Differential sensitivity of chicken progesterone receptor forms to sulfhydryl reactive reagents

DNA binding of chick progesterone receptor B form (PRB) has been examined and compared to that of the A form (PRA). We found that the elution profiles of the two receptors overlap on DNA-cellulose columns. Both PRA or PRB could bind to plasmid DNA equivalently as assayed by sedimentation velocity studies. However, DNA-binding activity of the two receptor forms showed differential sensitivity to reducing agents and to sulfhydryl (SH) reactive reagents. Reducing agents stabilized DNA-binding activity of PRA more efficiently than they stabilized PRB. Moreover, removal of reducing agents from receptor preparations caused preferential loss of DNA binding by PRB compared to the PRA. DNA-binding activity of PRA was readily destroyed by sulfhydryl modifying reagents such as N-ethylmaleimide and iodoacetamide while PRB was 3-4 times less sensitive to these reagents. We conclude the DNA-binding activity of PRB is less stable due to altered accessibility of SH groups despite the amino acid sequence identity of the DNA-binding domains of PRA and PRB.     

Siderophore transport through Escherichia coli outer membrane receptor FhuA with disulfide-tethered cork and barrel domains

The hydroxamate siderophore receptor FhuA is a TonB-dependent outer membrane protein of Escherichia coli composed of a C-terminal 22-stranded beta-barrel occluded by an N-terminal globular cork domain. During siderophore transport into the periplasm, the FhuA cork domain has been proposed to undergo conformational changes that allow transport through the barrel lumen; alternatively, the cork may be completely displaced from the barrel. To probe such changes, site-directed cysteine mutants in the cork domain (L109C and Q112C) and in the barrel domain (S356C and M383C) were created within the putative siderophore transport pathway. Molecular modeling predicted that the double cysteine mutants L109C/S356C and Q112C/M383C would form disulfide bonds, thereby tethering the cork and barrel domains. The double cysteine FhuA mutants were denatured under nonreducing conditions and fluorescently labeled with thiol-specific Oregon Green maleimide. Subsequent SDS-PAGE analysis revealed two distinct species: FhuA containing a disulfide bond and FhuA with free sulfhydryl groups. To address the role of the putative siderophore transport pathway and to evaluate possible rearrangements of the cork domain during ferricrocin transport, disulfide bond formation was enhanced by an oxidative catalyst. Cells containing double cysteine FhuA mutants that were subjected to oxidation during ferricrocin transport exhibited disulfide bond formation to near completion. After disulfide tethering of the cork to the barrel, ferricrocin transport was equivalent to transport by untreated cells. These results demonstrate that blocking the putative siderophore transport pathway does not abrogate ferricrocin uptake. We propose that, during siderophore transport through FhuA, the cork domain remains within the barrel rather than being displaced.     

Soluble human core 2 beta6-N-acetylglucosaminyltransferase C2GnT1 requires its conserved cysteine residues for full activity

Human UDP-GlcNAc: Galbeta1-3GalNAc- (GlcNAc to GalNAc) beta1,6-GlcNAc-transferase (C2GnT1) is a member of a group of beta6-GlcNAc-transferases that belongs to CAZy family 14. One of the striking features of these beta6-GlcNAc-transferases is the occurrence of nine completely conserved cysteine residues that are located throughout the catalytic domain. We have expressed the soluble catalytic domain of human C2GnT1 in insect cells, and isolated active enzyme as a secreted protein. beta-Mercaptoethanol (beta-ME) and dithiothreitol (DTT) were found to stimulate the enzyme activity up to 20-fold, indicating a requirement for a reduced sulfhydryl for activity. When the enzyme was subjected to nonreducing PAGE, the migration of the protein was identical to the migration in reducing gels, demonstrating the absence of intermolecular disulfide bonds. This suggested that the monomer is the active form of the enzyme. Sulfhydryl reagents such as 5,5'-dithiobis-2-nitrobenzoic acid (DTNB) and N-ethylmaleimide (NEM) inactivated the enzyme, and the inactivation was partially prevented by prior addition of donor or acceptor substrate and by sulfhydryl reducing agents. We therefore investigated the role of all nine conserved cysteine residues in enzyme stability and activity by site-directed mutagenesis where individual cysteine residues were changed to serine. All of the mutants were expressed as soluble proteins. Seven of the Cys mutants were found to be inactive, while C100S and C217S mutants had 10% and 41% activity, respectively, when compared to the wild-type enzyme. Wild-type and C217S enzymes had similar K(M) and V(max) values for acceptor substrate Galbeta1-3GalNAcalpha-p-nitrophenyl (GGApnp), but the K(M) value for UDP-GlcNAc was higher for C217S than for the wild-type enzyme. In contrast to wild-type enzyme, C217S was not stimulated by reducing agents and was not inhibited by sulfhydryl specific reagents. These results suggest that Cys-217 is a free sulfhydryl in active wild-type enzyme and that Cys-217, although not required for activity, is in or near the active site of the protein. Since seven of the mutations were totally inactive, it is likely that these seven Cys residues play a role in maintaining an active conformation of soluble C2GnT1 by forming disulfide bonds. These bonds are only broken at high concentrations of disulfide reducing agents.     

