Sequential protection-modification method for selective sulfhydryl group derivatization in proteins having more than one cysteine

The method of Smith and Hartman [J. Biol. Chem., 263, 4921-4925 (1988)] for introducing the non-natural lysine analog, S-(2-aminoethyl)cysteine, into specific sites in proteins by alkylation of a genetically introduced cysteine with 2-bromoethylamine has been generalized to be applicable to proteins containing one or more endogenous cysteines. The target cysteine residue introduced at the active site of aspartate aminotransferase is protected by bound cofactor. The enzyme is partially unfolded in low concentrations of urea, and the non-active site cysteine residues derivatized by a reversible thiol protecting reagent. The active site cysteine is then exposed and alkylated in 6 M urea. Enzyme activity is regenerated by removal of the thiol protecting groups and refolding of the protein.     

Identification of the reactive cysteines of Escherichia coli 5-enolpyruvylshikimate-3-phosphate synthase and their nonessentiality for enzymatic catalysis

Reaction of 5-enolpyruvylshikimate-3-phosphate synthase of Escherichia coli with the thiol reagent 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) leads to a modification of only 2 of the 6 cysteines of the enzyme, with a significant loss of its enzymatic activity. Under denaturing conditions, however, all 6 cysteines of 5-enolpyruvylshikimate-3-phosphate synthase react with DTNB, indicating the absence of disulfide bridges in the native protein. In the presence of shikimate 3-phosphate and glyphosate, only 1 of the 2 cysteines reacts with the reagent, with no loss of activity, suggesting that only 1 of these cysteines is at or near the active site of the enzyme. Cyanolysis of the DTNB-inactivated enzyme with KCN leads to elimination of 5-thio-2-nitrobenzoate, with formation of the thiocyano-enzyme. The thiocyano-enzyme is fully active; it exhibits a small increase in its I50 for glyphosate (6-fold) and apparent Km for phosphoenolpyruvate (4-fold) compared to the unmodified enzyme. Its apparent Km for shikimate 3-phosphate is, however, unaltered. These results clearly establish the nonessentiality of the active site-reactive cysteine of E. coli 5-enolpyruvylshikimate-3-phosphate synthase for either catalysis or substrate binding. Perturbations in the kinetic constants for phosphoenolpyruvate and glyphosate suggest that the cysteine thiol is proximal to the binding site for these ligands. By N-[14C]ethylmaleimide labeling, tryptic mapping, and N-terminal sequencing, the 2 reactive cysteines have been identified as Cys408 and Cys288. The cysteine residue protected by glyphosate and shikimate 3-phosphate from its reaction with DTNB was found to be Cys408.     

Cysteine labeling studies of beef heart aconitase containing a 4Fe, a cubane 3Fe, or a linear 3Fe cluster

The reactivity of cysteines following cluster destruction by iron chelation was investigated for [4Fe-4S]2+ and cubane [3Fe-4S]+ beef heart aconitase. When the chelator orthobathophenanthroline disulfonate was used, the formation of sulfur-sulfur bonds and the retention of inorganic sulfur from the cluster was observed. For both the 4Fe and 3Fe forms of aconitase, the two cysteines in peptide 7, the cysteine in peptide 3, and the cysteine in peptide 2 were found as the primary constituents of sulfur-sulfur bonds (the peptide sequences and nomenclature are from Plank, D. W., and Howard, J. B. (1988) J. Biol. Chem. 263, 8184-8189). Three of these four cysteines (peptides 3 and 7) correlated with those proposed to be cluster ligands recently determined by x-ray crystallography (Robbins, A. H. and Stout, C. D. (1989) Proteins, in press; Robbins, A. H., and Stout, C. D.,, (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 3639-3643) for pig heart aconitase. A mechanism is proposed whereby the greater affinity of orthobathophenanthroline disulfonate for Fe2+ relative to Fe3+ shifts the equilibrium toward reduction of ferric iron through sulfur-sulfur bond formation at the cluster site. Aconitase which has been oxidized with ferricyanide and from which the cluster iron has been removed by EDTA has been shown to have two di- or polysulfides (Kennedy, M. C., and Beinert, H. (1988) J. Biol. Chem. 263, 8194-8198). The cysteines found in the sulfur-sulfur bonds generated by this treatment also were predominantly those from peptides 3 and 7. In addition, the putative thiol ligands for the linear [3Fe-4S]+ cluster of aconitase are reported. The four cysteines of peptides 7 and 9 (two in each peptide) were found to be protected by the cluster from alkylation when the protein was denatured. The difference in the ligands between the cubane and linear forms indicates that a specific thiol exchange occurs during the conversion.     

