Species variability in plasma S-sulfonate levels during and following sulfite administration.

It has been shown that S-sulfonate compounds (R-S-SO-3) are produced by the action of sulfite on reactive disulfide bonds [4,5]. Plasma S-sulfonate production was determined as a function of sulfite ingestion and intraperitoneal injection in rats, mice and rhesus monkeys. The tendency of these species and of the rabbit [8] to produce S-sulfonates in plasma was related to the availability of sulfite and of reactive disulfide bonds and to the stability of plasma protein S-sulfonates. The rhesus monkey and the rabbit accumulated plasma S-sulfonates much more readily than did the rat, while the mouse produced little, if any, under the same test conditions. Plasma protein S-sulfonate fractions in the rat and rhesus monkey were characterized by half-lives of approximately 4 and 8 days respectively. The sensitivity and precision of the analytical method for plasma protein S-sulfonate were improved by incorporation of 35S into the outer sulfur atom of the S-sulfonate moiety (R-S-35SO-3).     

Inactivation of thioredoxin by sulfite ions

Oxidized thioredoxin undergoes sulfitolysis of its single disulfide bond at low concentrations of sulfite ions and protein and in the absence of denaturing agents. The reaction, which has an optimum at pH 8, was studied using [35S]sulfite and E. coli thioredoxin as model. The product, thioredoxin-S-sulfonate, has a half-life of several hours in solution. It is unable to activate chloroplast NADP malate dehydrogenase. Thioredoxin sulfitolysis may therefore be a physiologically important factor in mediating the phytotoxic effects of sulfur dioxide in plants.     

Enzymatic catalysis of the reversible sulfitolysis of glutathione disulfide and the biological reduction of thiosulfate esters

Rat liver supernatants were shown to contain an enzymatic activity catalyzing in both forward and reverse directions the reversible sulfitolysis of glutathione disulfide. The enzymatic sulfitolysis has maximal activity at pH 7. S-Sulfoglutathione, which is a product of the sulfitolysis, was isolated by passage through an ion-exchange column. Three different assays were applied to determine S-sulfoglutathione, viz., methods based on the ninhydrin reaction, the formation of a thiazoline derivative in strong acid, and the use of radioactively labeled glutathione. The reversal of the sulfitolysis, i.e., the reaction of S-sulfoglutathione with glutathione, was studied directly by determination of sulfite with radioactive N-ethylmaleimide, or indirectly by coupling to the NADPH- and glutathione reductase-linked reduction of glutathione disulfide.Chromatographic analysis of rat liver supernatants demonstrated that all fractions catalyzing the reversible sulfitolysis did also catalyze the previously studied thiol-disulfide interchange of glutathione and the mixed disulfide of cysteine and glutathione.The reduction of thiosulfate esters, such as S-sulfocysteine and trimethylammonium-ethylthiosulfate, with glutathione was also catalyzed by the enzyme active in the sulfitolysis, which indicates an important biosynthetic role of the enzyme in microorganisms synthesizing cysteine via S-sulfocysteine. The enzyme is also capable of participating in the formation of the naturally occurring S-sulfoglutathione.     

Formation of albumin dimers induced by exposure to peroxides in human plasma: a possible biomarker for oxidative stress

Human serum albumin (HSA) has one free thiol residue at Cys-34 that is likely oxidized by various reactive oxygen species (ROS). We attempted to identify the oxidation product of Cys-34 of HSA following exposure of plasma to ROS. Oxidation induced by tert-butyl hydroperoxide (t-BuOOH) of this free cysteine residue in HSA was observed in detail. Analysis of oxidized albumin in a partially purified fraction obtained by affinity column chromatography clearly revealed the formation of albumin disulfide dimers following t-BuOOH exposure. Albumin disulfide dimer formation was observed in normal plasma following treatment with various peroxides, as well as in untreated plasma from patients on hemodialysis using SDS-PAGE and Western blot analysis. The present results indicate that albumin dimers are oxidative products derived from peroxides, and that their presence in plasma might be a marker of oxidative stress as secondary metabolites of peroxidation.     