Identification and function of disulfide bridges in the extracellular domains of the angiotensin II type 2 receptor.

The angiotensin II (AngII) receptor family is comprised of two subtypes, type 1 (AT(1)) and type 2 (AT(2)). Although sharing low homology (only 34%), mutagenesis has identified some key residues that are conserved between both subtypes, including four extracellular cysteines. Previous AT(1) mutagenesis demonstrated that the cysteines form two disulfide bonds, one linking the first and second extracellular loops and another connecting the amino terminus to the third extracellular loop. The importance of these AT(1) disulfides in ligand binding is supported by the effect of dithiothreitol (DTT). DTT breaks disulfide bonds, thereby strongly inhibiting ligand binding in AT(1) receptors. Despite retaining the same cysteines, AT(2) receptor ligand binding is paradoxically enhanced by DTT. Thus, we constructed a series of AT(2) cysteine mutations, either individually or paired, to establish the role of the cysteines and the source of DTT's effects. The AT(2) cysteine mutants surprisingly confirmed that the cysteines form disulfide bonds in the same manner as in the AT(1) subtype. However, breaking the AT(2) disulfide bridges yielded two responses. As in AT(1) receptors, mutations disrupting the disulfide bond between the first and second extracellular loops reduced AT(2) binding by 4-fold. In contrast, mutations breaking the disulfide bridge between the amino terminus and the third extracellular loop increased AT(2) binding, mimicking DTT's effect on this subtype. Further analysis of AT(1)/AT(2) chimeric exchange mutants of these domains suggested that the AT(2) amino terminus and third extracellular loop may possess latent binding epitopes that are only uncovered after DTT exposure.     

Role of Disulfides and Sulfhydryl Groups in Agonist and Antagonist Binding in Serotonin1A Receptors from Bovine Hippocampus

SUMMARY 1. The serotonin_1A (5-HT_1A) receptors are members of a superfamily of seven-transmembrane-domain receptors that couple to G-proteins. They appear to be involved in various behavioral and cognitive functions. Mutagenesis and modeling studies point out that the ligand-binding sites in serotonin receptors are located in the transmembrane domain. However, these binding sites are not very well characterized. Since disulfide bonds and sulfhydryl groups have been shown to play vital roles in the assembly, organization, and function of various G-protein-coupled receptors, we report here the effect of disulfide and sulfhydryl group modifications on the agonist and antagonist binding activity of 5-HT_1A receptors from bovine hippocampus.2. DTT or NEM treatment caused a concentration-dependent reduction in specific binding of the agonist and antagonist in 5-HT_1A receptors from bovine hippocampal native and solubilized membranes. This is supported by a concomitant reduction in binding affinity.3. Pretreatment of the receptor with unlabeled ligands prior to chemical modifications indicate that the majority of disulfides or sulfhydryl groups that undergo modification giving rise to inhibition in binding activity could be at the vicinity of the ligand-binding sites.4. In addition, ligand-binding studies in presence of GTP--S, a nonhydrolyzable analogue of GTP, indicate that sulfhydryl groups (and disulfide bonds to a lesser extent) are vital for efficient coupling between the 5-HT_1A receptor and the G-protein.5. Our results point out that disulfide bonds and sulfhydryl groups could play an important role in ligand binding in 5-HT_1A receptors.     