Identification of the zinc ligands in cobalamin-independent methionine synthase (MetE) from Escherichia coli

Cobalamin-independent methionine synthase (MetE) from Escherichia coli catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine to form tetrahydrofolate and methionine. It contains 1 equiv of zinc that is essential for its catalytic activity. Extended X-ray absorption fine structure analysis of the zinc-binding site has suggested tetrahedral coordination with two sulfur (cysteine) and one nitrogen or oxygen ligands provided by the enzyme and an exchangeable oxygen or nitrogen ligand that is replaced by the homocysteine thiol group in the enzyme-substrate complex [González, J. C., Peariso, K., Penner-Hahn, J. E., and Matthews, R. G. (1996) Biochemistry 35, 12228-34]. Sequence alignment of MetE homologues shows that His641, Cys643, and Cys726 are the only conserved residues. We report here the construction, expression, and purification of the His641Gln, Cys643Ser, and Cys726Ser mutants of MetE. Each mutant displays significantly impaired activity and contains less than 1 equiv of zinc upon purification. Furthermore, each mutant binds zinc with lower binding affinity (K(a) approximately 10(14) M(-)(1)) compared to the wild-type enzyme (K(a) > 10(16) M(-)(1)). All the MetE mutants are able to bind homocysteine. X-ray absorption spectroscopy analysis of the zinc-binding sites in the mutants indicates that the four-coordinate zinc site is preserved but that the ligand sets are changed. Our results demonstrate that Cys643 and Cys726 are two of the zinc ligands in MetE from E. coli and suggest that His641 is a third endogenous ligand. The effects of the mutations on the specific activities of the mutant proteins suggest that zinc and homocysteine binding alone are not sufficient for activity; the chemical nature of the ligands is also a determining factor for catalytic activity in agreement with model studies of the alkylation of zinc-thiolate complexes.     

Characterization of the disulfide bonds and free cysteine residues of the Chlamydia trachomatis mouse pneumonitis major outer membrane protein

Members of the genus Chlamydia lack a peptidoglycan layer. As a substitute for peptidoglycan, it has been proposed that several cysteine rich proteins, including the major outer membrane protein (MOMP), form disulfide bonds to provide rigidity to the cell wall. Alignment of the amino acids sequences of the MOMP from various serovars of Chlamydia showed that they have from 7 to 10 cysteine residues and seven of them are highly conserved. Which of these are free cysteine residues and which are involved in disulfide bonds is unknown. The complexity of the outer membrane of Chlamydia precludes at this point the characterization of the structure of the cysteines directly in the bacteria. Therefore, mass spectrometric analysis of a purified and refolded MOMP was used in this study. Characterization of the structure of this preparation of the MOMP is critical because it has been shown, in an animal model, to be a very effective vaccine against respiratory and genital infections. Here, we demonstrated that in this MOMP preparation four cysteines are involved in disulfide bonds, with intramolecular pairs formed between Cys(48) and Cys(55) and between Cys(201) and Cys(203). A stepwise alkylation, reduction, alkylation process using two different alkylating reagents was required to establish the Cys(48)-Cys(55) disulfide pair. The other residues in MOMP, Cys(51), Cys(136), Cys(226), and Cys(351), are free cysteines and could potentially form disulfide-linked complexes with other MOMP or other membrane proteins.     

