Essential sulfhydryl groups in diamine oxidase from Euphorbia characias latex

Diamine oxidase from Euphorbia characias latex contains two sulfhydryl groups per mole of dimeric enzyme. The sulfhydryl groups are unreactive in the native enzyme but can be readily titrated by 4,4′-dithiodipyridine after protein denaturation, or anaerobically in the presence of the amine substrate. In the presence of both substrates (diamine and oxygen) they react sluggishly. The sulfhydryl groups show different reactivity toward various reagents, but in every case their modification inhibits catalytic activity. The insensitivity of the native enzyme to specific reagents suggests that the sulfhydryl groups are positioned in the interior of the protein and shielded from the solvent. Their reactivity in the presence of the amine substrate could be attributed to a conformational change occurring upon substrate binding or after substrate oxidation.     

Studies on regulatory functions of malic enzymes. VII. Structural and functional characteristics of sulfhydryl groups in NADP-linked malic enzyme from Escherichia coli W.

NADP-linked malic enzyme from Escherichia coli W contains 7 cysteinyl residues per enzyme subunit. The reactivity of sulfhydryl (SH) groups of the enzyme was examined using several SH reagents, including 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) and N-ethylmaleimide (NEM). 1. Two SH groups in the native enzyme subunit reacted with DTNB (or NEM) with different reaction rates, accompanied by a complete loss of the enzyme activity. The second-order modification rate constant of the "fast SH group" with DTNB coincided with the second-order inactivation rate constant of the enzyme by the reagent, suggesting that modification of the "fast SH group" is responsible for the inactivation. When the enzyme was denatured in 4 M guanidine HCl, all the SH groups reacted with the two reagents. 2. Althoug the inactivation rate constant was increased by the addition of Mg2+, an essential cofactor in the enzyme reaction, the modification rate constant of the "fast SH group" was unaffected. The relationship between the number of SH groups modified with DTNB or NEM and the residual enzyme activity in the absence of Mg2+ was linear, whereas that in the presence of Mg2+ was concave-upwards. These results suggest that the Mg2+-dependent increase in the inactivation rate constant is not the result of an increase in the rate constant of the "fast FH group" modification. 3. The absorption spectrum of the enzyme in the ultraviolet region was changed by addition of Mg2+. The dissociation constant of the Mg2+-enzyme complex obtained from the Mg2+- dependent increment of the difference absorption coincided with that obtained from the Mg2+- dependent enhancement of NEM inactivation. 4. Both the inactivation rate constant and the modification rate constant of the "fast SH group" were decreased by the addition of NADP+. The protective effect of NADP+ was increased by the addition of Mg2+. Based on the above results, the effects of Mg2+ on the SH-group modification are discussed from the viewpoint of conformational alteration of the enzyme.     

Modifications of cysteine residues in the solution and membrane-associated conformations of phosphatidylinositol transfer protein have differential effects on lipid transfer activity

The alpha isoforms of mammalian phosphatidylinositol transfer protein (PITP) contain four conserved Cys residues. In this investigation, a series of thiol-modifying reagents, both alkylating and mixed disulfide-forming, was employed to define the accessibility of these residues and to evaluate their role in protein-mediated intermembrane phospholipid transport. Isolation and analysis of chemically modified peptides and site-directed mutagenesis of each Cys residue to Ala were also performed. Soluble, membrane-associated, and denatured preparations of wild-type and mutant rat PITPs were studied. Under denaturing conditions, all four Cys residues could be detected spectrophotometrically by chemical reaction with 4,4'-dipyridyl disulfide or 5,5'-dithiobis(2-nitrobenzoate). In the native protein, two of the four Cys residues were sensitive to some but not all thiol-modifying reagents, with discrimination based on the charge and hydrophobicity of the reagent and the conformation of the protein. With the soluble conformation of PITP, achieved in the absence of phospholipid vesicles, the surface-exposed Cys(188) was chemically modified without consequence to lipid transfer activity. Cys(188) exhibited an apparent pK(a) of 7.6. The buried Cys(95), which constitutes part of the phospholipid substrate binding site, was covalently modified upon transient association of PITP with a membrane surface. The Cys-to-Ala mutations showed that neither Cys(95) nor Cys(188) was essential for lipid transfer activity. However, chemical modification of Cys(95) resulted in the loss of lipid transfer activity. These results demonstrate that the Cys residues of PITP can be assigned to several different classes of chemical reactivity. Of particular interest is Cys(95), whose sulfhydryl group becomes exposed to modification in the membrane-associated conformation of PITP. Furthermore, the inhibition of PITP activity by thiol-modifying reagents is a result of steric hindrance of phospholipid substrate binding.     

