Identification of ADP-ribosylation site in human glutamate dehydrogenase isozymes

When the influence of ADP-ribosylation on the activities of the purified human glutamate dehydrogenase isozymes (hGDH1 and hGDH2) was measured in the presence of 100 microM NAD+ for 60 min, hGDH isozymes were inhibited by up to 75%. If incubations were performed for longer time periods up to 3 h, the inhibition of hGDH isozymes did not increased further. This phenomenon may be related to the reversibility of ADP-ribosylation in mitochondria. ADP-ribosylated hDGH isozymes were reactivated by Mg2+-dependent mitochondrial ADP-ribosylcysteine hydrolase. The stoichiometry between incorporated ADP-ribose and GDH subunits shows a modification of one subunit per catalytically active homohexamer. Since ADP and GTP had no effects on the extent of modification, it would appear that the ADP-ribosylation is unlikely to occur in allosteric sites. It has been proposed that Cys residue may be involved in the ADP-ribosylation of GDH, although identification of the reactive Cys residue has not been reported. To identify the reactive Cys residue involved in the ADP-ribosylation, we performed cassette mutagenesis at three different positions (Cys59, Cys119, and Cys274) using synthetic genes of hGDH isozymes. Among the Cys residues tested, only Cys119 mutants showed a significant reduction in the ADP-ribosylation. These results suggest a possibility that the Cys119 residue has an important role in the regulation of hGDH isozymes by ADP-ribosylation.     

Amino acid changes within antenna helix are responsible for different regulatory preferences of human glutamate dehydrogenase isozymes

Human glutamate dehydrogenase (hGDH) exists in hGDH1 (housekeeping isozyme) and in hGDH2 (nerve-specific isozyme), which differ markedly in their allosteric regulation. Because they differ in only 16 of their 505 amino acids, the regulatory preferences must arise from amino acid residues that are not common between hGDH1 and hGDH2. To our knowledge none of the mutagenesis studies on the hGDH isozymes to date have identified the amino acid residues fully responsible for the different regulatory preferences between hGDH1 and hGDH2. In this study we constructed hGDH1(hGDH2(390-448))hGDH1 (amino acid segment 390-448 of hGDH1 replaced by the corresponding hGDH2 segment) and hGDH2(hGDH1(390-448))hGDH2 (amino acid segment 390-448 of hGDH2 replaced by the corresponding hGDH1 segment) by swapping the corresponding amino acid segments in hGDH1 and hGDH2. The chimeric enzymes by reciprocal swapping resulted in double mutations in amino acid sequences at 415 and 443 residues that are not common between hGDH1 and hGDH2 and are located in the C-terminal 48-residue "antenna" helix, which is thought to be part of the regulatory domain of mammalian GDHs. Functional analyses revealed that the doubly mutated chimeric enzymes almost completely acquired most of the different regulatory preferences between hGDH1 and hGDH2 for electrophoretic mobility, heat-stability, ADP activation, palmitoyl-CoA inhibition, and l-leucine activation, except for GTP inhibition. Our results indicate that substitutions of the residues in the antenna region may be important evolutionary changes that led to the adaptation of hGDH2 to the unique metabolic needs of the nerve tissue.     

Reactive amino acid residues involved in glutamate-binding of human glutamate dehydrogenase isozymes

In the present study, the cassette mutagenesis at several putative positions (K94, G96, K118, K130, or D172) was performed to examine the residues involved in the glutamate-binding of the human glutamate dehydrogenase isozymes (hGDH1 and hGDH2). None of the mutations tested affected the expression or stability of the proteins. There was dramatic reduction in the catalytic efficiency in mutant proteins at K94, G96, K118, or K130 site, but not at D172 site. The K(M) values for glutamate were 4-10-fold greater for the mutants at K94, G96, or K118 site than for the wild-type hGDH1 and hGDH2, whereas no differences in the K(M) values for NAD(+) were detected between the mutant and wild-type enzymes. For K130Y mutant, the K(M) value for glutamate increased 1.6-fold, whereas the catalytic efficiency (k(cat)/K(M)) showed only 2-3% of the wild-type. Therefore, the decreased catalytic efficiency of the K130 mutant mainly results from the reduced k(cat) value, suggesting a possibility that the K130Y residue may be involved in the catalysis rather than in the glutamate-binding. The D172Y mutant did not show any changes in k(cat) value and K(M) values for glutamate and NAD(+), indicating that D172Y is not directly involved in catalysis and substrates binding of the hGDH isozymes. For sensitivity to ADP activation, only the D172Y mutant showed a reduced sensitivity to ADP activation. The reduction of ADP activation in D172Y mutant was more profoundly observed in hGDH2 than in hGDH1. There were no differences in their sensitivities to GTP inhibition between the wild-type and mutant GDHs at all positions tested. Our results suggest that K94, G96, and K118 residues play an important role, although at different degrees, in the binding of glutamate to hGDH isozymes.     