Properties of the cysteine residues and the iron-sulfur cluster of the assimilatory 5'-adenylyl sulfate reductase from Enteromorpha intestinalis

The 5'-adenylyl sulfate (APS) reductase from the marine macrophytic green alga Enteromorpha intestinalis uses reduced glutathione as the electron donor for the reduction of APS to 5'-AMP and sulfite. The E. intestinalis enzyme (EiAPR) is composed of a reductase domain and a glutaredoxin-like C-terminal domain. The enzyme contains a single [4Fe-4S] cluster as its sole prosthetic group. Three of the enzyme's eight cysteine residues (Cys166, Cys257, and Cys260) serve as ligands to the iron-sulfur cluster. Site-directed mutagenesis experiments and resonance Raman spectroscopy are consistent with the presence of a cluster in which only three of the four ligands to the cluster irons contributed by the protein are cysteine residues. Site-directed mutagenesis experiments suggest that the thiol group of Cys250, a residue found only in algal APS reductases, is not an absolute requirement for activity. The other four cysteines that do not serve as cluster ligands, all of which are required for activity, are involved in the formation of two redox-active disulfide/dithiol couples. The couple involving Cys342 and Cys345 has an E(m) value at pH 7.0 of -140 mV, and the one involving Cys165 and Cys285 has an E(m) value at pH 7.0 of -290 mV. The C-terminal portion of EiAPR, expressed separately, exhibits the cystine reductase activity characteristic of glutaredoxins. It is proposed that the Cys342-Cys345 disulfide provides the site for entry of electrons from reduced glutathione and that the Cys166-Cys285 disulfide may serve as a structural element that is essential for keeping the enzyme in the catalytically active conformation.     

Crystal structure of the Vibrio cholerae ferric uptake regulator (Fur) reveals insights into metal co-ordination

The ferric uptake regulator (Fur) is a metal-dependent DNA-binding protein that acts as both a repressor and an activator of numerous genes involved in maintaining iron homeostasis in bacteria. It has also been demonstrated in Vibrio cholerae that Fur plays an additional role in pathogenesis, opening up the potential of Fur as a drug target for cholera. Here we present the crystal structure of V. cholerae Fur that reveals a very different orientation of the DNA-binding domains compared with that observed in Pseudomonas aeruginosa Fur . Each monomer of the dimeric Fur protein contains two metal binding sites occupied by zinc in the crystal structure. In the P. aeruginosa study these were designated as the regulatory site (Zn1) and structural site (Zn2). This V. cholerae Fur study, together with studies on Fur homologues and paralogues, suggests that in fact the Zn2 site is the regulatory iron binding site and the Zn1 site plays an auxiliary role. There is no evidence of metal binding to the cysteines that are conserved in many Fur homologues, including Escherichia coli Fur. An analysis of the metal binding properties shows that V. cholerae Fur can be activated by a range of divalent metals.     

Localization of disulfide bonds in the cystine knot domain of human von Willebrand factor

von Willebrand factor (VWF) is a multimeric glycoprotein that is required for normal hemostasis. After translocation into the endoplasmic reticulum, proVWF subunits dimerize through disulfide bonds between their C-terminal cystine knot-like (CK) domains. CK domains are characterized by six conserved cysteines. Disulfide bonds between cysteines 2 and 5 and between cysteines 3 and 6 define a ring that is penetrated by a disulfide bond between cysteines 1 and 4. Dimerization often is mediated by additional cysteines that differ among CK domain subfamilies. When expressed in a baculovirus system, recombinant VWF CK domains (residues 1957-2050) were secreted as dimers that were converted to monomers by selective reduction and alkylation of three unconserved cysteine residues: Cys(2008), Cys(2010), and Cys(2048). By partial reduction and alkylation, chemical and proteolytic digestion, mass spectrometry, and amino acid sequencing, the remaining intrachain disulfide bonds were characterized: Cys(1961)-Cys(2011) (), Cys(1987)-Cys(2041) (), Cys(1991)-Cys(2043) (), and Cys(1976)-Cys(2025). The mutation C2008A or C2010A prevented dimerization, whereas the mutation C2048A did not. Symmetry considerations and molecular modeling based on the structure of transforming growth factor-beta suggest that one or three of residues Cys(2008), Cys(2010), and Cys(2048) in each subunit mediate the covalent dimerization of proVWF.     

