a 25 min interval caused twice as much S-thiolation after the second addition as compared to the first. This increased sensitivity to the second diamide treatment may have resulted from glutathione loss during the first addition which produced a higher GSSG-to-GSH ratio after the second treatment. The GSSG-to-GSH ratio was highest prior to the maximum S-thiolation of creatine kinase, but, in general, the time course of glutathione was similar to the S-thiolation of creatine kinase. This study demonstrates that cytoplasmic creatine kinase is S-thiolated and, therefore, inhibited during a diamide-induced oxidative stress in heart cells. Implications for regulation of cardiac metabolism during oxidative stress are discussed.     

Regulation of protein S-thiolation by glutaredoxin 5 in the yeast Saccharomyces cerevisiae

The irreversible oxidation of cysteine residues can be prevented by protein S-thiolation, a process by which protein -SH groups form mixed disulfides with low molecular weight thiols such as glutathione. We report here that this protein modification is not a simple response to the cellular redox state, since different oxidants lead to different patterns of protein S-thiolation. SDS-polyacrylamide gel electrophoresis shows that glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is the major target for modification following treatment with hydroperoxides (hydrogen peroxide or tert-butylhydroperoxide), whereas this enzyme is unaffected following cellular exposure to the thiol oxidant diamide. Further evidence that protein S-thiolation is tightly regulated in response to oxidative stress is provided by the finding that the Tdh3 GAPDH isoenzyme, and not the Tdh2 isoenzyme, is S-thiolated following exposure to H(2)O(2) in vivo, whereas both GAPDH isoenzymes are S-thiolated when H(2)O(2) is added to cell-free extracts. This indicates that cellular factors are likely to be responsible for the difference in GAPDH S-thiolation observed in vivo rather than intrinsic structural differences between the GAPDH isoenzymes. To begin to search for factors that can regulate the S-thiolation process, we investigated the role of the glutaredoxin family of oxidoreductases. We provide the first evidence that protein dethiolation in vivo is regulated by a monothiol-glutaredoxin rather than the classical glutaredoxins, which contain two active site cysteine residues. In particular, glutaredoxin 5 is required for efficient dethiolation of the Tdh3 GAPDH isoenzyme.     

Formation of mixed disulfide of cystatin-beta in cultured macrophages treated with various oxidants

Macrophage cell cultures were treated with menadione, zymosan, or phorbol myristate acetate (PMA), and changes in productions of superoxide anion and hydroperoxide, and in glutathione oxidation and S-thiolation of cystatin-beta (formation of a mixed disulfide of cystatin-beta and glutathione) were examined. All three compounds promoted production of superoxide anion and hydroperoxide, but only menadione caused extensive oxidation of glutathione. Menadione caused S-thiolation of cystatin-beta in a dose-dependent fashion, but the other two compounds did not. Removal of menadione promptly reduced the oxidation of glutathione and S-thiolation of cystatin-beta induced by menadione. Inhibition of catalase by aminotriazol caused slight increase in the GSSG content in both menadione- and zymosan-treated cells, but not in S-thiolation of cystatin-beta in zymosan-treated cells. None of the three compounds influenced appreciably the activity of glutathione peroxidase, glutathione reductase, or superoxide dismutase in cultured cells. These results indicate that S-thiolation of cystatin-beta occurs in cells in response to oxidative challenge by menadione but not by zymosan or by the tumor promoter PMA. Dethiolation of cystatin-beta by purified thiol transferase and protein disulfide isomerase in the presence of different concentrations of GSH was examined in vitro. Both enzymes catalyzed dethiolation of cystatin-beta at a much lower level of GSH than that required for the non-enzymatic reaction, suggesting the importance of enzymatic catalysis of S-thiolation and dethiolation of cystatin-beta in cells.     

Phagocytosis and stimulation of the respiratory burst by phorbol diester initiate S-thiolation of specific proteins in macrophages.