Important role of Ser443 in different thermal stability of human glutamate dehydrogenase isozymes

Molecular biological studies confirmed that two glutamate dehydrogenase isozymes (hGDH1 and hGDH2) of distinct genetic origin are expressed in human tissues. hGDH1 is heat-stable and expressed widely, whereas hGDH2 is heat-labile and specific for neural and testicular tissues. A selective deficiency of hGDH2 has been reported in patients with spinocerebellar ataxia. We have identified an amino acid residue involved in the different thermal stability of human GDH isozymes. At 45 degrees C (pH 7.0), heat inactivation proceeded faster for hGDH2 (half life=45 min) than for hGDH1 (half-life=310 min) in the absence of allosteric regulators. Both hGDH1 and hGDH2, however, showed much slower heat inactivation processes in the presence of 1 mM ADP or 3 mM L-Leu. Virtually most of the enzyme activity remained up to 100 min at 45 degrees C after treatment with ADP and L-Leu in combination. In contrast to ADP and L-Leu, the thermal stabilities of the hGDH isozymes were not affected by addition of substrates or coenzymes. In human GDH isozymes, the 443 site is Arg in hGDH1 and Ser in hGDH2. Replacement of Ser by Arg at the 443 site by cassette mutagenesis abolished the heat lability of hGDH2 with a similar half-life of hGDH1. The mutagenesis at several other sites (L415M, A456G, and H470R) having differences in amino acid sequence between the two GDH isozymes did not show any change in the thermal stability. These results suggest that the Ser443 residue plays an important role in the different thermal stability of human GDH isozymes.     

The role of beta93 Cys in the inhibition of Hb S fiber formation

Recent studies have suggested that nitric oxide (NO) binding to hemoglobin (Hb) may lead to the inhibition of sickle cell fiber formation and the dissolution of sickle cell fibers. NO can react with Hb in at least 3 ways: 1) formation of Hb(II)NO, 2) formation of methemoglobin, and 3) formation of S-nitrosohemoglobin, through nitrosylation of the beta93 Cys residue. In this study, the role of beta93 Cys in the mechanism of sickle cell fiber inhibition is investigated through chemical modification with N-ethylmaleimide. UV resonance Raman, FT-IR and electrospray ionization mass spectroscopic methods in conjunction with equilibrium solubility and kinetic studies are used to characterize the effect of beta93 Cys modification on Hb S fiber formation. Both FT-IR spectroscopy and electrospray mass spectrometry results demonstrate that modification can occur at both the beta93 and alpha104 Cys residues under relatively mild reaction conditions. Equilibrium solubility measurements reveal that singly-modified Hb at the beta93 position leads to increased amounts of fiber formation relative to unmodified or doubly-modified Hb S. Kinetic studies confirm that modification of only the beta93 residue leads to a faster onset of polymerization. UV resonance Raman results indicate that modification of the alpha104 residue in addition to the beta93 residue significantly perturbs the alpha(1)beta(2) interface, while modification of only beta93 does not. These results in conjunction with the equilibrium solubility and kinetic measurements are suggestive that modification of the alpha104 Cys residue and not the beta93 Cys residue leads to T-state destabilization and inhibition of fiber formation. These findings have implications for understanding the mechanism of NO binding to Hb and NO inhibition of Hb S fiber formation.     