Cys(x)His(y)-Zn2+ interactions: thiol vs. thiolate coordination

In zinc proteins, the Zn2+ cation frequently binds with a tetrahedral coordination to cysteine and histidine side chains, for example, in many DNA-binding proteins, where it plays primarily a structural role. We examine the possibility of thiolate protonation in Cys(x)His(y)-Zn2+ groups, both in proteins and in solution, through a combination of theoretical calculations and database analysis. Seventy-five percent of the thiolate-coordinated zincs in the Cambridge Structural Database are tetrahedral, while di-alkanethiol coordination always involves five or more ligands. Ab initio quantum calculations are performed on (ethanethiol/thiolate)(3)imidazole-Zn2+ complexes in vacuum, yielding geometries and gas phase basicities. Protonating one (respectively two) thiolates increases the Zn-S(thiol) distance by 0.4 A (respectively 0.3 A), providing a structural marker for protonation. The stabilities of the complexes in solution are compared by combining the gas phase basicities with continuum dielectric solvation calculations. In a continuum solvent with permittivity epsilon = 4, 20, or 80, one of three thiolates is predicted to be protonated at neutral pH. By extension, Cys4-Zn2+ groups are expected to be protonated in the same conditions. In contrast, most Cys3His and Cys4 geometries in the Protein Data Bank (PDB) appear consistent with all-thiolate Zn2+ coordination. This apparent discrepancy is resolved by two recent surveys of zinc protein structures, which suggest that these all-thiolate sites are stabilized by charged and polar groups nearby in the protein, thus overcoming their intrinsic instability. However, the experimental resolution is not sufficient in all the PDB structures to rule out a thiol/thiolate mixture, and protonated thiolates may occur in some proteins not solved at high resolution or not represented in the PDB, as suggested by recent mass spectrometry experiments; this possibility should be allowed for in X-ray structure refinement.     

Derivatization of the interface cysteine of triosephosphate isomerase from Trypanosoma brucei and Trypanosoma cruzi as probe of the interrelationship between the catalytic sites and the dimer interface

In the interface of homodimeric triosephosphate isomerase from Trypanosoma brucei (TbTIM) and Trypanosoma cruzi (TcTIM), one cysteine of each monomer forms part of the intersubunit contacts. The relatively slow derivatization of these cysteines by sulfhydryl reagents induces progressive structural alterations and abolition of catalysis [Garza-Ramos et al. (1998) Eur. J. Biochem. 253, 684-691]. Derivatization of the interface cysteine by 5, 5-dithiobis(2-nitrobenzoate) (DTNB) and methylmethane thiosulfonate (MMTS) was used to probe if events at the catalytic site are transmitted to the dimer interface. It was found that enzymes in the active catalytic state are significantly less sensitive to the thiol reagents than in the resting state. Maximal protection against derivatization of the interface cysteine by thiol reagents was obtained at near-saturating substrate concentrations. Continuous recording of derivatization by DTNB showed that catalysis hinders the reaction of sulfhydryl reagents with the interface cysteine. Therefore, in addition to intrinsic structural barriers, catalysis imposes additional impediments to the action of thiol reagents on the interface cysteine. In TcTIM, the substrate analogue phosphoglycolate protected strongly against DTNB action, and to a lesser extent against MMTS action; in TbTIM, phosphoglycolate protected against the effect of DTNB, but not against the action of MMTS. This indicates that barriers of different magnitude to the reaction of thiol reagents with the interface cysteine are induced by the events at the catalytic site. Studies with a Cys14Ser mutant of TbTIM confirmed that all the described effects of sulfhydryl reagents on the trypanosomal enzymes are a consequence of derivatization of the interface cysteine.     

