Mouse T-cell antigen rt6.1 has thiol-dependent NAD glycohydrolase activity

Mouse Rt6.1 and Rt6.2, homologues of rat T-cell RT6 antigens, catalyze arginine-specific ADP-ribosylation. Without an added ADP-ribose acceptor, Rt6.2 shows NAD glycohydrolase (NADase) activity. However, Rt6.1 has been reported to be primarily an ADP-ribosyltransferase, but not an NADase. In the present study, we obtained evidence that recombinant Rt6.1 catalyzes NAD glycohydrolysis but only in the presence of DTT. The NADase activity of Rt6.1 observed in the presence of DTT was completely inhibited by N-ethylmaleimide (NEM). Native Rt6.1 antigen, immunoprecipitated from BALB/c mouse splenocytes with polyclonal antibodies generated against recombinant RT6.1, also exhibited NADase activity in the presence of DTT. Compared with Rt6.2, Rt6.1 has two extra cysteine residues at positions 80 and 201. When Cys-80 and Cys-201 in Rt6.1 were replaced with the corresponding residues of Rt6.2, serine and phenylalanine, respectively, Rt6.1 catalyzed the NADase reaction even in the absence of DTT. Conversely, replacing Ser-80 and Phe-201 in Rt6.2 with cysteines, as in Rt6.1, converted the thiol-independent Rt6.2 NADase to a thiol-dependent enzyme. Kinetic study of the NADase reaction revealed that the affinity of Rt6.1 for NAD and the rate of catalysis increased in the presence of DTT. Moreover, the NADase activity of Rt6.1 expressed on COS-7 cells was stimulated by culture supernatant from activated mouse macrophages, even in the absence of DTT. From these observations, we conclude that t!he Rt6.1 antigen has thiol-dependent NADase activity, and that Cys-80 and Cys-201 confer thiol sensitivity to Rt6.1 NADase. Our results also suggest that upon the interaction of T-cells expressing Rt6.1 with activated macrophages, the NADase activity of the antigen will be stimulated.     

Expression and mutagenesis of the novel serpin endopin 2 demonstrates a requirement for cysteine-374 for dithiothreitol-sensitive inhibition of elastase

The primary sequence of the serpin endopin 2 predicts a reactive site loop (RSL) region that possesses high homology to bovine elastase inhibitor, suggesting inhibition of elastase. Moreover, endopin 2 possesses two cysteine residues that implicate roles for reduced Cys residue(s) for inhibitory activity. To test these predicted properties, mutagenesis and chemical modification of recombinant endopin 2 were performed to examine the influence of dithiothreitol (DTT), a reducing agent, on endopin 2 activity. Endopin 2 inhibited elastase in a DTT-dependent manner, with enhanced inhibition in the presence of DTT. The stoichiometry of inhibition in the presence of DTT occurred at a molar ratio of endopin 2 to elastase of 8/1, resulting in complete inhibition of elastase. However, a higher molar ratio (25/1) was required in the absence of DTT. DTT enhanced the formation of SDS-stable complexes of endopin 2 and elastase, a characteristic property of serpins. Site-directed mutagenesis of endopin 2, with substitution of Ala for Cys-232 or Cys-374, demonstrated that Cys-374 (but not Cys-232) was required for the DTT-sensitive nature of endopin 2. Chemical modification of Cys-374 by bis(maleimido)ethane also reduced inhibitory activity. Modified electrophoretic mobilities of mutant endopin 2 suggested the presence of intramolecular disulfide bonds; in addition, chemical modification suggested that Cys-374 influences the electrophoretic and conformational properties of endopin 2. Moreover, the reducing agent glutathione enhanced endopin 2 activity, suggesting that glutathione can function as an endogenous reducing agent for endopin 2 in vivo. These findings demonstrate the importance of Cys-374 for DTT-sensitive inhibition of elastase by endopin 2.     

