Autoxidizability of beef heart cytochrome c1 lacking the hinge protein c1-c

The autoxidizability of beef heart cytochrome c1 was investigated in terms of the integrity of the binding of the hinge protein to the heme subunit. Cytochrome c1 was isolated as a subcomplex consisting of the heme subunit and the hinge protein. Treatment of the cytochrome c1 subcomplex with p-chloromercuribenzoate (pCMB) under mild conditions lessened the binding strength between the two subunits. They were dissociated on polyacrylamide gel electrophoresis (PAGE) under nondenaturing conditions, but were not separated by gel filtration chromatography. The pCMB-treated subcomplex had a slight autoxidizability. This was repressed to the level of the native subcomplex, when the mercurial compound bound to the subcomplex was removed by the addition of 2-mercaptoethanol. Concomitantly, the less stable binding between the subunits was apparently reversed to the native state. After pCMB treatment of the subcomplex, the heme subunit recovered from PAGE showed marked autoxidizability, even if it was treated with 2-mercaptoethanol. Addition of cholate repressed the autoxidizability of the heme subunit after the removal of the mercurial compound. These results confirmed that the stable binding of the hinge protein to the heme subunit was essential for the nonautoxidizability of cytochrome c1 subcomplex. In addition, it was suggested that cysteinyl residues in the subcomplex must be involved to a great extent in the stable binding between the two subunits.     

Role of cysteine 41 of the A subunit of pertussis toxin

The 2 cysteine residues present in the A subunit of pertussis toxin form a disulfide bond in the conformation of the toxin secreted from the bacteria. Previous studies have shown that reduction of this bond is necessary for activation of the enzyme. We have found that reduction of this bond also alters the conformation of the A subunit such that it no longer readily associates with the B oligomer of the toxin, a finding which may have implications concerning the form of the toxin found within the eukaryotic cell. In addition, we have demonstrated that reduction of the disulfide bond of the purified A subunit followed by treatment with sulfhydryl-modifying reagents such as N-ethylmaleimide or 5,5'-dithiobis-(2-nitrobenzoic acid) results in inhibition of the NAD glycohydrolase activity of the protein. When a tryptic fragment of the A subunit which contains only 1 of the cysteine residues (Cys-41) of the native protein was reacted with N-ethylmaleimide, the NAD glycohydrolase activity of this fragment was substantially reduced. These data indicate that Cys-41 may be in a region of the molecule which is critical for the enzymatic activity of the toxin.     

Proteinase inhibition by proform of eosinophil major basic protein (pro-MBP) is a multistep process of intra- and intermolecular disulfide rearrangements

The metzincin metalloproteinase pregnancy-associated plasma protein A (PAPP-A, pappalysin-1) promotes cell growth by the cleavage of insulin-like growth factor-binding proteins-4 and -5, causing the release of bound insulin-like growth factors. The proteolytic activity of PAPP-A is inhibited by the proform of eosinophil major basic protein (pro-MBP), which forms a covalent 2:2 proteinase-inhibitor complex based on disulfide bonds. To understand the process of complex formation, we determined the status of cysteine residues in both of the uncomplexed molecules. A comparison of the disulfide structure of the reactants with the known disulfide structure of the PAPP-A.pro-MBP complex reveals that six cysteine residues of the pro-MBP subunit (Cys-51, Cys-89, Cys-104, Cys-107, Cys-128, and Cys-169) and two cysteine residues of the PAPP-A subunit (Cys-381 and Cys-652) change their status from the uncomplexed to the complexed states. Upon complex formation, three disulfide bonds of pro-MBP, which connect the acidic propiece with the basic, mature portion, are disrupted. In the PAPP-A.pro-MBP complex, two of these form the basis of both two interchain disulfide bonds between the PAPP-A and the pro-MBP subunits and two disulfide bonds responsible for pro-MBP dimerization, respectively. Based on the status of the reactants, we investigated the role of individual cysteine residues upon complex formation by mutagenesis of specific cysteine residues of both subunits. Our findings allow us to depict a hypothetical model of how the PAPPA.pro-MBP complex is formed. In addition, we have demonstrated that complex formation is greatly enhanced by the addition of micromolar concentrations of reductants. It is therefore possible that the activity in vivo of PAPP-A is controlled by the redox potential, and it is further tempting to speculate that such mechanism operates under pathological conditions of altered redox potential.     