Addition of chemical oxidants to cells in culture has been shown to induce binding of low-molecular-weight thiols to reactive sulfhydryls on proteins in a process termed S-thiolation. We found that stimulation of the respiratory burst in mouse macrophages, with release of O2-, resulted in S-thiolation of several proteins, most prominently three with molecular weights of 74, 33, and 22 kDa. One protein (28 kDa) was S-thiolated without addition of an exogenous stimulus. Exposure of cells to concentrations of hydrogen peroxide like those released in the respiratory burst induced S-thiolation of these same proteins. S-thiolation and release of O2- began at approximately the same time. Stimulation of LPS-elicited macrophages induced prominent S-thiolation of three different proteins (38, 30, and 21 kDa). Under the conditions of these experiments, there was no detectable increase in glutathione disulfide and a negligible decrease in glutathione, which suggests that S-thiolation can occur without significant perturbation of the glutathione peroxidase/reductase cycle. S-thiolation of proteins could help protect the macrophage against the autoxidative damage associated with the respiratory burst. Modification of specific proteins by S-thiolation might serve to modulate cellular metabolic events.     

Irreversible thiol oxidation in carbonic anhydrase III: protection by S-glutathiolation and detection in aging rats

Proteins with reactive sulfhydryls are central to many important metabolic reactions and also contribute to a variety of signal transduction systems. In this report, we examine the mechanisms of oxidative damage to the two reactive sulfhydryls of carbonic anhydrase III. Hydrogen peroxide (H2O2), peroxy radicals, or hypochlorous acid (HOCl) produced irreversibly oxidized forms, primarily cysteine sulfinic acid or cysteic acid, of carbonic anhydrase III if glutathione (GSH) was not present. When GSH was approximately equimolar to protein thiols, irreversible oxidation was prevented. H202 and peroxyl radicals both generated S-glutathiolated carbonic anhydrase III via partially oxidized protein sulfhydryl intermediates, while HOCl did not cause S-glutathiolation. Thus, oxidative damage from H202 or AAPH was prevented by protein S-glutathiolation, while a direct reaction between GSH and oxidant likely prevents HOCl-mediated protein damage. In cultured rat hepatocytes, carbonic anhydrase III was rapidly S-glutathiolated by menadione. When hepatocyte glutathione was depleted, menadione instead caused irreversible oxidation. We hypothesized that normal depletion of glutathione in aged animals might also lead to an increase in irreversible oxidation. Indeed, both total protein extracts and carbonic anhydrase III contained significantly more cysteine sulfinic acid in older rats compared to young animals. These experiments show that, in the absence of sufficient GSH, oxidation reactions lead to irreversible protein sulfhydryl damage in purified proteins, cellular systems, and whole animals.     

The disulfide structure of bovine pituitary basic fibroblast growth factor.

Basic fibroblast growth factor has 4 cysteine residues in its amino acid sequence, two of which are perfectly conserved within the fibroblast growth factor family of proteins suggesting a disulfide bond at this position. Furthermore, thiol titration of bovine pituitary basic fibroblast growth factor (bFGF) indicates the presence of two free thiols, which is consistent with an intramolecular disulfide. Direct analysis of natural and recombinant fibroblast growth factor proteins have not confirmed the existence of such a disulfide. Instead, the two nonconserved cysteines of bFGF purified from bovine pituitaries are S-thiolated with glutathione. Inclusion of 75 mM N-ethylmaleimide during the homogenization of the pituitaries effectively blocks the S-thiolation, demonstrating that this modification is an artifact of the purification procedure. Analysis of the N-ethylmaleimide purified bovine pituitary bFGF suggests that the natural protein is in the correct redox state when all 4 cysteines are in the reduced form.     

Hemoglobin S-thiolation during peroxide-induced oxidative stress in chicken blood