Stoichiometry of phenylhydrazine inactivation of pig plasma amine oxidase

Pig plasma amine oxidase is irreversibly inactivated by phenylhydrazine. The stoichiometry of this inactivation was determined by monitoring the loss of catalytic activity, the formation of a new visible spectral band, changes in the circular dichroic spectrum and by equilibrium binding studies. In all cases, only 1 mol of phenylhydrazine reacted with the dimeric pig plasma amine oxidase; further additions of phenylhydrazine had no effect. Pretreatment of the enzyme with phenylhydrazine inhibited the binding of amine substrate. The phenylhydrazine-enzyme complex was found to be stable under various experimental conditions for at least 72 h. Circular dichroic spectra revealed the conformation of the phenylhydrazine-treated enzyme to be altered in the region around prosthetic groups and indicated some changes about the aromatic amino acids. No major conformational changes were detected by this technique. Isoelectric focusing experiments exposed no differences in the band pattern or isoelectric point between the untreated and phenylhydrazine-treated enzymes.     

Probing the role of cysteine residues in the CheR methyltransferase

The CheR methyltransferase catalyzes the transfer of methyl groups from S-adenosylmethionine to specific glutamyl residues in bacterial chemoreceptor proteins. Studies with sulfhydryl reagents such as p-chloromercuribenzoate, N-ethylmaleimide, and 5,5'-dithiobis(2-nitrobenzoate) suggest that a cysteine residue is required for enzyme activity. The nucleotide sequence of the cheR gene predicts a 288-amino acid protein with cysteine residues at positions 31 and 229. To ascertain the role of these cysteine residues in the structure and function of the enzyme, oligonucleotide-directed mutagenesis was used to change each cysteine to serine. Whereas the Cys229-Ser mutation had essentially no effect on transferase activity, the Cys31-Ser mutation caused an 80% decrease in enzyme activity. The double mutant in which both cysteines were replaced by serines also had markedly reduced transferase activity. Preincubation of the wild type or Cys229-Ser proteins with either S-adenosylmethionine or beta-mercaptoethanol protected it from inhibition by sulfhydryl reagents, whereas prior incubation with the second substrate, the Tar receptor, gave partial protection. From these studies, Cys31 appears to be necessary for enzyme activity, and it seems to be located in the vicinity of the active site.     

Site-directed mutagenesis and chemical modification of the six native cysteine residues of the rat mitochondrial carnitine carrier: implications for the role of cysteine-136

By use of site-directed mutagenesis in combination with chemical modification of mutated proteins, the role of the six Cys residues in the transport function of the rat mitochondrial carnitine carrier (CAC) was studied. Several CAC mutants, in which one or more Cys residues had been replaced with Ser, were overexpressed in Escherichia coli, purified, and reconstituted in liposomes. The efficiency of incorporation into liposomes of the reconstituted proteins was lower for all constructs lacking Cys-23. Single, double, and quadruple replacement mutants showed V(max) comparable to that of the wild type. On the basis of the values of internal and external transport affinities (K(m)) for carnitine and of their comparison with those measured in mitochondria, the recombinant CAC is oriented unidirectionally in the liposomes, right side out compared to mitochondria. Substitution of Cys-136 with Ser caused a nearly complete loss of sensitivity of the CAC to N-ethylmaleimide, (2-aminoethyl)methanethiosulfonate hydrobromide (MTSES), and other hydrophilic SH reagents but not to the very hydrophobic N-phenylmaleimide. The wild-type CAC and the mutants containing Cys-136 showed substrate protection against NEM and MTSES inhibition and against NEM labeling. The data show that none of the native cysteines is essential for the transport mechanism and that Cys-136 is the major target of SH reagents and raise the hypothesis that Cys-136 is accessible from the external medium and is located at, or near, the substrate binding site. A model of the CAC is proposed in which the matrix hydrophilic loop containing Cys-136 protrudes into the membrane between the transmembrane domains of the protein.     