Controlling the functionality of cytochrome c(1) redox potentials in the Rhodobacter capsulatus bc(1) complex through disulfide anchoring of a loop and a beta-branched amino acid near the heme-ligating methionine.

The cytochrome c(1) subunit of the ubihydroquinone:cytochrome c oxidoreductase (bc(1) complex) contains a single heme group covalently attached to the polypeptide via thioether bonds of two conserved cysteine residues. In the photosynthetic bacterium Rhodobacter (Rba.) capsulatus, cytochrome c(1) contains two additional cysteines, C144 and C167. Site-directed mutagenesis reveals a disulfide bond (rare in monoheme c-type cytochromes) anchoring C144 to C167, which is in the middle of an 18 amino acid loop that is present in some bacterial cytochromes c(1) but absent in higher organisms. Both single and double Cys to Ala substitutions drastically lower the +320 mV redox potential of the native form to below 0 mV, yielding nonfunctional cytochrome bc(1). In sharp contrast to the native protein, mutant cytochrome c(1) binds carbon monoxide (CO) in the reduced form, indicating an opening of the heme environment that is correlated with the drop in potential. In revertants, loss of the disulfide bond is remediated uniquely by insertion of a beta-branched amino acid two residues away from the heme-ligating methionine 183, identifying the pattern betaXM, naturally common in many other high-potential cytochromes c. Despite the unrepaired disulfide bond, the betaXM revertants are no longer vulnerable to CO binding and restore function by raising the redox potential to +227 mV, which is remarkably close to the value of the betaXM containing but loop-free mitochondrial cytochrome c(1). The disulfide anchored loop and betaXM motifs appear to be two independent but nonadditive strategies to control the integrity of the heme-binding pocket and raise cytochrome c midpoint potentials.     

Identification of in vivo disulfide conformation of TRPA1 ion channel

TRPA1 (transient receptor potential ankyrin 1) is an ion channel expressed in the termini of sensory neurons and is activated in response to a broad array of noxious exogenous and endogenous thiol-reactive compounds, making it a crucial player in chemical nociception. A number of conserved cysteine residues on the N-terminal domain of the channel have been identified as critical for sensing these electrophilic pungent chemicals, and our recent EM structure with modeled domains predicts that these cysteines form a ligand-binding pocket, allowing for the possibility of disulfide bonding between the cysteine residues. Here, we present a comprehensive mass spectrometry investigation of the in vivo disulfide bonding conformation and in vitro reactivity of 30 of the 31 cysteine residues in the TRPA1 ion channel. Four disulfide bonds were detected in the in vivo TRPA1 structure: Cys-666-Cys-622, Cys-666-Cys-463, Cys-622-Cys-609, and Cys-666-Cys-193. All of the cysteines detected were reactive to N-methylmaleimide (NMM) in vitro, with varying degrees of labeling efficiency. Comparison of the ratio of the labeling efficiency at 300 μM versus 2 mM NMM identified a number of cysteine residues that were outliers from the mean labeling ratio, suggesting that protein conformation changes rendered these cysteines either more or less protected from labeling at the higher NMM concentrations. These results indicate that the activation mechanism of TRPA1 may involve N-terminal conformation changes and disulfide bonding between critical cysteine residues.     

A homolog of prokaryotic thiol disulfide transporter CcdA is required for the assembly of the cytochrome b6f complex in Arabidopsis chloroplasts

The c-type cytochromes are defined by the occurrence of heme covalently linked to the polypeptide via thioether bonds between heme and the cysteine sulfhydryls in the CXXCH motif of apocytochrome. Maintenance of apocytochrome sulfhydryls in a reduced state is a prerequisite for covalent ligation of heme to the CXXCH motif. In bacteria, a thiol disulfide transporter and a thioredoxin are two components in a thio-reduction pathway involved in c-type cytochrome assembly. We have identified in photosynthetic eukaryotes nucleus-encoded homologs of a prokaryotic thiol disulfide transporter, CcdA, which all display an N-terminal extension with respect to their bacterial counterparts. The extension of Arabidopsis CCDA functions as a targeting sequence, suggesting a plastid site of action for CCDA in eukaryotes. Using PhoA and LacZ as topological reporters, we established that Arabidopsis CCDA is a polytopic protein with within-membrane strictly conserved cysteine residues. Insertional mutants in the Arabidopsis CCDA gene were identified, and loss-of-function alleles were shown to impair photosynthesis because of a defect in cytochrome b(6)f accumulation, which we attribute to a block in the maturation of holocytochrome f, whose heme binding domain resides in the thylakoid lumen. We postulate that plastid cytochrome c maturation requires CCDA, thioredoxin HCF164, and other molecules in a membrane-associated trans-thylakoid thiol-reducing pathway.     