Protein S-thiolation or protein-glutathione mixed disulfide (PSSG) occurs when cells are exposed to oxidative stress, and has been implicated in several cellular functions. The S-thiolation of hemoglobin as well as other abundant proteins is proposed to participate as a redox buffer, being part of the antioxidant protection system of the cell during the oxidative challenge. We studied the oxidative stress caused by peroxides (H(2)O(2), cumene and tert-butyl hydroperoxide) on chicken blood by measuring the thiol/disulfide status. Chicken blood under peroxide treatment showed a time- and concentration-dependent increase in glutathione disulfide (GSSG) and PSSG. GSSG peaked immediately after treatment (1 min), while PSSG increased progressively over time, showing a maximum after about 30 min. The system recovered after 140 min of incubation, with GSSG and PSSG then barely reaching control values. The S-thiolation of hemoglobin was monitored under nondenaturing PAGE, and the fraction of S-thiolated hemoglobin, or Hb A1, rose in a dose-dependent fashion and was proportional to total S-thiolation, measured as PSSG. This significant correlation indicates that hemoglobin is the major S-thiolated protein in chicken erythrocytes treated with peroxides. The present work shows the behavior of chicken blood under peroxide treatment; it anticipated that chicken hemoglobin thiol groups can actively participate in the redox processes of erythrocytes exposed to oxidative stress, and that hemoglobin is the major S-thiolated protein. This further corroborates the hypothesis that abundant proteins, such as hemoglobin, may take part in the cellular antioxidant defense system.     

The mouse liver content of carbonic anhydrase III and glutathione S-tranferases A3 and P1 depend on dietary supply of methionine and cysteine

The contents of glutathione S-transferase (GST) subunits, carbonic anhydrase III (CAIII), glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and a 230 kDa protein are affected by protein deprivation in mouse liver. In order to know if particular amino acids control these contents, the effects of feeding for 5 days with diets containing different amino acids were examined. After an exploration using SDS-PAGE analysis, the action of selected diets was further examined by distinct techniques. The 230 kDa protein was identified as fatty acid synthase (FAS) by both mass spectrometry and amino acid sequence analyses. Dietary tests showed that: (1) a protein-free diet (PFD) increased the content of glutathione S-transferases P1 and M1, and glyceraldehyde-3-phosphate dehydrogenase, while the content of glutathione S-transferase A3, fatty acid synthase and carbonic anhydrase III decreased; (2) a protein-free diet having either methionine or cysteine preserved the normal contents of glutathione S-transferases P1, A3, M1 and carbonic anydrase III; (3) a protein-free diet having threonine preserved partially the normal contents of glutathione S-transferases P1, A3, M1 and carbonic anhydrase III; (4) a protein-free diet having methionine, threonine and cysteine prevented in part the loss of fatty acid synthase; and (5) the glyceraldehyde-3-phosphate dehydrogenase content was controlled by increased carbohydrate level and/or by lower amino acid content of diets, but not by any specific amino acid. These data indicate that methionine and cysteine exert a main role on the control of liver glutathione S-transferases A3 and P1, and carbonic anhydrase III. Thus, they emerge necessary to prevent unsafe alterations of liver metabolism caused by protein deprivation.     

Differential protein S-thiolation of glyceraldehyde-3-phosphate dehydrogenase isoenzymes influences sensitivity to oxidative stress

The irreversible oxidation of cysteine residues can be prevented by protein S-thiolation, in which protein -SH groups form mixed disulfides with low-molecular-weight thiols such as glutathione. We report here the identification of glyceraldehyde-3-phosphate dehydrogenase as the major target of protein S-thiolation following treatment with hydrogen peroxide in the yeast Saccharomyces cerevisiae. Our studies reveal that this process is tightly regulated, since, surprisingly, despite a high degree of sequence homology (98% similarity and 96% identity), the Tdh3 but not the Tdh2 isoenzyme was S-thiolated. The glyceraldehyde-3-phosphate dehydrogenase enzyme activity of both the Tdh2 and Tdh3 isoenzymes was decreased following exposure to H2O2, but only Tdh3 activity was restored within a 2-h recovery period. This indicates that the inhibition of the S-thiolated Tdh3 polypeptide was readily reversible. Moreover, mutants lacking TDH3 were sensitive to a challenge with a lethal dose of H2O2, indicating that the S-thiolated Tdh3 polypeptide is required for survival during conditions of oxidative stress. In contrast, a requirement for the nonthiolated Tdh2 polypeptide was found during exposure to continuous low levels of oxidants, conditions where the Tdh3 polypeptide would be S-thiolated and hence inactivated. We propose a model in which both enzymes are required during conditions of oxidative stress but play complementary roles depending on their ability to undergo S-thiolation.     

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.     