Cadmium affects the redox state of rat liver glucocorticoid receptor

It has previously been documented that cadmium displays high affinity for protein thiol groups and induces an impairment of glucocorticoid receptor (GR) cellular functions. The present study examined the possibility that cadmium exerts these effects on GR activity by disturbing the receptor's redox equillibrium. To that end, the influence of cadmium on the rat liver GR potential to form intramolecular and intermolecular disulfide bonds under nonreducing conditions and under oxidizing conditions produced by the addition of hydrogen peroxide (H₂O₂) to the cytosol was examined by nonreducing SDS-PAGE and immunoblotting. The results show that cadmium inhibits formation of disulfide bonds within the GR both in the absence and in the presence of H₂O₂. The creation of intermolecular disulfide linkages between the apo-GR and associated heat shock proteins Hsp90 and Hsp70, which was evident in the presence of H₂O₂, was also significantly impaired after cadmium administration. These observations are consistent with the assumption that cadmium affects the redox state of the receptor, possibly by binding to its sulfhydryl groups. This revised version was published online in July 2006 with corrections to the Cover Date.     

Dihydropyridine binding to the L-type Ca2+ channel in rabbit heart sarcolemma and skeletal muscle transverse-tubules: role of disulfide, sulfhydryl and phosphate groups

The dihydropyridine receptor is associated with the L-type Ca2+ channel in the cell membrane. In this study we have examined the effects of group-specific modification on dihydropyridine binding in heart sarcolemmal membranes isolated from the rabbit. Specifically, dithiothreitol and glutathione were employed to assess the possible role of disulfide (-SS-) bonds in the binding of [3H]dihydropyridines. NEM, PCMS and iodoacetamide were employed to examine the effect of blocking free sulfhydryl groups (-SH) on the binding of [3H]dihydropyridines to their receptor in heart sarcolemma. Glutathione inhibited [3H]PN200-110 binding to sarcolemmal membranes 100%, with an IC50 value of 50 microM, while DTT inhibited maximally by 75% with an IC50 value in the millimolar range. Alkylation of free sulfhydryl groups by NEM or iodoacetamide inhibited binding of [3H]PN200-110 binding in cardiac sarcolemma approx. 40-60%. Blocking of free sulfhydryl groups by PCMS completely inhibited [3H]PN200-110 binding to their receptor in sarcolemmal membranes in a dose-dependent manner with an IC50 value of 20 microM. These results suggest the involvement of disulfide bonds and free sulfhydryl groups in DHP binding to the L-type Ca2+ channel in heart muscle. We also examined the effect of membrane phosphorylation on the specific binding of the dihydropyridine [3H]nitrendipine to its receptor. Phosphorylation was studied in cardiac sarcolemmal as well as skeletal muscle transverse-tubule membranes. Phosphorylation due to endogenous protein kinase and cAMP-dependent protein kinase was without effect on [3H]nitrendipine binding in both cardiac sarcolemmal and skeletal muscle membranes. Addition of exogenous calmodulin under conditions known to promote Ca2+/calmodulin-dependent phosphorylation increased [3H]nitrendipine binding 20% with no alteration in KD in both types of membrane preparation. These results suggest a role for calmodylin in dihydropyridine binding to L-type Ca2+ channels.     

Influence of liposome charge and composition on their interaction with human blood serum proteins

The roles of sulfhydryl and disulfide groups in the specific binding of synthetic cannabinoid CP-55,940 to the cannabinoid receptor in membrane preparations from the rat cerebral cortex have been examined. Various sulfhydryl blocking reagents including p-chloromercuribenzoic acid (p-CMB), N-ethylmaleimide (NEM), o-iodosobenzoic acid (o-ISB), and methyl methanethiosulfonate (MMTS) inhibited the specific binding of [³H]CP-55,940 to the cannabinoid receptor in a dose-dependent manner. About 80–95% inhibition was obtained at a 0.1 mM concentration of these reagents. Scatchard analysis of saturation experiments indicates that most of these sulfhydryl modifying reagents reduce both the binding affinity (K_d) and capacity (B_max). On the other hand, DL-dithiothreitol (DTT), a disulfide reducing agent, also irreversibly inhibited the specific binding of [³H]CP-55,940 to the receptor and about 50% inhibition was obtained at a 5 mM concentration. Furthermore, 5mM DTT was abelt to dissociate 50% of the bound ligand from the ligand-receptor complex. The marked inhibition of [³H]CP-55,940 binding by sulfhydryl reagents suggests that at least one free sulfhydryl group is essential to the binding of the ligand to the receptor. In addition, the inhibition of the binding by DTT implies that besides free sulfhydryl group(s), the integrity of a disulfide bridge is also important for [³H]CP-55,940 binding to the cannabinoid receptor.     