The V108M mutation decreases the structural stability of catechol O-methyltransferase

The human gene for catechol O-methyltransferase has a common single-nucleotide polymorphism that results in substitution of methionine (M) for valine (V) 108 in the soluble form of the enzyme (s-COMT). 108M s-COMT loses enzymatic activity more rapidly than 108V s-COMT at physiological temperature, and the 108M allele has been associated with increased risk of breast cancer and several neuropsychiatric disorders. We used circular dichroism (CD), dynamic light scattering, and fluorescence spectroscopy to examine how the 108V/M polymorphism affects the stability of the purified, recombinant protein to heat and guanidine hydrochloride (GuHCl). COMT contains two tryptophan residues, W143 and W38Y, which are located in loops that border the S-adenosylmethionine (SAM) and catechol binding sites. We therefore also studied the single-tryptophan mutants W38Y and W143Y in order to dissect the contributions of the individual tryptophans to the fluorescence signals. The 108V and 108M proteins differed in the stability of both the tertiary structure surrounding the active site, as probed by the fluorescence yields and emission spectra, and their global secondary structure as reflected by CD. With either probe, the midpoint of the thermal transition of 108M s-COMT was 5 to 7 degrees C lower than that of 108V s-COMT, and the free energy of unfolding at 25 degrees C was smaller by about 0.4 kcal/mol. 108M s-COMT also was more prone to aggregation or partial unfolding to a form with an increased radius of hydration at 37 degrees C. The co-substrate SAM stabilized the secondary structure of both 108V and 108M s-COMT. W143 dominates the tryptophan fluorescence of the folded protein and accounts for most of the decrease in fluorescence that accompanies unfolding by GuHCl. While replacing either tryptophan by tyrosine was mildly destabilizing, the lower stability of the 108M variant was retained in all cases.     

Activation of thiol-dependent antioxidant activity of human serum albumin by alkaline pH is due to the B-like conformational change

Antioxidant activity of human serum albumin (HSA) increased steeply as the reaction mixture was shifted from neutral to alkaline pH. The antioxidant activity was also remarkably increased by Ca(2+) or a cationic detergent (cetyltrimethylammonium chloride). Carboxyl group modification of HSA resulted in about 40-fold increase of the antioxidant activity. The chemical modification study indicated that in addition to functional cysteine(s), cationic amino acid residues such as histidine, arginine and lysine appeared to involve in the antioxidant reaction. HSA also exhibited alkaline-pH dependent peroxidase activity to remove fatty acid hydroperoxide. At neutral pH, only two thiols of Cys-289 and free Cys-34 of HSA were modified by a thiol-specific modification reagent, 5-((((2-iodoacetyl)amino)ethy)amino)naphthalene-1-sulfonic acid (I14), regardless of the presence or absence of dithiothreitol (DTT), and the resultant antioxidant activity was not decreased, suggesting that Cys-289 and Cys-34 did not participate in the antioxidant reaction. At alkaline pH, I14 modified several additional HSA thiols in the presence, but did not in the absence of DTT. The antioxidant activity of the modified HSA was remarkably decreased to as much as 30% of the antioxidant activity given by the unmodified HSA in the absence of DTT. The HPLC pattern for tryptic peptides containing modified cysteine(s) derived from the I14-treated c-HSA (carboxyl group-modified HSA) at pH 7.0 with DTT was very similar to that of the I14-modified HSA at pH 8.0 with DTT. Taken together, these results suggest that activation of thiol-dependent antioxidant activity of HSA at alkaline pH is due to the conformational change favorable for the functional cysteine(s)-mediated catalysis.     

Influence of multiple cysteines on human 3-hydroxy-3-methylglutaryl-CoA lyase activity and formation of inter-subunit adducts

Human 3-hydroxy-3-methylglutaryl-CoA lyase catalyzes formation of acetyl-CoA and acetoacetate in a reaction that requires divalent cation and is stimulated by sulfhydryl protective reagents. The enzyme is a homodimer and inter-subunit adducts form in the absence of reducing agents or upon treatment with cysteine selective crosslinking agents. To address the influence of cysteines on enzyme activity and formation of inter-subunit and intra-subunit adducts, single serine substitutions have been engineered for each enzyme cysteine. Enzyme activity varies for each cysteine→serine mutant protein and different mutations have widely different effects on recovery of activity upon DTT treatment of non-reduced enzyme. These levels of enzyme activity do not strongly correlate with formation of inter-subunit adducts by these HMGCL mutants. C170S, C266S, and C323S proteins do not form inter-subunit disulfide adducts but such an adduct is restored in the C170S/C174S double mutant. Coexpression of HMGCL proteins encoded by C266S and C323S expression plasmids supports formation of a C266S/C323S heterodimer which does form a covalent inter-subunit adduct. These observations are interpreted in the context of competition between cysteines in formation of intra-subunit and inter-subunit heterodisulfide adducts.     