Juxtaposition of the two distal CX3C motifs via intrachain disulfide bonding is essential for the folding of Tim10

The TIM10 complex, composed of the homologous proteins Tim10 and Tim9, chaperones hydrophobic proteins inserted at the mitochondrial inner membrane. A salient feature of the TIM10 complex subunits is their conserved "twin CX3C" motif. Systematic mutational analysis of all cysteines of Tim10 showed that their underlying molecular defect is impaired folding (demonstrated by circular dichroism, aberrant homo-oligomer formation, and thiol trapping assays). As a result of defective folding, clear functional consequences were manifested in (i) complex formation with Tim9, (ii) chaperone activity, and (iii) import into tim9ts mitochondria lacking both endogenous Tim9 and Tim10. The organization of the four cysteines in intrachain disulfides was determined by trypsin digestion and mass spectrometry. The two distal CX3C motifs are juxtaposed in the folded structure and disulfide-bonded to each other rather than within each other, with an inner cysteine pair connecting Cys44 with Cys61 and an outer pair between Cys40 and Cys65. These cysteine pairs are not equally important for folding and assembly; mutations of the inner Cys are severely affected and form wrong, non-native disulfides, in contrast to mutations of the outer Cys that can still maintain the native inner disulfide pair and display weaker functional defects. Taken together these data reveal this specific intramolecular disulfide bonding as the crucial mechanism for Tim10 folding and show that the inner cysteine pair has a more prominent role in this process.     

Identification of two cysteine residues forming a pair of vicinal thiols in glucosamine-6-phosphate deaminase from Escherichia coli and a study of their functional role by site-directed mutagenesis.

The nucleotide sequence of the nagB gene in Escherichia coli, encoding glucosamine-6-phosphate deaminase, located four cysteinyl residues at positions 118, 219, 228, and 239. Chemical modification studies performed with the purified enzyme had shown that the sulfhydryl groups of two of these residues form a vicinal pair in the enzyme and are easily modified by thiol reagents. The allosteric transition to the more active conformer (R), produced by the binding of homotropic (D-glucosamine 6-phosphate or 2-deoxy-2-amino-D-glucitol 6-phosphate) or heterotropic (N-acetyl-D-glucosamine 6-phosphate) ligands, completely protected these thiols against chemical modification. Selective cyanylation of the vicinal thiols with 2-nitro-5-(thiocyanato)benzoate, followed by alkaline hydrolysis to produce chain cleavage at the modified cysteines, gave a pattern of polypeptides which allowed us to identify Cys118 and Cys239 as the residues forming the thiol pair. Subsequently, three mutated forms of the gene were constructed by oligonucleotide-directed mutagenesis, in which one or both of the cysteine codons were changed to serine. The mutant proteins were overexpressed and purified, and their kinetics were studied. The dithiol formed by Cys118 and Cys239 was necessary for maximum catalytic activity. The single replacements and the double mutation affected catalytic efficiency in a similar way, which was also identical to the effect of the chemical block of the thiol pair. However, only one of these cysteinyl residues, Cys239, had a significant role in the allosteric transition, and its substitution for serine reduced the allosteric interaction energy, due to a lower value of KT.     

Identification of the cysteine nitrosylation sites in human endothelial nitric oxide synthase