A comparison of spectral and physicochemical properties of yeast iso-1 cytochrome c and Cys 102-modified derivatives of the protein

Derivatives of yeast iso-1 cytochrome c, chemically modified at Cys-102 (Cys-102 acetamide-derivatized monomer, Cys-102 thionitrobenzoate-derivatized monomer, Cys-102 S-methylated monomer, and the disulfide dimer), exhibit different spectral and physicochemical properties relative to the native, unmodified protein, depending on the nature of the modifying group. The results of proton NMR studies on the Cys-102 acetamidederivatized monomer of iso-1 ferricytochrome c indicate that the conformational characteristics of the heme environment in this protein derivative are intermediate between those of the unmodified monomer and disulfide dimer forms of the protein. Measurements of the pK_a of the alkaline transitions of the five forms of iso-1 ferricytochrome c provided values of 8.89, 8.82, 8.67, 8.47, and 8.50 for the unmodified monomer, S-methylated monomer, acetamide-derivatized monomer, thionitrobenzoate-derivatized monomer, and disulfide dimer, respectively. The results of proton NMR studies of the reduced form of these proteins suggest that the heme environments of the unmodified monomer and disulfide dimer derivatives of iso-1 ferrocytochrome c are similar and indicate that treatment of the thionitrobenzoate-derivatized and disulfide dimer forms of the protein with sodium dithionite results in cleavage of the disulfide bonds at position 102. Circular dichroism studies reveal that only the disulfide dimer form of iso-1 ferricytochrome c exhibits a Soret CD spectrum which differs from the native, unmodified monomer in that the intensity of the negative band at approximately 420 nm is diminished in the spectrum of the dimer relative to the spectrum of the monomer. Soret CD spectra of the ascorbate-reduced form of all protein derivatives are similar. The process of autoreduction of yeast iso-1 ferricytochrome c is shown to occur in the absence of a free sulfhydryl group at position 102 and is exacerbated under moderately high pH conditions. These results are suggestive of the presence of a redox-active amino acid, perhaps a tyrosine, in yeast iso-1 cytochrome c.     

Subunit interaction sites between the regulatory and catalytic subunits of cAMP-dependent protein kinase. Identification of a specific interchain disulfide bond

The catalytic (C) subunit and the type II regulatory (RII) subunit of cAMP-dependent protein kinase can be cross-linked by interchain disulfide bonding. This disulfide bond can be catalyzed by cupric phenanthroline and also can be generated by a disulfide interchange using either RII-subunit or C-subunit that has been modified with either 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or N-4(azidophenylthio)phthalimide (APTP). When the 2 cysteine residues of the C-subunit are reacted with DTNB prior to incubation with the RII-subunit, interchain disulfide bonding occurs. Similar observations are seen with C-subunit that had been modified with APTP. Interchain disulfide bonds also form when the RII-subunit is modified with DTNB prior to incubation with the C-subunit. The presence of cAMP facilitates this cross-linking while autophosphorylation of the RII-subunit retards the rate at which the interchain disulfide bond forms. Interchain disulfide bonds also form spontaneously when the RII-subunit and the C-subunit are dialyzed at pH 8.0 in the absence of reducing agents. The specific amino acid residues that participate in intersubunit disulfide bonding have been identified as Cys-97 in the RII-subunit and Cys-199 in the C-subunit. Based on the sequence homologies of the RII-subunit with other kinase substrates and on the proximity of Cys-97 to the catalytic site, a model is proposed in which the autophosphorylation site of the RII-subunit occupies the substrate-binding site in the holoenzyme. The model also proposes that this same site may be occupied by the region flanking Cys-199 in the C-subunit when the C-subunit is dissociated.     