A conformationally sensitive residue on the cytoplasmic surface of serotonin transporter

Serotonin transporter (SERT) contains a single reactive external cysteine residue at position 109 (Chen, J. G., Liu-Chen, S., and Rudnick, G. (1997) Biochemistry 36, 1479-1486) and seven predicted cytoplasmic cysteines. A mutant of rat SERT (X8C) in which those eight cysteine residues were replaced by other amino acids retained approximately 32% of wild type transport activity and approximately 56% of wild type binding activity. In contrast to wild-type SERT or the C109A mutant, X8C was resistant to inhibition of high affinity cocaine analog binding by the cysteine reagent 2-(aminoethyl)methanethiosulfonate hydrobromide (MTSEA) in membrane preparations from transfected cells. Each predicted cytoplasmic cysteine residue was reintroduced, one at a time, into the X8C template. Reintroduction of Cys-357, located in the third intracellular loop, restored MTSEA sensitivity similar to that of C109A. Replacement of only Cys-109 and Cys-357 was sufficient to prevent MTSEA sensitivity. Thus, Cys-357 was the sole cytoplasmic determinant of MTSEA sensitivity in SERT. Both serotonin and cocaine protected SERT from inactivation by MTSEA at Cys-357. This protection was apparently mediated through a conformational change following ligand binding. Although both ligands bind in the absence of Na(+) and at 4 degrees C, their ability to protect Cys-357 required Na(+) and was prevented at 4 degrees C. The accessibility of Cys-357 to MTSEA inactivation was increased by monovalent cations. The K(+) ion, which is believed to serve as a countertransport substrate for SERT, was the most effective ion for increasing Cys-357 reactivity.     

Identification of a Disulfide Bridge Important for Transport Function of SNAT4 Neutral Amino Acid Transporter

SNAT4 is a member of system N/A amino acid transport family that primarily expresses in liver and muscles and mediates the transport of L-alanine. However, little is known about the structure and function of the SNAT family of transporters. In this study, we showed a dose-dependent inhibition in transporter activity of SNAT4 with the treatment of reducing agents, dithiothreitol (DTT) and Tris(2-carboxyethyl)phosphine (TCEP), indicating the possible involvement of disulfide bridge(s). Mutation of residue Cys-232, and the two highly conserved residues Cys-249 and Cys-321, compromised the transport function of SNAT4. However, this reduction was not caused by the decrease of SNAT4 on the cell surface since the cysteine-null mutant generated by replacing all five cysteines with alanine was equally capable of being expressed on the cell surface as wild-type SNAT4. Interestingly, by retaining two cysteine residues, 249 and 321, a significant level of L-alanine uptake was restored, indicating the possible formation of disulfide bond between these two conserved residues. Biotinylation crosslinking of free thiol groups with MTSEA-biotin provided direct evidence for the existence of a disulfide bridge between Cys-249 and Cys-321. Moreover, in the presence of DTT or TCEP, transport activity of the mutant retaining Cys-249 and Cys-321 was reduced in a dose-dependent manner and this reduction is gradually recovered with increased concentration of H₂O₂. Disruption of the disulfide bridge also decreased the transport of L-arginine, but to a lesser degree than that of L-alanine. Together, these results suggest that cysteine residues 249 and 321 form a disulfide bridge, which plays an important role in substrate transport but has no effect on trafficking of SNAT4 to the cell surface.     