S-nitrosylation, or the replacement of the hydrogen atom in the thiol group of cysteine residues by a -NO moiety, is a physiologically important posttranslational modification. In our previous work we have shown that S-nitrosylation is involved in the disruption of the endothelial nitric oxide synthase (eNOS) dimer and that this involves the disruption of the zinc (Zn) tetrathiolate cluster due to the S-nitrosylation of Cysteine 98. However, human eNOS contains 28 other cysteine residues whose potential to undergo S-nitrosylation has not been determined. Thus, the goal of this study was to identify the cysteine residues within eNOS that are susceptible to S-nitrosylation in vitro. To accomplish this, we utilized a modified biotin switch assay. Our modification included the tryptic digestion of the S-nitrosylated eNOS protein to allow the isolation of S-nitrosylated peptides for further identification by mass spectrometry. Our data indicate that multiple cysteine residues are capable of undergoing S-nitrosylation in the presence of an excess of a nitrosylating agent. All these cysteine residues identified were found to be located on the surface of the protein according to the available X-ray structure of the oxygenase domain of eNOS. Among those identified were Cys 93 and 98, the residues involved in the formation of the eNOS dimer through a Zn tetrathiolate cluster. In addition, cysteine residues within the reductase domain were identified as undergoing S-nitrosylation. We identified cysteines 660, 801, and 1113 as capable of undergoing S-nitrosylation. These cysteines are located within regions known to bind flavin mononucleotide (FMN), flavin adenine dinucleotide (FAD), and nicotinamide adenine dinucleotide (NADPH) although from our studies their functional significance is unclear. Finally we identified cysteines 852, 975/990, and 1047/1049 as being susceptible to S-nitrosylation. These cysteines are located in regions of eNOS that have not been implicated in any known biochemical functions and the significance of their S-nitrosylation is not clear from this study. Thus, our data indicate that the eNOS protein can be S-nitrosylated at multiple sites other than within the Zn tetrathiolate cluster, suggesting that S-nitrosylation may regulate eNOS function in ways other than simply by inducing dimer collapse.     

Highly conserved cysteines of mouse core 2 beta1,6-N-acetylglucosaminyltransferase I form a network of disulfide bonds and include a thiol that affects enzyme activity

Core 2 beta1,6-N-acetylglucosaminyltransferase I (C2GnT-I) plays a pivotal role in the biosynthesis of mucin-type O-glycans that serve as ligands in cell adhesion. To elucidate the three-dimensional structure of the enzyme for use in computer-aided design of therapeutically relevant enzyme inhibitors, we investigated the participation of cysteine residues in disulfide linkages in a purified murine recombinant enzyme. The pattern of free and disulfide-bonded Cys residues was determined by liquid chromatography/electrospray ionization tandem mass spectrometry in the absence and presence of dithiothreitol. Of nine highly conserved Cys residues, under both conditions, one (Cys217) is a free thiol, and eight are engaged in disulfide bonds, with pairs formed between Cys59-Cys413, Cys100-Cys172, Cys151-Cys199, and Cys372-Cys381. The only non-conserved residue within the beta1,6-N-acetylglucosaminyltransferase family, Cys235, is also a free thiol in the presence of dithiothreitol; however, in the absence of reductant, Cys235 forms an intermolecular disulfide linkage. Biochemical studies performed with thiolreactive agents demonstrated that at least one free cysteine affects enzyme activity and is proximal to the UDP-GlcNAc binding site. A Cys217 --> Ser mutant enzyme was insensitive to thiol reactants and displayed kinetic properties virtually identical to those of the wild-type enzyme, thereby showing that Cys217, although not required for activity per se, represents the only thiol that causes enzyme inactivation when modified. Based on the pattern of free and disulfide-linked Cys residues, and a method of fold recognition/threading and homology modeling, we have computed a three-dimensional model for this enzyme that was refined using the T4 bacteriophage beta-glucosyltransferase fold.     

Neighboring cysteine residues in human fucosyltransferase VII are engaged in disulfide bridges, forming small loop structures.