Mechanism of the interaction between the intrinsically disordered C-terminus of the pro-apoptotic ARTS protein and the Bir3 domain of XIAP

ARTS (Sept4_i2) is a mitochondrial pro-apoptotic protein that functions as a tumor suppressor. Its expression is significantly reduced in leukemia and lymphoma patients. ARTS binds and inhibits XIAP (X-linked Inhibitor of Apoptosis protein) by interacting with its Bir3 domain. ARTS promotes degradation of XIAP through the proteasome pathway. By doing so, ARTS removes XIAP inhibition of caspases and enables apoptosis to proceed. ARTS contains 27 unique residues in its C-terminal domain (CTD, residues 248-274) which are important for XIAP binding. Here we characterized the molecular details of this interaction. Biophysical and computational methods were used to show that the ARTS CTD is intrinsically disordered under physiological conditions. Direct binding of ARTS CTD to Bir3 was demonstrated using NMR and fluorescence spectroscopy. The Bir3 interacting region in ARTS CTD was mapped to ARTS residues 266-274, which are the nine C-terminal residues in the protein. Alanine scan of ARTS 266-274 showed the importance of several residues for Bir3 binding, with His268 and Cys273 contributing the most. Adding a reducing agent prevented binding to Bir3. A dimer of ARTS 266-274 formed by oxidation of the Cys residues into a disulfide bond bound with similar affinity and was probably required for the interaction with Bir3. The detailed analysis of the ARTS - Bir3 interaction provides the basis for setting it as a target for anti cancer drug design: It will enable the development of compounds that mimic ARTS CTD, remove IAPs inhibition of caspases, and thereby induce apoptosis.     

Identification of amino acid residues responsible for different GTP preferences of human glutamate dehydrogenase isozymes

Human glutamate dehydrogenase isozymes (hGDH1 and hGDH2) differ markedly in their inhibition by GTP. These regulatory preferences must arise from amino acid residues that are not common between hGDH isozymes. We have constructed chimeric enzymes by reciprocally switching the corresponding amino acid segments 390-465 in hGDH isozymes that are located within or near the C-terminal 48-residue antenna helix, which is thought to be part of the regulatory domain of mammalian GDHs. These resulted in triple mutations in amino acid sequences at 415, 443, and 456 sites that are not common between hGDH1 and hGDH2. The chimeric enzymes did not change their enzyme efficiency (k_cat/K_m) and expression level. Functional analyses, however, revealed that the chimeric mutants almost completely acquired the different GTP regulatory preference between hGDH isozymes. These results suggest that the 415, 443, and 456 residues acting in concert are responsible for the GTP inhibitory properties of hGDH isozymes.     

Mapping the agonist binding site of the nicotinic acetylcholine receptor. Orientation requirements for activation by covalent agonist

To characterize the structural requirements for ligand orientation compatible with activation of the Torpedo nicotinic acetylcholine receptor (nAChR), we used Cys mutagenesis in conjunction with sulfhydryl-reactive reagents to tether primary or quaternary amines at defined positions within the agonist binding site of nAChRs containing mutant alpha- or gamma-subunits expressed in Xenopus oocytes. 4-(N-Maleimido)benzyltrimethylammonium and 2-aminoethylmethanethiosulfonate acted as irreversible antagonists when tethered at alphaY93C, alphaY198C, or gammaE57C, as well as at alphaN94C (2-aminoethylmethanethiosulfonate only). [2-(Trimethylammonium)-ethyl]-methanethiosulfonate (MTSET), which attaches thiocholine to binding site Cys, also acted as an irreversible antagonist when tethered at alphaY93C, alphaN94C, or gammaE57C. However, MTSET modification of alphaY198C resulted in prolonged activation of the nAChR not reversible by washing but inhibitable by subsequent exposure to non-competitive antagonists. Modification of alphaY198C (or any of the other positions tested) by [(trimethylammonium)methyl]methanethiosulfonate resulted only in irreversible inhibition, while modification of alphaY198C by [3-(trimethylammonium)propyl]methanethiosulfonate resulted in irreversible activation of nAChR, but at lower efficacy than by MTSET. Thus changing the length of the tethering arm by less than 1 A in either direction markedly effects the ability of the covalent trimethylammonium to activate the nAChR, and agonist activation depends on a very selective orientation of the quaternary ammonium within the agonist binding site.     