Identification of the [Fe-S] cluster-binding residues of Escherichia coli biotin synthase

The gene encoding Escherichia coli biotin synthase (bioB) has been expressed as a histidine fusion protein, and the protein was purified in a single step using immobilized metal affinity chromatography. The His(6)-tagged protein was fully functional in in vitro and in vivo biotin production assays. Analysis of all the published bioB sequences identified a number of conserved residues. Single point mutations, to either serine or threonine, were carried out on the four conserved (Cys-53, Cys-57, Cys-60, and Cys-188) and one non-conserved (Cys-288) cysteine residues, and the purified mutant proteins were tested both for ability to reconstitute the [2Fe-2S] clusters of the native (oxidized) dimer and enzymatic activity. The C188S mutant was insoluble. The wild-type and four of the mutant proteins were characterized by UV-visible spectroscopy, metal and sulfide analysis, and both in vitro and in vivo biotin production assays. The molecular masses of all proteins were verified using electrospray mass spectrometry. The results indicate that the His(6) tag and the C288T mutation have no effect on the activity of biotin synthase when compared with the wild-type protein. The C53S, C57S, and C60S mutant proteins, both as prepared and reconstituted, were unable to covert dethiobiotin to biotin in vitro and in vivo. We conclude that three of the conserved cysteine residues (Cys-53, Cys-57, and Cys-60), all of which lie in the highly conserved "cysteine box" motif, are crucial for [Fe-S] cluster binding, whereas Cys-188 plays a hitherto unknown structural role in biotin synthase.     

Versatility and differential roles of cysteine residues in human prostacyclin receptor structure and function

Prostacyclin plays important roles in vascular homeostasis, promoting vasodilatation and inhibiting platelet thrombus formation. Previous studies have shown that three of six cytoplasmic cysteines, particularly those within the C-terminal tail, serve as important lipidation sites and are differentially conjugated to palmitoyl and isoprenyl groups (Miggin, S. M., Lawler, O. A., and Kinsella, B. T. (2003) J. Biol. Chem. 278, 6947-6958). Here we report distinctive roles for extracellular- and transmembrane-located cysteine residues in human prostacyclin receptor structure-function. Within the extracellular domain, all cysteines (4 of 4) appear to be involved in disulfide bonding interactions (i.e. a highly conserved Cys-92-Cys-170 bond and a putative non-conserved Cys-5-Cys-165 bond), and within the transmembrane (TM) region there are several cysteines (3 of 8) that maintain critical hydrogen bonding interactions (Cys-118 (TMIII), Cys-251 (TMVI), and Cys-202 (TMV)). This study highlights the necessity of sulfhydryl (SH) groups in maintaining the structural integrity of the human prostacyclin receptor, as 7 of 12 extracellular and transmembrane cysteines studied were found to be differentially indispensable for receptor binding, activation, and/or trafficking. Moreover, these results also demonstrate the versatility and reactivity of these cysteine residues within different receptor environments, that is, extracellular (disulfide bonds), transmembrane (H-bonds), and cytoplasmic (lipid conjugation).     

Importance of cysteines in the LDLR-related domain of the subgroup A avian leukosis and sarcoma virus receptor for viral entry.

The extracellular domain of the subgroup A avian sarcoma and leukemia virus (ALSV-A) receptor contains a region that is related in sequence to the ligand-binding motifs of the low-density lipoprotein receptor (LDLR). This domain contains six cysteines that are highly conserved between different members of the LDLR protein superfamily, and these residues are presumed to participate in intrachain disulfide bonds. To assess the importance of each cysteine in the ALSV-A receptor, individual or multiple cysteines were mutated to alanines and the altered receptors were tested for the ability to confer susceptibility to viral infection. Receptors bearing single mutations allowed subgroup A viral entry, albeit at less than wild-type levels. Receptors containing two or three substitutions were completely inactive if one of the changed residues was Cys-35 or Cys-50. Of the altered receptors tested, the only exception to this rule was a functional receptor which lacked both Cys-35 and Cys-50, an activity that was dependent on the presence of other cysteines in this protein. Most interestingly, a receptor containing both Cys-35 and Cys-50 but lacking the other four cysteines was completely functional. These results demonstrate the importance of Cys-35 and Cys-50 for viral entry mediated by the ALSV-A receptor and show that in the presence of these two residues, all of the other cysteines in this protein can be removed without loss of this function.     