Among alpha 3-fucosyltransferases (alpha3-FucTs) from most species, four cysteine residues appear to be highly conserved. Two of these cysteines are located at the N-terminus and two at the C-terminus of the catalytic domain. FucT VII possesses two additional cysteines in close proximity to each other located in the middle of the catalytic domain. We identified the disulfide bridges in a recombinant, soluble form of human FucT VII. Potential free cysteines were modified with a biotinylated alkylating reagent, disulfide bonds were reduced and alkylated with iodoacetamide, and the protein was digested with either trypsin or chymotrypsin, before characterization by high-performance liquid chromatography/electrospray ionization mass spectrometry. More than 98% of the amino acid sequence for the truncated enzyme (beginning at amino acid 53) was verified. Mass spectrometry analysis also demonstrated that both potential N-linked sites are occupied. All six cysteines in the FucT VII sequence were shown to be disulfide-linked. The pairing of the cysteines was determined by proteolytic cleavage of nonreduced protein and subsequent analysis by mass spectrometry. The results demonstrated that Cys(68)-Cys(76), Cys(211)-Cys(214), and Cys(318)-Cys(321) are disulfide-linked. We have used this information, together with a method of fold recognition and homology modeling, using the (alpha/beta)(8)-barrel fold of Escherichia coli dihydrodipicolinate synthase as a template to propose a model for FucT VII.     

Cys359 of GrdD is the active-site thiol that catalyses the final step of acetyl phosphate formation by glycine reductase from Eubacterium acidaminophilum.

In the amino-acid-fermenting anaerobe Eubacterium acidaminophilum, acetyl phosphate is synthesized by protein C of glycine reductase from a selenoprotein A-bound carboxymethyl-selenoether. We investigated specific thiols present in protein C for responsibility for acetyl phosphate liberation. After cloning of the genes encoding the large and the small subunit (grdC1, grdD1), they were expressed separately in Escherichia coli and purified as Strep-tag proteins. GrdD was the only subunit that catalysed arsenate-dependent hydrolysis of acetyl phosphate (up to 274 U.mg-1), whereas GrdC was completely inactive. GrdD contained two cysteine residues that were exchanged by site-directed mutagenesis. The GrdD(C98S) mutant enzyme still catalysed the hydrolysis of acetyl phosphate, but the GrdD(C359A) mutant enzyme was completely inactive. Next, these thiols were analysed further by chemical modification. After iodoacetate treatment of GrdD, the enzyme activity was lost, but in the presence of acetyl phosphate enzyme activity was protected. Subsequently, the inactivated carboxymethylated enzyme and the protected enzyme were both denatured, and the remaining thiols were pyridylethylated. Peptides generated by proteolytic cleavage were separated and subjected to mass spectrometry. Cys98 was not accessible to carboxymethylation by iodoacetate in the native enzyme in the presence or absence of the substrate, but could be alkylated after denaturation. Cys359, in contrast, was protected from carboxymethylation in the presence of acetyl phosphate, but became accessible to pyridylethylation upon prior denaturation of the protein. This clearly confirmed the catalytic role of Cys359 as the active site thiol of GrdD responsible for liberation of acetyl phosphate.     

Fluorescence energy transfer between cysteine 199 and cysteine 343: evidence for MgATP-dependent conformational change in the catalytic subunit of cAMP-dependent protein kinase

The catalytic subunit of cAMP-dependent protein kinase has two cysteine residues, Cys 199 and Cys 343, which are protected against alkylation by MgATP [Nelson, N. C., & Taylor, S. S. (1981) J. Biol. Chem. 256, 3743]. While Cys 199 is in close proximity to the active site of the catalytic subunit and is probably directly protected against alkylation by MgATP, the mechanism by which MgATP prevents alkylation of Cys 343 is unclear. To determine whether MgATP directly protects Cys 343 from alkylation by being in close proximity to both Cys 199 and the MgATP binding site, fluorescence resonance energy transfer techniques were used to measure the distance between Cys 199 and Cys 343. Two different donor-acceptor pairs containing 4-[N-[(iodoacetoxy)ethyl]-N-methylamino]-7-nitrobenz-2-oxa-1,3-diazole at Cys 199 as the acceptor and either 3,6,7-trimethyl-4-(bromomethyl)-1,5-diazabicyclo[3.3.0]octa-3,6-diene-2, 8- dione or N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine at Cys 343 as the donor were prepared following the method described in the preceding paper [First, E. A., & Taylor, S. S. (1989) Biochemistry (preceding paper in this issue)]. From the efficiencies of fluorescence resonance energy transfer for each donor-acceptor pair, the distance between Cys 199 and Cys 343 was estimated to be between 31 and 52 A. Since Cys 199 is close to the MgATP binding site and since MgATP cannot extend beyond a distance of 16 A, it is unlikely that Cys 343 at a distance of at least 31 A from Cys 199 is in direct contact with the bound nucleotide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Keap1, the sensor for electrophiles and oxidants that regulates the phase 2 response, is a zinc metalloprotein