Disulfide bond interchange in Escherichia coli-derived recombinant human interferon-beta 1 under denaturing conditions

Disulfide bond interchange has been pointed out as a considerable problem in preparing recombinant proteins from Escherichia coli cells. This has been reported in the system of reducing denaturation followed by a refolding process, where incorrectly folded molecules are sometimes produced. As the possibility of disulfide bond interchange may also arise in the cytoplasm of E. coli cells, the state of sulfhydryl groups of recombinant proteins obtained from a nonreducing and nondenaturing process should be examined. The state of sulfhydryl groups of E. coli-derived recombinant human interferon-beta 1, which had been purified under nonreducing and nondenaturing conditions, was examined by using the N-(7-dimethylamino-4-methylcoumarinyl)maleimide (DACM) labeling technique. Among the three cysteine residues in E. coli-derived human interferon-beta 1, the 17th cysteine was identified as being unpaired, as in the natural molecule. However, it was found that three isomers of the recombinant protein could be formed when the protein was denatured with 6 M guanidine hydrochloride. These three isomers were identified as having unpaired cysteine residues at positions 17, 31, and 141, respectively. These results indicate that disulfide bond interchange occurs in E. coli-derived recombinant human interferon-beta 1 under denaturing conditions in spite of the absence of a reducing agent.     

Characterization of affinity-purified insulin receptor/kinase. Effects of dithiothreitol on receptor/kinase function

The insulin receptor/kinase was purified to near homogeneity from human placenta. The purified kinase exhibited a specific activity of 300 nmol/min/mg of protein at 30 degrees C using the synthetic peptide, Arg-Arg-Leu-Ile-Glu-Asp-Ala-Glu-Tyr-Ala-Ala-Arg-Gly, as substrate in the presence of insulin. Treatment of the receptor/kinase with dithiothreitol (DTT) reduced insulin binding by 40-50% and also inhibited tyrosine kinase activity. Phosphorylation and activation of the receptor/kinase did not prevent the DTT-induced loss of binding but completely protected it from the deleterious effects of reducing agent on enzymic activity. Analyses of the structure of the receptor/kinase following phosphorylation and treatment with DTT indicated that the class I disulfide bonds were reduced under the conditions employed, but the tetrameric structure of the receptor/kinase was essentially unaltered. These findings indicate that intact class I disulfides are required for insulin binding but are not necessary for maintenance of the preactivated kinase. DTT was also found to enhance the autoactivation of the insulin receptor/kinase and to promote the reversal of the autophosphorylation reaction. Thus disulfide bonds appear to have multiple roles in the function of the insulin receptor/kinase.     

Reoxidation of the class I disulfides of the rat adipocyte insulin receptor is dependent upon the presence of insulin: the class I disulfide of the insulin receptor is extracellular

Elements of the quaternary structure of the native and dithiothreitol- (DTT) reduced rat adipocyte insulin receptor have been elucidated by vectorial probing and subunit cross-linking. The charged reducing agents glutathione and beta-mercaptoethylamine were used to reduce the class I disulfides of the receptor in intact adipocytes, demonstrating the extracellular location of the disulfide directly. This interpretation was confirmed by use of DTT as a reducing agent and the nonpermeant sulfhydryl blocking reagent Thiolyte MQ to prevent the reoxidation of the class I sulfhydryl groups which occurred when they were not blocked. It was found that the above reoxidation of the receptor is dependent on the concentration of insulin in the nanomolar range, not occurring measurably at 4 degrees C in its absence. Cross-linking studies with ethylene glycol bis(succinimidyl succinate) demonstrated that the alpha subunits could not be cross-linked to each other after reduction of the class I disulfides, suggesting that the interaction between the receptor heterodimers may be due primarily to the disulfide bonds.     