The local electrostatic environment determines cysteine reactivity of tubulin

Of the 20 cysteines of rat brain tubulin, some react rapidly with sulfhydryl reagents, and some react slowly. The fast reacting cysteines cannot be distinguished with [14C]iodoacetamide, N-[(14)C]ethylmaleimide, or IAEDANS ([5-((((2-iodoacetyl)amino)ethyl)amino) naphthalene-1-sulfonic acid]), since modification to mole ratios 1 cysteine/dimer always leads to labeling of 6-7 cysteine residues. These have been identified as Cys-305alpha, Cys-315alpha, Cys-316alpha, Cys-347alpha, Cys-376alpha, Cys-241beta, and Cys-356beta by mass spectroscopy and sequencing. This lack of specificity can be ascribed to reagents that are too reactive; only with the relatively inactive chloroacetamide could we identify Cys-347alpha as the most reactive cysteine of tubulin. Using the 3.5-A electron diffraction structure, it could be shown that the reactive cysteines were within 6.5 A of positively charged arginines and lysines or the positive edges of aromatic rings, presumably promoting dissociation of the thiol to the thiolate anion. By the same reasoning the inactivity of a number of less reactive cysteines could be ascribed to inhibition of modification by negatively charged local environments, even with some surface-exposed cysteines. We conclude that the local electrostatic environment of cysteine is an important, although not necessarily the only, determinant of its reactivity.     

Aurothiomalate inhibits transformed growth by targeting the PB1 domain of protein kinase Ciota

We recently identified the gold compound aurothiomalate (ATM) as a potent inhibitor of the Phox and Bem1p (PB1)-PB1 domain interaction between protein kinase C (PKC) iota and the adaptor molecule Par6. ATM also blocks oncogenic PKCiota signaling and the transformed growth of human lung cancer cells. Here we demonstrate that ATM is a highly selective inhibitor of PB1-PB1 domain interactions between PKCiota and the two adaptors Par6 and p62. ATM has no appreciable inhibitory effect on other PB1-PB1 domain interactions, including p62-p62, p62-NBR1, and MEKK3-MEK5 interactions. ATM can form thio-gold adducts with cysteine residues on target proteins. Interestingly, PKCiota (and PKCzeta) contains a unique cysteine residue, Cys-69, within its PB1 domain that is not present in other PB1 domain containing proteins. Cys-69 resides within the OPR, PC, and AID motif of PKCiota at the binding interface between PKCiota and Par6 where it interacts with Arg-28 on Par6. Molecular modeling predicts formation of a cysteinyl-aurothiomalate adduct at Cys-69 that protrudes into the binding cleft normally occupied by Par6, providing a plausible structural explanation for ATM inhibition. Mutation of Cys-69 of PKCiota to isoleucine or valine, residues frequently found at this position in other PB1 domains, has little or no effect on the affinity of PKCiota for Par6 but confers resistance to ATM-mediated inhibition of Par6 binding. Expression of the PKCiota C69I mutant in human non-small cell lung cancer cells confers resistance to the inhibitory effects of ATM on transformed growth. We conclude that ATM inhibits cellular transformation by selectively targeting Cys-69 within the PB1 domain of PKCiota.     

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.     

The roles of thiols in the bacterial organomercurial lyase (MerB)

The bacterial plasmid-encoded organomercurial lyase, MerB (EC 4.99.1.2), catalyzes the protonolysis of organomercury compounds yielding Hg(II) and the corresponding protonated hydrocarbon. A small, soluble protein with no known homologues, MerB is widely distributed among eubacteria in three phylogenetically distinct subfamilies whose most prominent motif includes three conserved cysteine residues. We found that the 212-residue MerB encoded by plasmid R831b is a cytosolic enzyme, consistent with its high thiol requirement in vitro. MerB is inhibited by the nonphysiological dithiol DTT but uses the physiological thiols, glutathione and cysteine, equally well. Highly conserved Cys96 and Cys159 are essential for activity, whereas weakly conserved Cys160 is not. Proteins mutant in highly conserved Cys117 are insoluble. All MerB cysteines are DTNB-reactive in native and denatured states except Cys117, which fails to react with DTNB in the native form, suggesting it is buried. Mass spectrometric analysis of trypsin fragments of reduced proteins treated with N-ethylmaleimide or iodoacetamide revealed that all cysteines form covalent adducts and remain covalently modifiable even when exposed to 1:1 PHMB prior to treatment with NEM or IAM. Stable PHMB adducts were also observed on all cysteines in mutant proteins, suggesting rapid exchange of PHMB among the remaining protein thiols. However, PHMB exposure of reduced wild-type MerB yielded only Hg adducts on the Cys159/Cys160 peptide, suggesting a trapped reaction intermediate. Using HPLC to follow release of benzoic acid from PHMB, we confirmed that fully reduced wild-type MerB and mutant C160S can carry out a single protonolysis without exogenous thiols. On the basis of the foregoing we refine the previously proposed S(E)2 mechanism for protonolysis by MerB.     