Critical role of the cysteine 323 residue in the catalytic activity of human glutamate dehydrogenase isozymes

The role of residue C323 in catalysis by human glutamate dehydrogenase isozymes (hGDH1 and hGDH2) was examined by substituting Arg, Gly, Leu, Met, or Tyr at C323 by cassette mutagenesis using synthetic human GDH isozyme genes. As a result, the Km of the enzyme for NADH and alpha-ketoglutarate increased up to 1.6-fold and 1.1-fold, respectively. It seems likely that C323 is not responsible for substrate-binding or coenzyme-binding. The efficiency (kcat/Km) of the mutant enzymes was only 11-14% of that of the wild-type isozymes, mainly due to a decrease in kcat values. There was a linear relationship between incorporation of [14C]p-chloromercuribenzoic acid and loss of enzyme activity that extrapolated to a stoichiometry of one mol of [14C] incorporated per mol of monomer for wild type hGDHs. No incorporation of [14C]p-chloromer-curibenzoic acid was observed with the C323 mutants. ADP and GTP had no effect on the binding of p-chloromercuribenzoic acid, suggesting that C323 is not directly involved in allosteric regulation. There were no differences between the two hGDH isozymes in sensitivities to mutagenesis at C323. Our results suggest that C323 plays an important role in catalysis by human GDH isozymes.     

The role of transmembrane segment TM3 in the xanthine permease XanQ of Escherichia coli

The xanthine permease XanQ of Escherichia coli is used as a study prototype for function-structure analysis of the ubiquitous nucleobase-ascorbate transporter (NAT/NCS2) family. Our previous mutagenesis study of polar residues of XanQ has shown that Asn-93 at the middle of putative TM3 is a determinant of substrate affinity and specificity. To study the role of TM3 in detail we employed Cys-scanning mutagenesis. Using a functional mutant devoid of Cys residues (C-less), each amino acid residue in sequence 79-107 (YGIVGSGLLSIQSVNFSFVTVMIALGSSM) including TM3 (underlined) and flanking sequences was replaced individually with Cys. Of 29 single-Cys mutants, 20 accumulate xanthine to 40-110% of the steady state observed with C-less, six (S88C, F94C, A102C, G104C, S106C) accumulate to low levels (10-30%) and three (G83C, G85C, N93C) are inactive. Extensive mutagenesis reveals that Gly-83 and, to a lesser extent, Gly-85, are crucial for expression in the membrane. Replacements of Asn-93 disrupt affinity (Thr) or permit recognition of 8-methylxanthine which is not a wild-type ligand (Ala, Ser, Asp) and utilization of uric acid which is not a wild-type substrate (Ala, Ser). Replacements of Phe-94 impair affinity for 2-thio and 6-thioxanthine (Tyr) or 3-methylxanthine (Ile). Single-Cys mutants S84C, L86C, L87C, and S95C are highly sensitive to inactivation by N-ethylmaleimide. Our data reveal that key residues of TM3 cluster in two conserved sequence motifs, (83)GSGLL(87) and (93)NFS(95), and highlight the importance of Asn-93 and Phe-94 in substrate recognition and specificity; these findings are supported by structural modeling on the recently described x-ray structure of the uracil-transporting homolog UraA.     

Serotonin and cocaine-sensitive inactivation of human serotonin transporters by methanethiosulfonates targeted to transmembrane domain I

To explore aqueous accessibility and functional contributions of transmembrane domain (TM) 1 in human serotonin transporter (hSERT) proteins, we utilized the largely methanethiosulfonate (MTS) insensitive hSERT C109A mutant and mutated individual residues of hSERT TM1 to Cys followed by tests of MTS inactivation of 5-hydroxytryptamine (5-HT) transport. Residues in TM1 cytoplasmic to Gly-94 were largely unaffected by Cys substitution, whereas the mutation of residues extracellular to Ile-93 variably diminished transport activity. TM1 Cys substitutions displayed differential sensitivity to MTS reagents, with residues more cytoplasmic to Asp-98 being largely insensitive to MTS inactivation. Aminoethylmethanethiosulfonate (MTSEA), [2-(trimethylammonium) ethyl]methanethiosulfonate bromide (MTSET), and sodium (2-sulfonatoethyl)-methanethiosulfonate (MTSES) similarly and profoundly inactivated 5-HT transport by SERT mutants D98C, G100C, W103C, and Y107C. MTSEA uniquely inactivated transport activity of S91C, G94C, Y95C but increased activity at I108C. MTSEA and MTSET, but not MTSES, inactivated transport function at N101C. Notably, 5-HT provided partial to complete protection from MTSET inactivation for D98C, G100C, N101C, and Y107C. Equivalent blockade of MTSET inactivation at N101C was observed with 5-HT at both room temperature and at 4 degrees C, inconsistent with major conformational changes leading to protection. Notably, cocaine also protected MTSET inactivation of G100C and N101C, although MTS incubations with N101C that eliminate 5-HT transport do not preclude cocaine analog binding nor its inhibition by 5-HT. 5-HT modestly enhanced the inactivation by MTSET at I93C and Y95C, whereas cocaine significantly enhanced MTSET sensitivity at Y107C and I108C. In summary, our studies reveal physical differences in TM1 accessibility to externally applied MTS reagents and reveal sites supporting substrate and antagonist modulation of MTS inactivation. Moreover, we identify a limit to accessibility for membrane-impermeant MTS reagents that may reflect aspects of an occluded permeation pathway.     