Induction of the phase 2 response, a major cellular reaction to oxidative/electrophile stress depends on a protein triad: actin-tethered Keap1 that binds to Nrf2. Inducers react with Keap1 releasing Nrf2 for nuclear translocation and activation of the antioxidant response element (ARE), which regulates phase 2 genes. The primary sensors for inducers are certain uniquely reactive cysteine thiols of Keap1. Recombinant murine Keap1 contains 0.9 zinc atoms per monomer as determined by inductively coupled plasma-optical emission spectrometry: its zinc content depends on the metal composition of the overexpression medium. Simultaneous direct measurement of bound zinc using a pyridazoresorcinol chelator and protein thiol groups using 4,4'-dipyridyl disulfide has established that (i) zinc is bound to reactive cysteine thiols of Keap1 and is displaced stoichiometrically by inducers, (ii) with these cysteines mutated to alanine, the affinity for zinc is reduced by nearly 2 orders of magnitude, and (iii) the association constant of Keap1 for zinc is 1.02 (+/-0.19) x 10(11) M(-)(1), consistent with a Zn(2+) metalloprotein. Co(2+) substitution for Zn(2+) yields an optical spectrum consistent with tetrahedral metal coordination. Coincident binding of inducers and release of zinc alters the conformation of Keap1, as shown by a profound decline of its tryptophan fluorescence and depression of fluorescence of a hydrophobicity probe. Thus, regulation of the phase 2 response involves chemical modification of critical cysteine residues of Keap1, whose reactivity is modulated by zinc binding. Keap1 is a zinc-thiol protein endowed with a delicate switch controlled by both metal-binding and thiol reactivity.     

The iron-sulfur center of biotin synthase: site-directed mutants

Biotin synthase contains an essential [4Fe-4S]+ cluster that is thought to provide an electron for the cleavage of S-adenosylmethionine, a cofactor required for biotin formation. The conserved cysteine residues Cys53, Cys57 and Cys60 have been proposed as ligands to the [4Fe-4S] cluster. These residues belong to a C-X3-C-X2-C motif which is also found in pyruvate formate lyase-activating enzyme, lysine 2,3-aminomutase and the anaerobic ribonucleotide reductase-activating component. To investigate the role of the cysteine residues, Cys-->Ala mutants of the eight cysteine residues of Escherichia coli biotin synthase were prepared and assayed for activity. Our results show that six cysteines are important for biotin formation. Only two mutant proteins, C276A and C288A, closely resembled the wild-type protein, indicating that the corresponding cysteines are not involved in iron chelation and biotin formation. The six other mutant proteins, C53A, C57A, C60A, C97A, C128A and C188A, were inactive but capable of assembling a [4Fe-4S] cluster, as shown by M?ssbauer spectroscopy. The C53A, C57A and C60A mutant proteins are unique in that their cluster could not undergo reduction to the [4Fe-4S]+ state, as shown by EPR and M?ssbauer spectroscopy. On this basis and by analogy with pyruvate formate lyase-activating enzyme and the anaerobic ribonucleotide reductase-activating component, it is suggested that the corresponding cysteines coordinate the cluster even though one cannot fully exclude the possibility that other cysteines play that role as well. Therefore it appears that for activity biotin synthase absolutely requires cysteines that are not involved in iron chelation.