Cysteines involved in radical generation and catalysis of class III anaerobic ribonucleotide reductase. A protein engineering study of bacteriophage T4 NrdD

Class III ribonucleotide reductase (RNR) is an anaerobic glycyl radical enzyme that catalyzes the reduction of ribonucleotides to deoxyribonucleotides. We have investigated the importance in the reaction mechanism of nine conserved cysteine residues in class III RNR from bacteriophage T4. By using site-directed mutagenesis, we show that two of the cysteines, Cys-79 and Cys-290, are directly involved in the reaction mechanism. Based on the positioning of these two residues in the active site region of the known three-dimensional structure of the phage T4 enzyme, and their structural equivalence to two cysteine residues in the active site region of the aerobic class I RNR, we suggest that Cys-290 participates in the reaction mechanism by forming a transient thiyl radical and that Cys-79 participates in the actual reduction of the substrate. Our results provide strong experimental evidence for a similar radical-based reaction mechanism in all classes of RNR but also identify important differences between class III RNR and the other classes of RNR as regards the reduction per se. We also identify a cluster of four cysteines (Cys-543, Cys-546, Cys-561, and Cys-564) in the C-terminal part of the class III enzyme, which are essential for formation of the glycyl radical. These cysteines make up a CX(2)C-CX(2)C motif in the vicinity of the stable radical at Gly-580. We propose that the four cysteines are involved in radical transfer between Gly-580 and the cofactor S-adenosylmethionine of the activating NrdG enzyme needed for glycyl radical generation.     

Identification of reactive cysteines in a protein using arsenic labeling and collision-induced dissociation tandem mass spectrometry

Trivalent arsenicals have high affinity for thiols (such as free cysteines) in proteins. We describe here the use of this property to develop a collision-induced dissociation (CID) tandem mass spectrometry (MS/MS) technique for the identification of reactive cysteines in proteins. A trivalent arsenic species, dimethylarsinous acid (DMA (III)), with a residue mass (103.9607) and mass defect distinct from the normal 20 amino acids, was used to selectively label reactive cysteine residues in proteins. The CID fragment ions of the arsenic-labeled sequences shifted away from the more abundant normal fragments that would otherwise overlap with the ions of interest. Along with the internal and immonium ions, the arsenic-labeled fragment ions served as MS/MS signatures for identification of the binding sites and for assessment of the relative reactivity of individual cysteine residues in a protein. Using this method, we have identified two highly reactive binding sites in rat hemoglobin (Hb): Cys-13alpha and Cys-125beta. Cys-13alpha was bound to DMA (III) in the Hb of rats fed with arsenic, and this binding was responsible for arsenic accumulation in rat blood, while Cys-125beta was found to bind to glutathione in rat blood. This study revealed the relative reactivity of the cysteines in rat Hb in the following decreasing order: Cys-13alpha > Cys-111alpha > Cys-104alpha and Cys-13alpha > Cys-125beta > Cys-93beta. Arsenic-labeling is easy and fast for identification of active binding sites without enzymatic digestion and acid hydrolysis, and useful for characterization and identification of metal binding sites in other proteins.     

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.     

Mutational analysis of the cysteine residues in the hepatitis B virus small envelope protein.