Biochemical characterization of the thioredoxin domain of Escherichia coli DsbE protein reveals a weak reductant

Thioredoxin (Trx) domain is a typical fold functioning in thiol/disulfide exchange. DsbE protein is one of the Trx-domain containing proteins involved in electron transfer for cytochrome c maturation in the periplasm of Escherichia coli. The soluble C-terminal Trx domain of DsbE protein was overexpressed and purified to homogeneity. We herein report biochemical characterization of the structural and redox properties of this domain. During redox reaction, the domain undergoes a structural transformation resulting in a more stable reduced form with a free energy difference (DeltaDeltaG(Redox)) of ca. 5 kcal/mol, but the thiol/disulfide exchange exhibits very low reactivity. The standard redox potential (E0') for the active thiol/disulfide is -0.175 V and the pK(a) value of the active cysteine is around 6.8, indicating that the domain acts as a weak reductant. This implies that the membrane-anchored DsbE protein may provide driven reducing power for the redox reaction in the thiol/disulfide exchange pathway.     

Reactivity of the two essential cysteine residues of the periplasmic mercuric ion-binding protein, MerP

Reactivities of the two essential cysteine residues in the heavy metal binding motif, MTC(14)AAC(17), of the periplasmic Hg(2+)-binding protein, MerP, have been examined. While Cys-14 and Cys-17 have previously been shown to be Hg(2+)-binding residues, MerP is readily isolated in an inactive Cys-14-Cys-17 disulfide form. In vivo results demonstrated that these cysteine residues are reduced in the periplasm of Hg(2+)-resistant Escherichia coli. Denaturation and redox equilibrium studies revealed that reduced MerP is thermodynamically favored over the oxidized form. The relative stability of reduced MerP appears to be related to the lowered thiol pK(a) (5.5) of the Cys-17 side chain. Despite its much lower pK(a), the Cys-17 thiol is far less accessible than Cys-14, reacting 45 times more slowly with iodoacetamide at pH 7.5. This is reminiscent of proteins such as thioredoxin and DsbA, which contain a similar C-X-X-C motif, except in those cases the more exposed thiol has the lowered pK(a). In terms of MerP function, electrostatic attraction between Hg(2+) and the buried Cys-17 thiolate may be important for triggering the structural change that MerP has been reported to undergo upon Hg(2+) binding. Control of cysteine residue reactivity in heavy metal binding motifs may generally be important in influencing specific metal-binding properties of proteins containing them.     

Four free cysteine residues found in human IgG1 of healthy donors

Modifications with different thiol reagents demonstrated that 28 of 32 cysteine residues of human IgG1 are involved in the formation of disulfide bonds, and four cysteines remain free. So IgG1 is a protein possessing both free SH-groups and disulfide bonds. Only one of the four SH-groups is accessible for silver or mercury ions and hydrophobic reagents, whereas the remaining three SH-groups are masked and can be revealed only after deep denaturation of the protein. Detection of the masked cysteine residues was shown to depend on the kinetics of intramolecular changes occurring during denaturation of the protein and on the method of the assay of the SH-groups.     

The thiol groups of mouse immunoglobulin A. Incomplete formation of the C alpha 1-domain disulphide bridge.

The BALB/c IgA (immunoglobulin A) myeloma protein M167 contained on average 5.7 free SH groups per IgA dimer. These groups were preponderantly on the heavy chains and comprised two distinct populations: 3.3 exposed SH groups per dimer in the Fc region, and 2.4 buried SH groups per dimer in the Fd region, detectable o only after denaturation. To locate the cysteine residues involved, labelled peptides were purified from thermolysin digests of radioalkylated IgA by high-performance liquid chromatography. From the amino acid compositions of the peptides, the exposed thiol groups were assigned to Cys-307 in the C alpha 2 domain, which thus existed in the reduced form to an extent exceeding 80%. This residue may allow attachment of secretory component to dimer IgA in the mouse to proceed via thiol-disulphide exchange. The buried thiol groups were assigned to Cys-150 and Cys-208, in the C alpha 1 domain, each being in the reduced form to the extent of approx. 30%. This pair of residues would normally give rise to the characteristic intradomain disulphide bridge. It appears that disulphide formation is not a crucial event during folding of the C alpha 1 domain in IgA biosynthesis. The sequence in the region 140-151 was re-investigated, and residue 142 was shown to be serine, not cysteine, helping explain the lack of heavy-chain-light chain bonding in BALB/c mouse IgA. A disulphide-bond model for mouse IgA is proposed on the basis of these assignments and other features of the mouse alpha-chain sequence.     