Identification and characterization of a critical region in the glycogen synthase from Escherichia coli

The cysteine-specific reagent 5,5'-dithiobis(2-nitrobenzoic acid) inactivates the Escherichia coli glycogen synthase (Holmes, E., and Preiss, J. (1982) Arch. Biochem. Biophys. 216, 736-740). To find the responsible residue, all cysteines, Cys(7), Cys(379), and Cys(408), were substituted combinatorially by Ser. 5,5'-Dithiobis(2-nitrobenzoic acid) modified and inactivated the enzyme if and only if Cys(379) was present and it was prevented by the substrate ADP-glucose (ADP-Glc). Mutations C379S and C379A increased the S(0.5) for ADP-Glc 40- and 77-fold, whereas the specific activity was decreased 5.8- and 4.3-fold, respectively. Studies of inhibition by glucose 1-phosphate and AMP indicated that Cys(379) was involved in the interaction of the enzyme with the phosphoglucose moiety of ADP-Glc. Other mutations, C379T, C379D, and C379L, indicated that this site is intolerant for bulkier side chains. Because Cys(379) is in a conserved region, other residues were scanned by mutagenesis. Replacement of Glu(377) by Ala and Gln decreased V(max) more than 10,000-fold without affecting the apparent affinity for ADP-Glc and glycogen binding. Mutation of Glu(377) by Asp decreased V(max) only 57-fold indicating that the negative charge of Glu(377) is essential for catalysis. The activity of the mutation E377C, on an enzyme form without other Cys, was chemically restored by carboxymethylation. Other conserved residues in the region, Ser(374) and Gln(383), were analyzed by mutagenesis but found not essential. Comparison with the crystal structure of other glycosyltransferases suggests that this conserved region is a loop that is part of the active site. The results of this work indicate that this region is critical for catalysis and substrate binding.     

A second disulfide bridge from the N-terminal domain to extracellular loop 2 dampens receptor activity in GPR39

A highly conserved feature across all families of 7TM receptors is a disulfide bridge between a Cys residue located at the extracellular end of transmembrane segment III (TM-III) and one in extracellular loop 2 (ECL-2). The zinc sensor GPR39 contains four Cys residues in the extracellular domains. By using mutagenesis, treatment with the reducing agent TCEP, and a labeling procedure for free sulfhydryl groups, we identify the pairing of these Cys residues in two disulfide bridges: the prototypical bridge between Cys (108) in TM-III and Cys (210) in ECL-2 and a second disulfide bridge connecting Cys (11) in the N-terminal domain with Cys (191) in ECL-2. Disruption of the conserved disulfide bond by mutagenesis greatly reduced the level of cell surface expression and eliminated agonist-induced increases in inositol phosphate production but surprisingly enhanced constitutive signaling. Disruption of the nonconserved disulfide bridge by mutagenesis led to an increase in the Zn (2+) potency. This phenotype, with an approximate 10-fold increase in agonist potency and a slight increase in E max, was mimicked by treatment of the wild-type receptor with TCEP at low concentrations, which had no effect on the receptor already lacking the second disulfide bridge and already displaying a high Zn (2+) potency. We conclude that the second disulfide bridge, which according to the beta2-adrenergic structure will form a covalent link across the entrance to the main ligand binding pocket, serves to dampen GPR39 activation. We suggest that formation of extra disulfide bridges may be an important general mechanism for regulating the activity of 7TM receptors.     

Mapping the substrate binding site of the prostaglandin transporter PGT by cysteine scanning mutagenesis.