Detection and quantification of free sulfhydryls in monoclonal antibodies using maleimide labeling and mass spectrometry

The detection of free sulfhydryls in proteins can reveal incomplete disulfide bond formation, indicate cysteine residues available for conjugation, and offer insights into protein stability and structure. Traditional spectroscopic methods of free sulfhydryl detection, such as Ellman’s reagent, generally require a relatively large amount of sample, preventing their use for the analysis of biotherapeutics early in the development cycle. These spectroscopic methods also cannot accurately determine the location of the free sulfhydryl, further limiting their utility. Mass spectrometry was used to detect free sulfhydryl residues in intact proteins after labeling with Maleimide-PEG₂-Biotin. As little as 2% cysteine residues with free sulfhydryls (0.02 mol SH per mol protein) could be detected by this method. Following reduction, the free sulfhydryl abundance on antibody heavy and light chains could be measured. To determine free sulfhydryl location at peptide-level resolution, free sulfhydryls and cysteines involved in disulfide bonds were differentially labeled with N-ethylmaleimide and d₅-N-ethylmaleimide, respectively. Following enzymatic digestion and nanoLC-MS, the abundance of free sulfhydryls at individual cysteine residues was quantified down to 2%. The method was optimized to avoid non-specific labeling, disulfide bond scrambling, and maleimide exchange and hydrolysis. This new workflow for free sulfhydryl analysis was used to measure the abundance and location of free sulfhydryls in 3 commercially available monoclonal antibody standards (NIST Monoclonal Antibody Reference Material (NIST), SILu?Lite SigmaMAb Universal Antibody Standard (Sigma-Aldrich) and Intact mAb Mass Check Standard (Waters)) and 1 small protein standard (β-Lactoglobulin A).     

Redox manipulation of DNA binding activity and BuGR epitope reactivity of the glucocorticoid receptor.

Treatment of the transformed glucocorticoid receptor with hydrogen peroxide promotes the formation of disulfide bonds and inhibits the ability of the receptor to bind to DNA (Tienrungroj, W., Meshinchi, S., Sanchez, E. R., Pratt, S. E., Grippo, J. F., Holmgren, A., and Pratt, W. B. (1987) J. Biol. Chem. 262, 6992-7000). It has not been determined whether the inhibition of DNA binding activity is due to disulfide bonds formed within the DNA binding domain or between the DNA binding domain and another region of the receptor. In this paper, we examined the ability of hydrogen peroxide to inactivate the DNA binding activity of the mouse glucocorticoid receptor. We show that inhibition of DNA binding activity caused by hydrogen peroxide can be accounted for entirely by the formation of disulfide bonds between cysteine residues lying within the 15-kDa tryptic fragment containing the DNA binding domain of the receptor. Reversal of the peroxide-induced inactivation of DNA binding activity requires both zinc and a thiol-disulfide exchange reagent, such as dithiothreitol. Peroxide also eliminates recognition of the intact receptor and the 15-kDa tryptic fragment by the BuGR monoclonal antibody, and the reactivity of the BuGR epitope is restored by reduction without a requirement for zinc. Pretreatment of the receptor with methyl methanethiosulfonate inhibits much of the peroxide-mediated inactivation of the BuGR epitope but pretreatment with N-ethylmaleimide does not. Similarly, DNA binding activity of the receptor is inhibited by methyl methanethiosulfonate but not by N-ethylmaleimide. These results are consistent with the proposal that peroxide promotes the formation of disulfide bonds between thiols that lie spatially close to one another in the 15-kDa tryptic fragment, resulting in rapid elimination of zinc. Restoration of the zinc finger structure restores DNA-binding activity but restoration of the BuGR epitope requires only reduction without restoration of the zinc fingers.     

Direct evidence for intra- and intermolecular disulfide bond formation in the human glucocorticoid receptor. Inhibition of DNA binding and identification of a new receptor-associated protein