Recombinant human insulin. VIII. Isolation of fusion protein--S-sulfonate, biotechnological precursor of human insulin, from the biomass of transformed Escherichia coli cells

Various methods have been investigated for the isolation and purification of fusion proteins of precursors of human insulin in the form of S-sulfonates, from the biomass of transformed Escherichia coli cells. Fusion proteins were prepared with different sizes and structures of the leader peptide and the poly-His position (inserted for purification by metal chelate affinity chromatography). The fusion proteins contained an IgG-binding B domain of protein A from Staphylococcus aureus at the N-terminus and an Arg residue between the leader peptide of the molecule and the proinsulin sequence, for trypsin cleavage of the leader peptide. Six residues of Cys in proinsulin allow the chemical modification of the protein as a (Cys-S-SO(-)(3))(6) derivative (S-sulfonate), which increases its polyelectrolytic properties and improves the efficiency of its isolation. Various methods of oxidative sulfitolysis were compared with catalysis by sodium tetrathionate or cystine and Cu2+ or Ni2+ ions. An optimum scheme for the isolation and purification of S-sulfonated fusion proteins was developed by the combination of metal-chelating affinity and ion-exchange chromatography. Highly purified (95%) S-sulfonated fusion protein was recovered which was 85% of the fusion protein contained in the biomass of E. coli cells. Folding of fusion protein S-sulfonate occurred with high yield (up to 90-95%). We found that the fusion protein-S-sulfonate has proinsulin-like secondary structure.This structure causes highly efficient fusion protein folding.     

A method for the controlled cleavage of disulfide bonds in proteins in the absence of denaturants

A simple method was developed for the controlled cleavage of protein disulfide bonds and the simultaneous blockage of the free sulfhydryl groups in the absence of a denaturant. The disulfide bonds of bovine serum albumin were cleaved unsymmetrically at pH 7.0 using 0.1 M sulfite in 0.1 M phosphate buffer and the free sulfhydryl groups formed were sulfonated in an oxidation-reduction cycle using molecular oxygen and 400 microM cupric sulfate as a catalyst. The reaction was affected by cupric ion concentration, sulfite concentration, reaction pH and temperature. The standardized method was successfully used to cleave the disulfide bonds of other proteins pepsin, trypsin, and chymotrypsin. The method is reliable and can be used for achieving progressive cleavage of disulfide bonds in proteins without employing a denaturant.     

Interaction of S-sulfonated human IgG with human complement and its components.

S-sulfonated human IgG (S-sIgG) was prepared by treating IgG with sodium sulfite and sodium tetrathionate. The treatment resulted in the selective cleavage of interchain disulfide bonds of the IgG to give S-sulfonate groups. Complement fixing activities of aggregated S-sIgG and the immune complex formed with the S-sIgG antibody were very weak. S-sIgG at a high dose reduced the activity of the first complement component (C1) in normal human serum without any reduction of other complement components activites, but S-alkylated IgG at the same dose did not. Loss of C1 activity was not caused by either S-sulfonated myeloma proteins (IgA and IgE) or urea-treated S-sIgG, in which both inter- and intra-chain disulfide bonds were cleaved. These results suggest that the selective reduction of C1 by S-sIgG is due to a conformational change of the immunoglobulin.     

Distribution of free sulfhydryl and disulfide groups among platelet membrane proteins.

Reactive sulfhydryl and disulfide groups were identified in platelet membrane proteins resolved by sodium dodecyl sulfate-polycrylamide gel electrophoresis. Platelet membranes treated with N-ethyl(1-14C)maleimide, phenyl(203Hg)mercuric acetate and p-chloro(203Hg)mercuribenzoate showed similar patterns of distribution of sulfhydryl groups among the sodium dodecyl sulfate-solubilized membrane proteins. Four major and two minor polypeptides ranging in molecular weight from greater than 200 000 to 20 000 were found to have reactive SH groups. Reduction of membrane proteins by sulfite coupled with subsequent mercaptide formation of the resultant monothiols led to the identification of four polypeptides with disulfide bonds. Reaction of platelet membranes with 14C-labeled 5,5'-dithio-bis(2-nitrobenzoic acid) resulted changes in the distribution profile of the solubilized membrane proteins suggestive of a polymerization process dependent upon, 5,5'-dithio-bis(2-nitrobenzoic acid)-induced intermolecular disulfide interchange.     