We have identified a cDNA, PGT, that encodes a widely expressed transporter for prostaglandin (PG) E(2), PGF(2alpha), PGD(2), 8-iso-PGF(2alpha), and thromboxane B(2). To begin to understand the molecular mechanisms of transporter function, we have initiated a structure-function analysis of PGT to identify its substrate-binding region. We have found that by introducing the small, water-soluble, thiol-reactive anion Na(2-sulfonatoethyl)methanethiosulfonate (MTSES) into the substrate pathway, we were able to cause inhibition of transport that could be reversed with dithiothreitol. Importantly, co-incubation with PGE(2) protected PGT from this inhibition, suggesting that MTSES gains access to the aqueous pore pathway of PGT to form a mixed disulfide near the substrate-binding site. To identify the susceptible cysteine, we mutated, one at a time, all six of the putative transmembrane cysteines to serine. Only the mutation of Cys-530 to serine within putative transmembrane 10 became resistant to inhibition by MTSES. Thus, Cys-530 is the substrate-protectable, MTSES-inhibitable residue. To identify other residues that may be lining the substrate-binding site, we initiated cysteine-scanning mutagenesis of transmembrane 10 using Cys-530 as an entry point. On a C530S, MTSES-resistant background, residues in the N- and C-terminal directions were individually mutated to cysteine (Ala-513 to His-536), one at a time, and then analyzed for MTSES inhibition. Of the 24 cysteine-substituted mutants generated, 6 were MTSES-sensitive and, among these, 4 were substrate-protectable. The pattern of sensitivity to MTSES places these residues on the same face of an alpha-helix. The results of cysteine-scanning mutagenesis and molecular modeling of putative transmembrane 10 indicate that the substrate binding of PGT is formed among its membrane-spanning segments, with 4 residues along the cytoplasmic end of helix 10 contributing to one surface of the binding site.     

Introduction of a lethal redox switch that controls the opening and closing of the hydrophobic cavity in LolA

LolA plays a critical role in the outer membrane sorting of Escherichia coli lipoproteins because it carries a hydrophobic lipoprotein from the inner membrane through the hydrophilic periplasm to the outer membrane receptor LolB. LolA has an incomplete beta-barrel structure composed of 11 beta-strands with an alpha-helical lid forming a hydrophobic cavity inside. The accompanying study revealed that the hydrophobic cavity opens and closes upon the binding and release of lipoproteins, respectively. Ile(93) in the alpha-helix and Phe(140) in the beta-strand are located close to each other in the hydrophobic cavity. These two residues were replaced by Cys to construct the I93C/F140C derivative. Expression of I93C/F140C immediately arrested growth whether wild-type LolA was present or not. However, this dominant negative phenotype was abolished by reducing agents, indicating that the intramolecular disulfide bonding between the two Cys residues is lethal. I93C/F140C was unstable, and its periplasmic level was lower than that of wild-type LolA or its single Cys derivative. Reduction of I93C/F140C was essential for the release of lipoproteins from the inner membrane. Moreover, treatment of I93C/F140C with divalent cross-linkers having different side chain lengths revealed that opening of the lid for a sufficient distance is required for the release activity. The binding of a fluorescent probe to the hydrophobic cavity of I93C/F140C also depended on reducing agents. Taken together, these results indicate that the two Cys residues introduced into LolA function as a redox switch, which regulates the opening and closing of the hydrophobic cavity.     

Mapping the zinc ligands of S100A2 by site-directed mutagenesis

S100 family proteins are characterized by short individual N and C termini and a conserved central part, harboring two Ca(2+)-binding EF-hands, one of them highly conserved among EF-hand family proteins and the other characteristic for S100 proteins. In addition to Ca(2+), several members of the S100 protein family, including S100A2, bind Zn(2+). Two regions in the amino acid sequences of S100 proteins, namely the helices of the N-terminal EF-hand motif and the very C-terminal loop are believed to be involved in Zn(2+)-binding due to the presence of histidine and/or cysteine residues. Human S100A2 contains four cysteine residues, each of them located at positions that may be important for Zn(2+) binding. We have now constructed and purified 10 cysteine-deficient mutants of human S100A2 by site-directed mutagenesis and investigated the contribution of the individual cysteine residues to Zn(2+) binding. Here we show that Cys(1(3)) (the number in parentheses indicating the position in the sequence of S100A2) is the crucial determinant for Zn(2+) binding in association with conformational changes as determined by internal tyrosine fluorescence. Solid phase Zn(2+) binding assays also revealed that the C-terminal residues Cys(3(87)) and Cys(4(94)) mediated a second type of Zn(2+) binding, not associated with detectable conformational changes in the molecule. Cys(2(22)), by contrast, which is located within the first EF hand motif affected neither Ca(2+) nor Zn(2+) binding, and a Cys "null" mutant was entirely incapable of ligating Zn(2+). These results provide new information about the mechanism and the site(s) of zinc binding in S100A2.     