We have investigated the potential for the steroid affinity-labeled human glucocorticoid receptor to form both intramolecular and intermolecular disulfide bonds. Glucocorticoid receptors labeled in intact HeLa S3 cells with the covalent affinity label [3H]dexamethasone mesylate ([3H]DM) were analyzed on denaturing 5-12% polyacrylamide gels under both nonreducing and reducing conditions. Under nonreducing conditions the affinity-labeled receptor migrated as a heterogeneous species having an average molecular mass of approximately 96 kDa whereas, under reducing conditions, the receptor migrated as a more discrete form. These data suggest that a reducing environment can influence the structure of the glucocorticoid receptor monomer and further imply that sulfhydryl groups within the affinity-labeled receptor are available for modification. To pursue this observation in greater detail, we tested the effect of oxidizing conditions on the structure of the glucocorticoid receptor. The presence of low concentrations (0.125-0.5 mM) of three oxidizing reagents (sodium tetrathionate, disulfiram, and iodosobenzoate) altered the migration of the affinity-labeled receptor resulting in forms of apparent lower molecular mass (as low as 78 kDa). This altered migration, not seen with most other cytosolic proteins, is consistent with the formation of intramolecular disulfide bonds within the receptor which presumably cause it to assume a folded conformation and migrate faster through the gel. At higher concentrations of these reagents (up to 5.0 mM), we also detect a saturably labeled [3H]DM band which has a higher molecular mass (approximately 140 kDa), indicating the formation of intermolecular disulfide bonds between the [3H]DM-labeled receptor and another closely associated protein(s) having a molecular mass of approximately 40 kDa. The effects which these oxidizing reagents have on glucocorticoid receptor structure are completely reversed upon the addition of dithiothreitol, indicating that the observed changes in migration do not reflect receptor proteolysis but rather a folding and unfolding within the receptor monomeric protein. We have also analyzed the effect of this oxidation/reduction on the function of the glucocorticoid receptor. Oxidation of the [3H]DM-labeled receptor complex with 0.5 mM sodium tetrathionate inhibited activation of receptor to a form capable of binding to DNA-cellulose. This inhibition can be reversed with dithiothreitol at 25 degrees C but not at 0 degrees C, suggesting that these oxidizing reagents are inhibitory at the transformation and/or activation steps.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of rat ovarian lutropin receptor. Role of thiol groups in receptor association

Rat ovarian lutropin receptor occurs predominantly as a monomer of an apparent molecular mass of 70 or 80 kDa determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing and reducing conditions, respectively. The receptor contains 0.4% free cysteine and 1.9% cysteine as cystine, determined by amino acid analysis of the S-carboxymethyl receptor prepared before and after reduction. The presence of free thiol groups was further shown by the specific adsorption of the receptor on p-chloromercuribenzoate-agarose and its susceptibility to 3H labeling with [3H]N-ethylmaleimide or [3H]iodoacetic acid. The receptor readily undergoes association into homo-oligomers. Evidence suggests that the association was caused by the intermolecular oxidation of the free -SH groups to form disulfide bonds. The aggregation could be induced by H2O2 or molecular O2 and was inhibited by sulfhydryl protecting agents such as N-ethylmaleimide, iodoacetic acid, dithiothreitol, cysteine, and Zn(II). The oligomers could be dissociated by reduction into a monomer. 125I-Labeling of the S-carboxymethyl- or N-ethylmaleyl receptor gave a single band of molecular mass 70 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Furthermore, S-alkylation of the receptor did not affect its binding to the ligand. On reduction, however, it lost its ability to bind to the ligand, but the reduced receptor retained its ability to bind to a specific polyclonal rabbit antireceptor antibody indicating the separation of the ligand and antibody binding sites. Endoproteinase Glu-C cleaved the receptor at a single glutamyl residue to give two components, 46 and 36 kDa. The 36-kDa component was extracellularly located since it contained the carbohydrate. On deglycosylation with endoglycosidase F, it yielded two components, 27 and 25 kDa. The deglycosylation of the reduced intact receptor (80 kDa) with endoglycosidase F occurred in two steps giving 73- and 64-kDa polypeptides, indicating the presence of about 20% carbohydrate contained in two or more N-linked chains.     