Effects of sulfite on glutathione S-sulfonate and the glutathione status of lung cells

A mechanistic study was performed to elucidate the biochemical events connected with the cocarcinogenic effect of sulfur dioxide (SO2). Glutathione S-sulfonate (GSSO3H), a competitive inhibitor of the glutathione S-transferases, forms in lung cells exposed in culture to sulfite, the hydrated form of SO2. Changes in glutathione status (total GSH) were also observed during a 1-h exposure. Some cells were pretreated with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) to inhibit glutathione reductase. In human lung cells GSSO3H formed in a concentration-dependent manner, while glutathione (GSH) increased and glutathione disulfide (GSSG) decreased as the extracellular sulfite concentration was increased from 0 to 20 mM. The ratio of GSH/GSSG increased greater than 5-fold and the GSH/GSSO3H ratio decreased to 10 with increasing sulfite concentration. GSSO3H formed in rat lung cells exposed to sulfite, with no detectable effect on GSH and GSSG. GSSO3H also formed from cellular GSH mixed disulfides. GSSO3H formed rapidly, reaching its maximum value in 15 min. The viability of both cell types was unaffected except at 20 mM sulfite. GSSO3H incubated with human lung cells did not affect cellular viability. BCNU inhibited cellular GSSO3H reductase to the same extent as GSSG reductase. These results indicate that GSSO3H is formed in cells exposed to sulfite, and could be the active metabolite of sulfite responsible for the cocarcinogenic effect of SO2 by inhibiting conjugation of electrophiles by GSH.     

Preferential S-sulfonate formation in lung and aorta.

S-sulfonate (S-SO-3) compounds have previously been identified as metabolites of sulfite in the plasma of several species of mammals [6--8]. We now report the formation of non-diffusible and relatively stable S-sulfonates in the aorta and lung lobes of rabbits exposed intravenously to constant arterial sulfite concentrations of approx. 550 microM. Under these conditions the kinetics of S-SO-3 formation were first order with coefficients in the range of 0.3--0.4 h-1 and asymptotic concentrations of approx. 900 and 9000 nmol S-SO-3/g dry wt. of lung and aorta respectively. The kinetics of this reaction in aorta tissue were closely approximated in vitro. Clearance of S-SO-3 from both lungs and aorta appeared to be first order with a half-life of 2--3 days.     

Photonic immobilization of BSA for nanobiomedical applications: creation of high density microarrays and superparamagnetic bioconjugates

Light assisted molecular immobilization has been used for the first time to engineer covalent bioconjugates of superparamagnetic nanoparticles and proteins. The technology involves disulfide bridge disruption upon UV excitation of nearby aromatic residues. The close spatial proximity of aromatic residues and disulfide bridges is a conserved structural feature in proteins. The created thiol groups bind thiol reactive surfaces leading to oriented covalent protein immobilization. We have immobilized a model carrier protein, bovine serum albumin, onto Fe(3)O(4)@Au core-shell nanoparticles as well as arrayed it onto optically flat thiol reactive surfaces. This new immobilization technology allows for ultra high dense packing of different bio-molecules on a surface, allowing the creation of multi-potent functionalized active new biosensor materials, biomarkers identification and the development of nanoparticles based novel drug delivery system.     