Structural and redox properties of the leaderless DsbE (CcmG) protein: both active-site cysteines of the reduced form are involved in its function in the Escherichia coli periplasm

The thiol/disulfide oxidoreductases play important roles in ensuring the correct formation of disulfide bonds, of which the DsbE protein, also called CcmG, is the one implicated in electron transfer for cytochrome c maturation in the periplasm of Escherichia coli. The soluble, N-terminally truncated DsbE was overexpressed and purified to homogeneity. Here we report the structural and redox properties of the leaderless form (DsbEL-). During the redox reaction, the protein undergoes a structural transformation resulting in a more stable reduced form, but this form shows very low reactivity in thiol/ disulfide exchange of cysteine residues and low activity in accelerating the reduction of insulin. The standard redox potential (E'0) for the active thiol/ disulfide was determined to be -0.186 V; only one of the two cysteines (Cys80) was suggested to be the active residue in the redox reaction. From the aspect of biochemical properties, DsbE can be regarded as a weak reductant in the Escherichia coli periplasm. This implies that the function of DsbE in cytochrome c maturation can be ascribed to its active-site cysteines and the structure of the reduced form.     

Inactivation of rabbit muscle creatine kinase by reversible formation of an internal disulfide bond induced by the fungal toxin gliotoxin

The biological activity of gliotoxin is dependent on the presence of a strained disulfide bond that can react with accessible cysteine residues on proteins. Rabbit muscle creatine kinase contains 4 cysteines per 42-kDa subunit and is active in solution as a dimer. Only Cys-282 has been identified as essential for activity. Modification of this residue results in loss of activity of the enzyme. Treatment of creatine kinase with gliotoxin resulted in a time-dependent loss of activity abrogated in the presence of reducing agents. Activity was restored when the inactivated enzyme was treated with reducing agents. Inactivation of creatine kinase by gliotoxin was accompanied by the formation of a 37-kDa form of the enzyme. This oxidized form of creatine kinase was rapidly reconverted to the 42-kDa species by the addition of reducing agents concomitant with restoration of activity. A 1:1 mixture of the oxidized and reduced monomer forms of creatine kinase as shown on polyacrylamide gel electrophoresis was equivalent to the activity of the fully reduced form of the enzyme consistent with only one reduced monomer of the dimer necessary for complete activity. Conversion of the second monomeric species of the dimer to the oxidized form by gliotoxin correlated with loss of activity. Our data are consistent with gliotoxin inducing the formation of an internal disulfide bond in creatine kinase by initially binding and possibly activating a cysteine residue on the protein, followed by reaction with a second neighboring thiol. The recently published crystal structure of creatine kinase suggests the disulfide is formed between Cys-282 and Cys-73.     

Two-dimensional 1H NMR studies of cytochrome c: hydrogen exchange in the N-terminal helix

The hydrogen exchange behavior of the N-terminal helical segment in horse heart cytochrome c was studied in both the reduced and the oxidized forms by use of two-dimensional nuclear magnetic resonance methods. The amide protons of the first six residues are not H bonded and exchange rapidly with solvent protons. The most N-terminal H-bonded groups--the amide NH of Lys-7 to Phe-10--exhibit a sharp gradient in exchange rate indicative of dynamic fraying behavior, consistent with statistical-mechanical principles. This occurs identically in both reduced and oxidized cytochrome c. In the oxidized form, residues 11-14, which form the last helical turn, all exchange with a similar rate, about one million times slower than the rate characteristic of freely exposed peptide NH, even though some are on the aqueous face of the helix and others are fully buried. These and similar observations in several other proteins appear to document local cooperative unfolding reactions as determinants of protein H exchange reactions. The N-terminal segment of cytochrome c is insensitive to the heme redox state, as in the crystallographic model, except for residues closest to the heme (Cys-14 and Ala-15), which exchange about 15-fold more slowly in the reduced form. The cytochrome c H exchange results can be further considered in terms of the conformation of the native and the transiently unfolded forms and their free energy relationships in both the reduced and the oxidized states.     