The mycobacterial thioredoxin peroxidase can act as a one-cysteine peroxiredoxin

Thioredoxin peroxidase (TPx) has been reported to dominate the defense against H(2)O(2), other hydroperoxides, and peroxynitrite at the expense of thioredoxin (Trx) B and C in Mycobacterium tuberculosis (Mt). By homology, the enzyme has been classified as an atypical 2-C-peroxiredoxin (Prx), with Cys(60) as the "peroxidatic" cysteine (C(P)) forming a complex catalytic center with Cys(93) as the "resolving" cysteine (C(R)). Site-directed mutagenesis confirms Cys(60) to be C(P) and Cys(80) to be catalytically irrelevant. Replacing Cys(93) with serine leads to fast inactivation as seen by conventional activity determination, which is associated with oxidation of Cys(60) to a sulfinic acid derivative. However, in comparative stopped-flow analysis, WT-MtTPx and MtTPx C93S reduce peroxynitrite and react with TrxB and -C similarly fast. Reduction of pre-oxidized WT-MtTPx and MtTPx C93S by MtTrxB is demonstrated by monitoring the redox-dependent tryptophan fluorescence of MtTrxB. Furthermore, MtTPx C93S remains stable for 10 min at a morpholinosydnonimine hydrochloride-generated low flux of peroxynitrite and excess MtTrxB in a dihydrorhodamine oxidation model. Liquid chromatography-tandem mass spectrometry analysis revealed disulfide bridges between Cys(60) and Cys(93) and between Cys(60) and Cys(80) in oxidized WT-MtTPx. Reaction of pre-oxidized WT-MtTPx and MtTPx C93S with MtTrxB C34S or MtTrxC C40S yielded dead-end intermediates in which the Trx mutants are preferentially linked via disulfide bonds to Cys(60) and never to Cys(93) of the TPx. It is concluded that neither Cys(80) nor Cys(93) is required for the catalytic cycle of the peroxidase. Instead, MtTPx can react as a 1-C-Prx with Cys(60) being the site of attack for both the oxidizing and the reducing substrate. The role of Cys(93) is likely to conserve the oxidation equivalents of the sulfenic acid state of C(P) as a disulfide bond to prevent overoxidation of Cys(60) under a restricted supply of reducing substrate.     

Identification of a lactoferrin-derived peptide possessing binding activity to hepatitis C virus E2 envelope protein

Bovine and human lactoferrins (LF) prevent hepatitis C virus (HCV) infection in cultured human hepatocytes; the preventive mechanism is thought to be the direct interaction between LF and HCV. To clarify this hypothesis, we have characterized the binding activity of LF to HCV E2 envelope protein and have endeavored to determine which region(s) of LF are important for this binding activity. Several regions of human LF have been expressed and purified as thioredoxin-fused proteins in Escherichia coli. Far-Western blot analysis using these LF fragments and the E2 protein, expressed in Chinese hamster ovary cells, revealed that the 93 carboxyl amino acids of LF specifically bound to the E2 protein. The 93 carboxyl amino acids of LFs derived from bovine and horse cells also possessed similar binding activity to the E2 protein. In addition, the amino acid sequences of these carboxyl regions appeared to show partial homology to CD81, a candidate receptor for HCV, and the binding activity of these carboxyl regions was also comparable with that of CD81. Further deletion analysis identified 33 amino acid residues as the minimum binding site in the carboxyl region of LF, and the binding specificity of these 33 amino acids was also confirmed by using 33 maltose-binding protein-fused amino acids. Furthermore, we demonstrated that the 33 maltose-binding protein-fused amino acids prevented HCV infection in cultured human hepatocytes. In addition, the site-directed mutagenesis to an Ala residue in both terminal residues of the 33 amino acids revealed that Cys at amino acid 628 was determined to be critical for binding to the E2 protein. These results led us to consider the development of an effective anti-HCV peptide. This is the first identification of a natural protein-derived peptide that specifically binds to HCV E2 protein and prevents HCV infection.     