Preparation and characterization of bovine albumin isoforms

Albumin undergoes changes in conformation and isomerizations by disulfide interchange of unknown biological significance. The aim of this study was to prepare and characterize albumin isoforms, which were stable under near physiological conditions. Modified albumins were obtained by urea denaturation and renaturation, and by aging at low ionic strength and alkaline pH in the presence of cysteine. We describe a cathodic electrophoresis technique, which allows the separation of albumin isoforms with greater positive charge. Differences between native and modified albumins were analyzed by new criteria based on the reactivity of the thiol and histidyl residues and on the susceptibility of the disulfide bonds to sulfitolysis. Modified albumins had, (i) a more cationic component which disappears by sulfitolysis of the disulfide bonds or by incubation with a glutathione redox system; (ii) higher reactivities of the free thiol group and of the histidyl residues, and; (iii) decreased fluorescence. These differences were not observed when processes were carried out on albumin with the thiol group blocked by iodacetic acid, but reappeared with the addition of cysteine. Renatured and aged albumins differed in the nature of the cationic component. Generation of albumin isoforms is dependent on the presence of a free thiol group and seems to involve thiol disulfide interchanges.     

Characterization of a novel gelatin-binding 21 kDa protein secreted by cultured adherent cells

A novel gelatin-binding 21 kDa protein was identified in the culture medium of fibroblastic and sarcoma cells by affinity chromatography on gelatin-Sepharose. Its affinity for gelatin was lower than that of the other gelatin-binding proteins, fibronectin and the 70 kDa protein, as judged by stepwise elution by urea and arginine. The protein bound also to spermine and to some extent to heparin but not to staphylococcal protein A, bovine serum albumin, concanavalin A or plain Sepharose 4B. In gel filtration chromatography the protein eluted in fractions differing from those of fibronectin and the Mr 70,000 protein and retained its ability to bind to gelatin-Sepharose, indicating that the binding was not mediated by the two other gelatin-binding proteins. It contains intrachain disulfide bridges, as judged by analysis under nonreducing and reducing conditions. The protein is composed of two major subtypes with pI values of 5.85-6.10 and 6.55-6.75. It was sensitive to trypsin but not to collagenase or thrombin. Antiserum was raised in rabbits against the gelatin-binding proteins isolated from serum-free conditioned fibroblast culture medium. The antiserum reacted with fibronectin, the Mr 70,000 protein and the Mr 21,000 protein in immunoprecipitation experiments. Absorption of the antiserum with human plasma fibronectin did not decrease its reactivity with the Mr 70,000 and 21,000 proteins. However, absorption with the Mr 70,000 protein abolished also the reactivity against the Mr 21,000 protein, suggesting immunological cross-reactivity. The protein was synthesized independently from the Mr 70,000 protein, as shown by pulse-chase labeling experiments of cells. The production of the Mr 21,000 protein in cultured cells was enhanced by transforming growth factor-beta.     

Formation and loss of nitrated proteins in peroxynitrite-treated rat skin in vivo.

Peroxynitrite is a reactive cytotoxic species, capable of nitrating tyrosine residues to form 3-nitrotyrosine. Little is known about the formation and loss of nitrated proteins in vivo. We have measured nitrated proteins, by enzyme-linked immunosorbent assay, in rat skin after exposure to peroxynitrite. Peroxynitrite (100-200 nmol site(-1)) was injected into the skin of anesthetized rats. At the highest dose 78.6 +/- 9.5 pmol mg(-1) protein of nitrated BSA equivalents were measured at 4 h and a significant increase was observed for 24 h after administration in skin samples. The loss of nitrated proteins from skin appeared biphasic with an initial (t(1/2) = 2 h) and slower loss (t(1/2) = 22 h). A major nitrated protein was identified as albumin by Western blot analysis. The data demonstrate that a single exposure to peroxynitrite can lead to the presence of nitrated proteins in skin for at least 24 h. The sustained presence of nitrated proteins may influence the inflammatory process in skin disease.     

Disulfide-bonded dimerization of fibronectin in vitro.