Glutathione-protein mixed disulfide decreases the affinity of rat liver fatty acid-binding protein for unsaturated fatty acid

.16 +/- 0.062% of the fatty acid-binding protein purified from 50 mM N-ethylmaleimide-treated rat liver (L-FABP) was determined as a form S-thiolated by glutathione (L-FABP-SSG). L-FABP-SSG, which was prepared in vitro through thiol-disulfide exchange reaction, showed more acidic pI (approximately 5.0) than the pI (approximately 7.0) of reduced L-FABP. S-thiolation of L-FABP by glutathione decreased the affinity of the protein for unsaturated fatty acids without changing the equimolar maximum binding. The changes in Kd were from 0.63 +/- 0.054 microM to 1.03 +/- 0.14 microM for oleic acid, from 0.63 +/- 0.028 microM to 0.97 +/- 0.12 microM for linoleic acid and from 0.85 +/- 0.050 microM to 1.45 +/- 0.024 microM for arachidonic acid. This modification did not alter the affinity nor the maximum binding for saturated fatty acids, which were determined to be Kd of approximately 1.0 microM for palmitic acid and approximately 0.9 microM for stearic acids, and equimolar maximum binding for both fatty acids. The binding affinity of L-FABP for unsaturated fatty acid may be regulated by redox state of the liver.     

Dramatic stabilization of the native state of human carbonic anhydrase II by an engineered disulfide bond

To find a disulfide pair that could stabilize the enzyme human carbonic anhydrase II (HCA II), we grafted the disulfide bridge from the related and unusually stable carbonic anhydrase form from Neisseria gonorrhoeae (NGCA) into the human enzyme. Thus, the two Cys residues at positions 23 and 203 were engineered into a pseudo-wild-type form of HCA II (C206S), giving the mutant C206S/A23C/L203C. The disulfide bond was not formed spontaneously. The native state of the reduced form of the mutant was markedly destabilized (2.9 kcal/mol) compared to that of HCA II. Formation of a disulfide bridge was achieved by treatment by oxidized glutathione. This led to a significant stabilization of the native conformation. Compared to HCA II the unfolding midpoint for the variant was increased from 0.9 to 1.7 M guanidine HCl, corresponding to a stabilization of 3.7 kcal/mol. This makes the human enzyme almost as stable as the model protein NGCA, for which the unfolding of the native state has a midpoint at 2.1 M guanidine HCl. The stabilized protein underwent, contrary to all other investigated variants of HCA II, an apparent two-state unfolding transition, as judged from intrinsic Trp fluorescence measurements. A molten-globule intermediate is nevertheless formed but is suppressed because of the high denaturant pressure it faces upon rupture of the native state.     

The relationship between the two forms of glycogen phosphorylase in Dictyostelium discoideum

The cellular slime mold, Dictyostelium disoideum, provides an ideal model system to study eukaryotic cell differentiation. In D. discoideum, glycogen degradation provides precursors for the synthesis of developmentally regulated structural products. The enzyme responsible for glycogen degradation, glycogen phosphorylase, exists in active and inactive forms. The active, or 'a' form, is independent of 5'adenosine monophosphate (5'AMP) while the inactive, or 'b' form, is 5'AMP-dependent. The activity of the 'b' form predominates early in development, while the activity of the 'a' form peaks in mid-late development; their combined specific activities remain constant at any point. Polyclonal antibodies raised to the purified forms of this enzyme showed low cross-reactivity. The anti-'a' serum reacted with a 104-kDa protein that was associated with phosphorylase 'a' activity; the anti-'b' serum reacted with a 92-kDa protein that was associated with phosphorylase 'b' activity and weakly cross-reacted with the 104-kDa protein. Immunoblots of peptide maps of the purified enzyme forms showed that each antibody was specific for the proteolytic fragments of its respective antigen. We also demonstrated in vitro phosphorylation of the 'b' form by an endogenous protein kinase. Cyclic AMP perturbation of intact cells caused induction of both phosphorylase-'a' activity and the 104-kDa protein. Immunotitration data suggested that the 'a' form accumulates due to de novo protein synthesis, although this result must be interpreted with caution.     