Reaction of oxidized dopamine with endogenous cysteine residues in the human dopamine transporter

There is evidence to suggest that dopamine (DA) oxidizes to form dopamine ortho-quinone (DAQ), which binds covalently to nucleophilic sulfhydryl groups on protein cysteinyl residues. This reaction has been shown to inhibit dopamine uptake, as well as other biological processes. We have identified specific cysteine residues in the human dopamine transporter (hDAT) that are modified by this electron-deficient substrate analog. DAQ reactivity was inferred from its effects on the binding of [(3)H]2-beta-carbomethoxy-3-beta-(4-fluorophenyl)tropane (beta-CFT) to hDAT cysteine mutant constructs. One construct, X5C, had four cysteines mutated to alanine and one to phenylalanine (Cys(90)A, Cys(135)A, C306A, C319F and Cys(342)A). In membrane preparations 1 mM DAQ did not affect [(3)H]beta-CFT binding to X5C hDAT, in contrast to its effect in wild-type hDAT in which it reduced the B:(max) value by more than half. Wild-type cysteines were substituted back into X5C, one at a time, and the ability of DAQ to inhibit [(3)H]beta-CFT binding was assessed. Reactivity of DAQ with Cys(90) increased the affinity of [(3)H]beta-CFT for the transporter, whereas reactivity with Cys(135) decreased the affinity of [(3)H]beta-CFT. DAQ did not change the K:(D) for [(3)H]beta-CFT binding to wild-type. The reactivity of DAQ at Cys(342) decreased B:(max) to the same degree as wild-type. The latter result suggests that Cys(342) is the wild-type residue most responsible for DAQ-induced inhibition of [(3)H]beta-CFT binding.     

Ligand binding properties and structural studies of recombinant and chemically modified hemoglobins altered at beta 93 cysteine

To investigate the roles of beta93 cysteine in human normal adult hemoglobin (Hb A), we have constructed four recombinant mutant hemoglobins (rHbs), rHb (betaC93G), rHb (betaC93A), rHb (betaC93M), and rHb (betaC93L), and have prepared two chemically modified Hb As, Hb A-IAA and Hb A-NEM, in which the sulfhydryl group at beta93Cys is modified by sulfhydryl reagents, iodoacetamide (IAA) and N-ethylmaleimide (NEM), respectively. These variants at the beta93 position show higher oxygen affinity, lower cooperativity, and reduced Bohr effect relative to Hb A. The response of some of these Hb variants to allosteric effectors, 2,3-bisphosphoglycerate (2,3-BPG) and inositol hexaphosphate (IHP), is decreased relative to that of Hb A. The proton nuclear magnetic resonance (NMR) spectra of these Hb variants show that there is a marked influence on the proximal heme pocket of the beta-chain, whereas the environment of the proximal heme pocket of the alpha-chain remains unchanged as compared to Hb A, suggesting that higher oxygen affinity is likely to be determined by the heme pocket of the beta-chain rather than by that of the alpha-chain. This is further supported by NO titration of these Hbs in the deoxy form. For Hb A, NO binds preferentially to the heme of the alpha-chain relative to that of the beta-chain. In contrast, the feature of preferential binding to the heme of the alpha-chain becomes weaker and even disappears for Hb variants with modifications at beta93Cys. The effects of IHP on these Hbs in the NO form are different from those on HbNO A, as characterized by (1)H NMR spectra of the T-state markers, the exchangeable resonances at 14 and 11 ppm, reflecting that these Hb variants have more stability in the R-state relative to Hb A, especially rHb (betaC93L) and Hb A-NEM in the NO form. The changes of the C2 proton resonances of the surface histidyl residues in these Hb variants in both the deoxy and CO forms, compared with those of Hb A, indicate that a mutation or chemical modification at beta93Cys can result in conformational changes involving several surface histidyl residues, e.g., beta146His and beta2His. The results obtained here offer strong evidence to show that the salt bridge between beta146His and beta94Asp and the binding pocket of allosteric effectors can be affected as the result of modifications at beta93Cys, which result in the destabilization of the T-state and a reduced response of these Hbs to allosteric effectors. We further propose that the impaired alkaline Bohr effect can be attributed to the effect on the contributions of several surface histidyl residues which are altered because of the environmental changes caused by mutations and chemical modifications at beta93Cys.