Human plasma fibronectin was denatured with 8 M urea and reduced with dithiothreitol. Dialysis or dilution of the solution led to formation of fibronectin dimers which migrated in non-reducing SDS/PAGE similarly to untreated control protein. When the redimerized fibronectin was reduced and re-electrophoresed it formed a doublet of alpha and beta chains of equal intensity indicating that it was a heterodimer. Low concentrations (less than 1 mM) of Fe3+ enhanced the redimerization of fibronectin, suggesting that metal ions may mediate oxidative reactions in the formation of the disulfides. Consequently, redimerization of fibronectin was completely prevented by deferoxamine, an iron chelator. Dimerization of fibronectin took place most effectively at pH greater than or equal to 8.8 but decreased strongly at lower pH, representing more unfavourable conditions for the action of the thiolate anion in the thiol/disulfide exchange reaction. Redimerized fibronectin, however, lost many of its binding properties to macromolecular ligands, suggesting that the disulfide bonding did not entirely regenerate the proper conformation of the protein. Pulse/chase experiments of fibroblast cultures showed that the initially monomeric fibronectin was rapidly and quantitatively dimerized under conditions representing natural pH and environment. SDS/PAGE analysis of the dialyzed urea-denatured/reduced thrombin and plasmin digests of fibronectin revealed that the NH2-terminal 30-kDa fragment and other fragments that contained intrachain disulfides quantitatively regained their non-reduced electrophoretic mobility. The results show that the dimerization and formation of intrachain disulfides of fibronectin may occur, in part, spontaneously, based on the amino acid sequence information of the protein. However, complete disulfide formation may also need other factors, present only in living cells, as suggested by pulse/chase experiments in fibroblasts.     

Reaction of selenium with immunoglobulin molecules.

Radioactive selenite reacts with purified human and goat immunoglobulins at acidic and neutral pH. The antigenic properties of the immunoglobulins are retained during the selenium labelling as shown by immunoelectrophoresis and autoradiography. Pepsin digests of 75Se-labelled IgG possess 75Se both in the (Fab')2 fraction and in the low molecular weight peptides derived from the Fc domains. Alpha-1-acid glycoprotein, ribonuclease, and lysozyme are also labelled by this procedure. Enhancement of 75Se incorporation by urea, guanidinium chloride, mercaptoethanol, sodium sulfite and carrier selenite is interpreted as an effect of destabilization of IgG disulfide bonds. Up to 1.4 g atoms Se per mol IgG have been incorporated. We assume that selenite is cleaving disulfides by a process akin to sulfitolysis. The lability of the isolated 75Se-labelled IgG to high concentrations of mercaptans and sulfite is consistent with this idea. These 75Se-labelled proteins may be useful in structure studies and radioimmunoassay.     

Sensitive quantitative analysis of disulfide bonds in polypeptides and proteins

A sensitive quantitative method has been developed to determine the number of disulfide bonds in peptides and proteins. The disulfide bonds of several peptides and proteins were cleaved quantitatively by excess sodium sulfite at pH 9.5 and room temperature. Guanidine thiocyanate (2 M) was added to the protein solutions in order to denature them and thereby make the disulfide bonds accessible. The reaction with sulfite leads to a thiosulfonate and a free sulfhydryl group; the concentration of the latter was determined by reaction with disodium 2-nitro-5-thiosulfobenzoate (NTSB) in the presence of excess sodium sulfite. The synthesis, purification, and characterization of NTSB are described. The assay is rapid, requiring 3-5 min for oligopeptides and 20 min for proteins, and is as sensitive and quantitative as the sulfhydryl group assay employing 5,5'-dithiobis(2-nitrobenzoic acid) (Ellman's reagent). It can be used for the analysis of as little as 10(8) mol of disulfide bonds, with an error of +/- 3%.     

Sulfenic acid formation in human serum albumin by hydrogen peroxide and peroxynitrite