The small envelope protein of hepatitis B virus is the major component of the viral coat and is also secreted from cells as a 20-nm subviral particle, even in the absence of other viral proteins. Such empty envelope particles are composed of approximately 100 copies of this polypeptide and host-derived lipids and are stabilized by extensive intermolecular disulfide cross-linking. To study the contribution of disulfide bonds to assembly and secretion of the viral envelope, single and multiple mutants involving all 14 cysteines in HepG2 and COS-7 cells were analyzed. Of the six cysteines located outside the region carrying the surface antigen, Cys-48, Cys-65, and Cys-69 were each found to be essential for secretion of 20-nm particles, whereas Cys-76, Cys-90, and Cys-221 were dispensable. By introduction of an additional cysteine substituting serine 58, the yield of secreted particles was increased. Of four mutants involving the eight cysteines located in the antigenic region, only the double mutant lacking Cys-121 and Cys-124 was secreted with wild-type efficiency. Secretion-competent envelope proteins were intracellularly retained by secretion-deficient cysteine mutants. According to alkylation studies, both intracellular and secreted envelope proteins contained free sulfhydryl groups. Disulfide-linked oligomers were studied by gel electrophoresis under nonreducing conditions.     

Inactivation of porcine kidney betaine aldehyde dehydrogenase by hydrogen peroxide

Concentrated urine formation in the kidney is accompanied by conditions that favor the accumulation of reactive oxygen species (ROS). Under hyperosmotic conditions, medulla cells accumulate glycine betaine, which is an osmolyte synthesized by betaine aldehyde dehydrogenase (BADH, EC 1.2.1.8). All BADHs identified to date have a highly reactive cysteine residue at the active site, and this cysteine is susceptible to oxidation by hydrogen peroxide. Porcine kidney BADH incubated with H(2)O(2) (0-500 μM) lost 25% of its activity. However, pkBADH inactivation by hydrogen peroxide was limited, even after 120 min of incubation. The presence of coenzyme NAD(+) (10-50 μM) increased the extent of inactivation (60%) at 120 min of reaction, but the ligands betaine aldehyde (50 and 500 μM) and glycine betaine (100 mM) did not change the rate or extent of inactivation as compared to the reaction without ligand. 2-Mercaptoethanol and dithiothreitol, but not reduced glutathione, were able to restore enzyme activity. Mass spectrometry analysis of hydrogen peroxide inactivated BADH revealed oxidation of M278, M243, M241 and H335 in the absence and oxidation of M94, M327 and M278 in the presence of NAD(+). Molecular modeling of BADH revealed that the oxidized methionine and histidine residues are near the NAD(+) binding site. In the presence of the coenzyme, these oxidized residues are proximal to the betaine aldehyde binding site. None of the oxidized amino acid residues participates directly in catalysis. We suggest that pkBADH inactivation by hydrogen peroxide occurs via disulfide bond formation between vicinal catalytic cysteines (C288 and C289).     

Regulation of plant cytosolic glyceraldehyde 3-phosphate dehydrogenase isoforms by thiol modifications

Cytosolic NAD-dependent glyceraldehyde 3-P dehydrogenase (GAPDH; GapC; EC 1.2.1.12) catalyzes the oxidation of triose phosphates during glycolysis in all organisms, but additional functions of the protein has been put forward. Because of its reactive cysteine residue in the active site, it is susceptible to protein modification and oxidation. The addition of GSSG, and much more efficiently of S-nitrosoglutathione, was shown to inactivate the enzymes from Arabidopsis thaliana (isoforms GapC1 and 2), spinach, yeast and rabbit muscle. Inactivation was fully or at least partially reversible upon addition of DTT. The incorporation of glutathione upon formation of a mixed disulfide could be shown using biotinylated glutathione ethyl ester. Furthermore, using the biotin-switch assay, nitrosylated thiol groups could be shown to occur after treatment with nitric oxide donors. Using mass spectrometry and mutant proteins with one cysteine lacking, both cysteines (Cys-155 and Cys-159) were found to occur as glutathionylated and as nitrosylated forms. In preliminary experiments, it was shown that both GapC1 and GapC2 can bind to a partial gene sequence of the NADP-dependent malate dehydrogenase (EC 1.2.1.37; At5g58330). Transiently expressed GapC-green fluorescent protein fusion proteins were localized to the nucleus in A. thaliana protoplasts. As nuclear localization and DNA binding of GAPDH had been shown in numerous systems to occur upon stress, we assume that such mechanism might be part of the signaling pathway to induce increased malate-valve capacity and possibly other protective systems upon overreduction and initial formation of reactive oxygen and nitrogen species as well as to decrease and protect metabolism at the same time by modification of essential cysteine residues.