Proton NMR comparison of the Saccharomyces cerevisiae ferricytochrome c isozyme-1 monomer and covalent disulfide dimer

Proton NMR studies of Saccharomyces cerevisiae (bakers yeast) isozyme-1 monomer and dimer ferricytochrome c have been carried out. The dimer is formed via a disulfide bridge between the Cys-102 residues of monomer proteins. Nuclear Overhauser effect (NOE) experiments have led to resonance assignments for many of the heme and axial ligand (Met-80; His-18) protons in both protein forms. Resonances of the following amino acids have also been assigned in both forms: Phe-10; Pro-30; Phe-82; Trp-59; Leu-68. The proton NOE connectivity patterns of the monomer of yeast isozyme-1 ferricytochrome c are similar to those of horse, tuna, and yeast isozyme-2 ferricytochromes c, even though the observed hyperfine resonance spectra are significantly different for the various cytochromes. The pattern of dimer proton hyperfine resonances is distinct from the isozyme-1 monomer pattern, which indicates that the formation of a disulfide bridge via Cys-102 is detected at the heme site, approximately 10 A distant. It appears that a specific structural change is induced upon dimerization, which, in turn, causes specific perturbations in the vicinity of the heme. However, the general features of the NOE connectivity pattern in the dimer are the same as for the monomer indicating that dimerization does not result in drastic structural disruption. Furthermore, the 1H NMR spectrum of the dimer can be mimicked by the monomer form that results when the -SH group of Cys-102 is chemically modified with certain types of bulky, or hydrophilic reagents (i.e. 5,5'-dithiobis[2-nitrobenzoate], indicating that perturbations of the yeast isozyme-1 ferricytochrome c proton resonance spectrum observed upon dimerization are essentially due to changes in intramolecular, rather than intermolecular, interactions. These results suggest that a possible regulatory site for yeast isozyme-1 cytochrome c exists at position 102, which could conceivably have a physiological role in altering the conformation of the molecule.     

Topological studies of monomeric and dimeric cytochrome c oxidase and identification of the copper A site using a fluorescence probe

Beef heart cytochrome c oxidase was labeled at a single sulfhydryl group by treatment with 5 mM N-iodoacetylamidoethyl-1-aminonaphthalene-5-sulfonate (1,5-I-AEDANS) at pH 8.0 for 4 h. Sodium dodecyl sulfate gel electrophoresis revealed that the enzyme was exclusively labeled at subunit III, presumably at Cys-115. The high affinity phase of the electron transfer reaction with horse cytochrome c was not affected by acetylamidoethyl-1-aminonaphthalene-5-sulfonate (AEDANS) labeling. Addition of horse cytochrome c to dimeric AEDANS-cytochrome c oxidase resulted in a 55% decrease in the AEDANS fluorescence due to the formation of a 1:1 complex between the two proteins. Forster energy transfer calculations indicated that the distance from the AEDANS label on subunit III to the heme group of cytochrome c was in the range 26-40 A. In contrast to the results with the dimeric enzyme, the fluorescence of monomeric AEDANS-cytochrome c oxidase was not quenched at all by binding horse heart cytochrome c, indicating that the AEDANS label on subunit III was at least 54 A from the heme group of cytochrome c. These results support a model in which the lysines surrounding the heme crevice of cytochrome c interact with carboxylates on subunit II of one monomer of the cytochrome c oxidase dimer and the back of the molecule is close to subunit III on the other monomer. In order to identify the cysteine residues that ligand copper A, a new procedure was developed to specifically remove copper A from cytochrome c oxidase by incubation with 2-mercaptoethanol followed by gel chromatography. Treatment of the copper A-depleted cytochrome c oxidase preparation with 1,5-I-AEDANS resulted in labeling sulfhydryl groups on subunit II as well as on subunit III. No additional subunits were labeled. This result indicates that the copper A binding site is located at cysteines 196 and/or 200 of subunit II and that removal of copper A exposes these residues for labeling by 1,5-I-AEDANS. Alternative copper A depletion methods involving incubation with bathocuproine sulfonate (Weintraub, S.T., and Wharton, D.C. (1981) J. Biol. Chem. 256, 1669-1676) or p-(hydroxymercuri)benzoate (Li, P.M., Gelles, J., Chan, S.I., Sullivan, R.J., and Scott, R.A. (1987) Biochemistry 26, 2091-2095) were also investigated. Treatment of these preparations with 1,5-I-AEDANS resulted in labeling cysteine residues on subunits II and III. However, additional sulfhydryl residues on other subunits were also labeled, preventing a definitive assignment of the location of copper A using these depletion procedures.     