Human serum albumin (HSA), the most abundant protein in plasma, has been proposed to have an antioxidant role. The main feature responsible for this property is its only thiol, Cys34, which comprises approximately 80% of the total free thiols in plasma and reacts preferentially with reactive oxygen and nitrogen species. Herein, we show that the thiol in HSA reacted with hydrogen peroxide with a second-order rate constant of 2.26 M(-1) s(-1) at pH 7.4 and 37 degrees C and a 1:1 stoichiometry. The formation of intermolecular disulfide dimers was not observed, suggesting that the thiol was being oxidized beyond the disulfide. With the reagent 7-chloro-4-nitrobenzo-2-oxa-1,3-diazol (NBD-Cl), we were able to detect the formation of sulfenic acid (HSA-SOH) from the UV-vis spectra of its adduct. The formation of sulfenic acid in Cys34 was confirmed by mass spectrometry using 5,5-dimethyl-1,3-cyclohexanedione (dimedone). Sulfenic acid was also formed from exposure of HSA to peroxynitrite, the product of the reaction between nitric oxide and superoxide radicals, in the absence or in the presence of carbon dioxide. The latter suggests that sulfenic acid can also be formed through free radical pathways since following reaction with carbon dioxide, peroxynitrite yields carbonate radical anion and nitrogen dioxide. Sulfenic acid in HSA was remarkably stable, with approximately 15% decaying after 2 h at 37 degrees C under aerobic conditions. The formation of glutathione disulfide and mixed HSA-glutathione disulfide was determined upon reaction of hydrogen peroxide-treated HSA with glutathione. Thus, HSA-SOH is proposed to serve as an intermediate in the formation of low molecular weight disulfides, which are the predominant plasma form of low molecular weight thiols, and in the formation of mixed HSA disulfides, which are present in approximately 25% of circulating HSA.     

Multiple mechanisms of dissociated epidermal cell spreading

To test the possibility that epidermal cells use a common basement membrane protein whenever they spread, in vitro experiments were conducted using trypsin-dissociated guinea pig epidermal cells and the following proteins: human serum, bovine serum albumin, serum fibronectin, Type IV collagen, laminin, and epibolin (a recently described serum glycoprotein which supports epidermal cell spreading; Stenn, K.S., 1981, Proc. Natl. Acad. Sci. U.S.A. 78:6907.). When the cells were added to media containing the specific proteins, all the tested proteins, except for serum albumin, supported cell spreading. Added to protein-coated substrates in defined media, the cells spread on fibronectin, epibolin, and laminin-Type IV collagen, but not on albumin or whole serum. In none of these experiments were the results qualitatively affected by the presence of cycloheximide. Antibodies to a specific protein blocked cell spreading on that protein but not on the other active proteins, e.g. whereas antibodies to epibolin blocked cell spreading on epibolin, they did not affect spreading on fibronectin, collagen, or laminin. In a second assay in which the cells were allowed to adhere to tissue culture plastic before the protein-containing medium was added, the cells spread only if the medium contained epibolin. Moreover, under these conditions the spreading activity of whole serum and plasma was neutralized by antiepibolin antibodies. These results support the conclusion that dissociated epidermal cells possess multiple spreading modes which depend, in part, on the proteins of the substrate, proteins of the medium, and the sequence of cell adhesion and protein exposure.     

Covalent binding of 4-nitrobenzyl mercaptan S-sulfate to the sulfhydryl groups of hepatic cytosolic proteins and bovine serum albumin with mixed disulfide bond formation

4-Nitrobenzyl [35S]mercaptan S-sulfonic acid ([35S]NBM S-sulfate), a new type of reactive metabolite of the thiol [35S]NBM in rat liver cytosol fortified with 3'-phosphoadenosine 5'-phosphosulfate, bound rapidly and covalently at pH 7.4 and 37 degrees C to the sulfhydryl groups of rat liver cytosolic proteins with formation of disulfide bonds. From the radioactive proteins was isolated and identified the sole amino acid adduct, S-([35S]NBM)cysteine, after their acid hydrolysis under the anaerobic conditions. Bovine serum albumin (BSA), a model protein with a single SH group, also reacted readily with radioactive NBM S-sulfate to form a disulfide bond in stoichiometric manner. S-([35S]NBM)-cysteine was also isolated and identified as the sole amino acid adduct from the well-washed, radioactive BSA after the same anaerobic acid hydrolysis. A normal hepatic level of GSH not only retarded the BSA-NBM adduct formation completely, but also detached the radioactivity from BSA by the reduction of the disulfide bond with formation of [35S]NBM and its disulfide. Of twenty-one amino acids examined at pH 7.4 and 37 degrees C, only cysteine reacted with NBM S-sulfate and afforded S-(NBM)cysteine with concomitant formations of S-sulfocysteine, cystine, NBM, and its disulfide.