Carbonic anhydrase III: the phosphatase activity is extrinsic

The carbonic anhydrases reversibly hydrate carbon dioxide to yield bicarbonate and hydrogen ion. They have a variety of physiological functions, although the specific roles of each of the 10 known isozymes are unclear. Carbonic anhydrase isozyme III is particularly rich in skeletal muscle and adipocytes, and it is unique among the isozymes in also exhibiting phosphatase activity. Previously published studies provided evidence that the phosphatase activity was intrinsic to carbonic anhydrase III, that it had specificity for tyrosine phosphate, and that activity was regulated by reversible glutathionylation of cysteine186. To study the mechanism of this phosphatase, we cloned and expressed the rat liver carbonic anhydrase III. The purified recombinant had the same specific activity as the carbonic anhydrase purified from rat liver, but it had virtually no phosphatase activity. We attempted to identify an activator of the phosphatase in rat liver and found a protein of approximately 14 kDa, the amount of which correlated with the phosphatase activity of the carbonic anhydrase III fractions. It was identified as liver fatty acid binding protein, which was then purified to test for activity as an activator of the phosphatase and for protein-protein interaction, but neither binding nor activation could be demonstrated. Immunoprecipitation experiments established that carbonic anhydrase III could be separated from the phosphatase activity. Finally, adding additional purification steps completely separated the phosphatase activity from the carbonic anhydrase activity. We conclude that the phosphatase activity previously considered to be intrinsic to carbonic anhydrase III is actually extrinsic. Thus, this isozyme exhibits only the carbon dioxide hydratase and esterase activities characteristic of the other mammalian isozymes, and the phosphatase previously shown to be activated by glutathionylation is not carbonic anhydrase III.     

Sexual differentiation of rat liver carbonic anhydrase III

Using radioimmunoassay, the concentration of carbonic anhydrase III in the livers of adult male rats was found to be approx. 30-times greater than that observed in mature females. Castration of male rats led to a marked reduction in liver carbonic anhydrase III concentrations which could be partially restored to control levels by testosterone replacement. Administration of testosterone to ovariectomised female rats induced about a 5-fold increase in liver carbonic anhydrase III concentration. Immunoprecipitation analysis of the products of liver mRNA translation in vitro with antiserum specific for carbonic anhydrase III showed that hormonal control of the levels of carbonic anhydrase III in liver is mediated by changes in the amount of translatable carbonic anhydrase III mRNA. Marked changes in liver carbonic anhydrase III concentrations were also observed in developing and ageing male rats.     

Detection, quantitation, purification, and identification of cardiac proteins S-thiolated during ischemia and reperfusion.

We have developed methods that allow detection, quantitation, purification, and identification of cardiac proteins S-thiolated during ischemia and reperfusion. Cysteine was biotinylated and loaded into isolated rat hearts. During oxidative stress, biotin-cysteine forms a disulfide bond with reactive protein cysteines, and these can be detected by probing Western blots with streptavidin-horseradish peroxidase. S-Thiolated proteins were purified using streptavidin-agarose. Thus, we demonstrated that reperfusion and diamide treatment increased S-thiolation of a number of cardiac proteins by 3- and 10-fold, respectively. Dithiothreitol treatment of homogenates fully abolished the signals detected. Fractionation studies indicated that the modified proteins are located within the cytosol, membrane, and myofilament/cytoskeletal compartments of the cardiac cells. This shows that biotin-cysteine gains rapid and efficient intracellular access and acts as a probe for reactive protein cysteines in all cellular locations. Using Western blotting of affinity-purified proteins we identified actin, glyceraldehyde-3-phosphate dehydrogenase, HSP27, protein-tyrosine phosphatase 1B, protein kinase Calpha, and the small G-protein ras as substrates for S-thiolation during reperfusion of the ischemic rat heart. MALDI-TOF mass fingerprint analysis of tryptic peptides independently confirmed actin and glyceraldehyde-3-phosphate dehydrogenase S-thiolation during reperfusion. This approach has also shown that triosephosphate isomerase, aconitate hydratase, M-protein, nucleoside diphosphate kinase B, and myoglobin are S-thiolated during post-ischemic reperfusion.