Mutational analysis of disulfide bridges in the Mr 46,000 mannose 6-phosphate receptor. Localization and role for ligand binding

Formation of intramolecular disulfide bonds is a key step in the early maturation of newly synthesized Mr 46,000 mannose 6-phosphate receptors to acquire ligand-binding activity (Hille, A., Waheed, A., and von Figura, K. (1990) J. Cell Biol. 110, 963-972). The luminal domain of the receptor, which carries the ligand-binding site, contains 6 cysteine residues. We have analyzed the function of individual cysteine residues for the ligand-binding conformation by exchanging cysteine for glycine. In each case, the replacement of cysteine resulted in a complete loss of binding activity, indicating that all 6 luminal cysteine residues are required for the ligand-binding conformation. The cysteine mutants displayed a greatly reduced immunoreactivity, decreased stability, and a blocked or delayed transport to the trans Golgi. The glycosylation pattern allowed the distinguishing of three phenotypes, each of which was represented by one pair of cysteine mutants. Based on the assumption that replacement of either of the 2 cysteine residues forming a disulfide bond results in an identical phenotype, we postulate that disulfide bonds are formed between Cys-32 and Cys-78 and between Cys-132 and Cys-167, as well as between Cys-145 and Cys-179. This assumption was supported by the observation that the simultaneous exchange of the 2 cysteine residues of a putative pair resulted in the same phenotypes as the single exchange of either of the 2 cysteine residues.     

Chemical modification and inactivation of rat liver microsomal cytochrome P-450c by 2-bromo-4'-nitroacetophenone

The alkylating agent 2-bromo-4'-nitroacetophenone (BrNAP) binds covalently to each of 10 isozymes of purified rat liver microsomal cytochrome P-450 (P-450a-P-450j) but substantially inhibits the catalytic activity of only cytochrome P-450c. Regardless of pH, incubation time, presence of detergents, or concentration of BrNAP, treatment of cytochrome P-450c with BrNAP resulted in no more than 90% inhibition of catalytic activity. Alkylation with BrNAP did not cause the release of heme from the holoenzyme or alter the spectral properties of cytochrome P-450c, data that exclude the putative heme-binding cysteine, Cys-460, as the major site of alkylation. Two residues in cytochrome P-450c reacted rapidly with BrNAP, for which reason maximal loss of catalytic activity was invariably associated with the incorporation of approximately 1.5 mol of BrNAP/mol of cytochrome P-450c. Two major radio-labeled peptides were isolated from a tryptic digest of [14C]BrNAP-treated cytochrome P-450c by reverse-phase high performance liquid chromatography. The amino acid sequence of each peptide was determined by microsequence analysis, but the identification of the residues alkylated by BrNAP was complicated by the tendency of the adducts to decompose when subjected to automated Edman degradation. However, results of competitive binding experiments with the sulfhydryl reagent 4,4'-dithiodipyridine identified Cys-292 as the major site of alkylation and Cys-160 as the minor site of alkylation by BrNAP in cytochrome P-450c.     

Assignment of disulfide bridges in the fusion glycoprotein of Sendai virus.

The mature fusion (F) glycoprotein of the paramyxovirus family consists of two disulfide-linked subunits, the N-terminal F2 and the C-terminal F1 subunits, and contains 10 cysteine residues which are highly conserved at specific positions. The high level of conservation strongly suggests that they are indeed disulfide linked and play important roles in the folding and functioning of the molecule. However, it has not even been clarified which cysteine residues link the F2 and F1 subunits. This report describes our assignment of the disulfide bridges in purified Sendai virus F glycoprotein by fragmentation of the polypeptide and isolation of cystine-containing peptides and determination of their N-terminal sequences. The data demonstrate that all of the 10 cysteine residues participate in disulfide bridges and that Cys-70, the only cysteine in F2, and Cys-199, the most upstream cysteine in F1, form the interchain bond. Of the remaining eight cysteine residues clustered near the transmembrane domain of F1, the specific bridges identified are Cys-338 to Cys-347 and Cys-362 to Cys-370. Although no exact pairings between the subsequent four residues were defined, it seems likely that the most downstream, Cys-424, is linked to Cys-394, Cys-399, or Cys-401. Thus, we conclude that the cysteine-rich domain indeed contributes to the formation of a bunched structure containing at least two tandem cystine loops.