Reversible inactivation of AT(2) angiotensin II receptor from cysteine-disulfide bond exchange

Dithiothreitol (DTT) treatment of angiotensin II (Ang II) type 2 (AT(2)) receptor potentiates ligand binding, but the underlying mechanism is not known. Two disulfide bonds proposed in the extracellular domain were examined in this report. Based on the analysis of ligand affinity of cysteine (Cys, C) to alanine (Ala, A) substitution mutants, we provide evidence that Cys(35)-Cys(290) and Cys(117)-Cys(195) disulfide bonds are formed in the wild-type AT(2) receptor. Disruption of the highly conserved Cys(117)-Cys(195) disulfide bond linking the second and third extracellular segments leads to inactivation of the receptor. The Cys(35)-Cys(290) bond is highly sensitive to DTT. Its breakage results in an increased binding affinity for both Ang II and the AT(2) receptor-specific antagonist PD123319. Surprisingly, in the single Cys mutants, C35A and C290A, a labile population of receptors is produced which can be re-folded to high-affinity state by DTT treatment. These results suggest that the free -SH group of Cys(35) or Cys(290) competes with the disulfide bond formation between Cys(117) and Cys(195). This Cys-disulfide bond exchange results in production of the inactive population of the mutant receptors through formation of a non-native disulfide bond.     

Kinetic analyses of the surface-transmembrane disulfide bond isomerization-controlled fusion activation pathway in Moloney murine leukemia virus

The surface (SU) and transmembrane (TM) subunits of Moloney murine leukemia virus (Mo-MLV) Env are disulfide linked. The linking cysteine in SU is part of a conserved CXXC motif in which the other cysteine carries a free thiol. Recently, we showed that receptor binding activates its free thiol to isomerize the intersubunit disulfide bond into a disulfide within the motif instead (M. Wallin, M. Ekstr?m and H. Garoff, EMBO J. 23:54-65, 2004). This facilitated SU dissociation and activation of TM for membrane fusion. The evidence was mainly based on the finding that alkylation of the CXXC-thiol prevented isomerization. This arrested membrane fusion, but the activity could be rescued by cleaving the intersubunit disulfide bond with dithiothreitol (DTT). Here, we demonstrate directly that receptor binding causes SU-TM disulfide bond isomerization in a subfraction of the viral Envs. The kinetics of the isomerization followed that of virus-cell membrane fusion. Arresting the fusion with lysophosphatidylcholine did not arrest isomerization, suggesting that isomerization precedes the hemifusion stage of fusion. Our earlier finding that native Env was not possible to alkylate but required isomerization induction by receptor binding intimated that alkylation trapped an intermediate form of Env. To further clarify this possibility, we analyzed the kinetics by which the alkylation-sensitive Env was generated during fusion. We found that it followed the fusion kinetics. In contrast, the release of fusion from alkylated, isomerization-blocked virus by DTT reduction of the SU-TM disulfide bond was much faster. These results suggest that the alkylation-sensitive form of Env is a true intermediate in the fusion activation pathway of Env.     

Nonnative interactions between cysteines direct productive assembly of P22 tailspike protein

Nonnative disulfide bond formation can play a critical role in the assembly of disulfide bonded proteins. During the folding and assembly of the P22 tailspike protein, nonnative disulfide bonds form both in vivo and in vitro. However, the mechanism and identity of cysteine disulfide pairs remains elusive, particularly for P22 tailspike, which contains no disulfide bonds in its native, functional form. Understanding the interactions between cysteine residues is important for developing a mechanistic model for the role of nonnative cysteines in P22 tailspike assembly. Prior in vivo studies have suggested that cysteines 496, 613, and 635 are the most likely site for sulfhydryl reactivity. Here we demonstrate that these three cysteines are critical for efficient assembly of tailspike trimers, and that interactions between cysteine pairs lead to productive assembly of native tailspike.     

Effects of dithiothreitol on protein activity unrelated to thiol-disulfide exchange: for consideration in the analysis of protein function with Cleland's reagent

Dithiothreitol (DTT) is widely used to reduce disulfide bonds in the analysis of protein structure and function. However, thiol-disulfide exchange is not the only mechanism whereby DTT can alter protein function. We observe that DTT diminishes the carbohydrate binding activity of a cysteineless mutant of pigpen as well as it inhibits the intact molecule. Lack of inhibition by threitol, a derivative of the four-carbon sugar threose, indicates that the thiol groups of DTT are required for inhibition, and also that DTT is not acting as a simple carbohydrate competitor. Moreover, inhibition of pigpen-carbohydrate binding is not likely due to metal chelation because pigpen binding to carbohydrate is insensitive to EDTA and 1, 10-phenanthroline, which would otherwise be expected to mimic the DTT effect. Our results suggest that DTT can interact with protein domains in the absence of cysteine residues, and that the biochemical reactivity of DTT is not necessarily one and the same with its assumed biochemical specificity.