The reactivity of thiol groups and the subunit structure of aldolase

1. Seven unique carboxymethylcysteine-containing peptides have been isolated from tryptic digests of rabbit muscle aldolase carboxymethylated with iodo[2-(14)C]acetic acid in 8m-urea. These peptides have been characterized by amino acid and end-group analysis and their location within the cyanogen bromide cleavage fragments of the enzyme has been determined. 2. Reaction of native aldolase with 5,5'-dithiobis-(2-nitrobenzoic acid), iodoacetamide and N-ethylmaleimide showed that a total of three cysteine residues per subunit of mol.wt. 40000 were reactive towards these reagents, and that the modification of these residues was accompanied by loss in enzymic activity. Chemical analysis of the modified enzymes demonstrated that the same three thiol groups are involved in the reaction with all these reagents but that the observed reactivity of a given thiol group varies with the reagent used. 3. One reactive thiol group per subunit could be protected when the modification of the enzyme was carried out in the presence of substrate, fructose 1,6-diphosphate, under which conditions enzymic activity was retained. This thiol group has been identified chemically and is possibly at or near the active site. Limiting the exposure of the native enzyme to iodoacetamide also served to restrict alkylation to two thiol groups and left the enzymic activity unimpaired. The thiol group left unmodified is the same as that protected by substrate during more rigorous alkylation, although it is now more reactive towards 5,5'-dithiobis-(2-nitrobenzoic acid) than in the native enzyme. 4. Conversely, prolonged incubation of the enzyme with fructose 1,6-diphosphate, which was subsequently removed by dialysis, caused an irreversible fall in enzymic activity and in thiol group reactivity measured with 5,5'-dithiobis-(2-nitrobenzoic acid). 5. It is concluded that the aldolase tetramer contains at least 28 cysteine residues. Each subunit appears to be identical with respect to number, location and reactivity of thiol groups.     

Reactions of bovine serum amine oxidase with NN-diethyldithiocarbamate. Selective removal of one copper ion.

NN-Diethyldithiocarbamate (DDC) was able to bind, at 1.0 mM concentration, only about 50% the Cu(II) ions of bovine plasma amine oxidase. Under reducing conditions, this Cu(II) was removed with inactivation of the enzyme. Up to 90% activity could be recovered by treatment with excess Cu(II). The organic cofactor, sensitive to carbonyl reagents, was reduced in the half-Cu-depleted protein and no longer bound phenylhydrazine. The fully reacted protein, in the presence of 10 mM-DDC, lost 50% Cu(II) upon storage at -20 degrees C, but in this case the residual Cu(II) was in the DDC-bound form and the cofactor was in the oxidized state, as it could still bind phenylhydrazine. In the presence of DDC, the rate of reaction with phenylhydrazine was always low, even at 50% DDC saturation, and all derivatives showed identical modifications of the optical and e.p.r. spectra with respect to the phenylhydrazone of the native protein. It is concluded that the two Cu(II) ions are not equivalent, that removal of a single Cu(II) is sufficient to inhibit the re-oxidation of the organic cofactor, and that both Cu(II) ions are in some way involved in the reaction with phenylhydrazine. After reaction with DDC, the optical and e.p.r. spectra of 63Cu(II)-amine oxidase and of 63Cu(II)-carbonic anhydrase [Morpurgo, Desideri, Rigo, Viglino & Rotilio (1983) Biochim. Biophys. Acta 746, 168-175] are very similar and show distorted equatorial co-ordination to Cu(II) of two sulphur atoms and two magnetically equivalent nitrogen atoms.     

The role of Cys108 in Trigonopsis variabilisd-amino acid oxidase examined through chemical oxidation studies and point mutations C108S and C108D

Oxidative modification of Trigonopsis variabilisd-amino acid oxidase in vivo is traceable as the conversion of Cys108 into a stable cysteine sulfinic acid, causing substantial loss of activity and thermostability of the enzyme. To simulate native and modified oxidase each as a microheterogeneity-resistant entity, we replaced Cys108 individually by a serine (C108S) and an aspartate (C108D), and characterized the purified variants with regard to their biochemical and kinetic properties, thermostability, and reactivity towards oxidation by hypochlorite. Tandem MS analysis of tryptic peptides derived from a hypochlorite-treated inactive preparation of recombinant wild-type oxidase showed that Cys108 was converted into cysteine sulfonic acid, mimicking the oxidative modification of native enzyme as isolated. Colorimetric titration of protein thiol groups revealed that in the presence of ammonium benzoate (0.12 mM), the two muteins were not oxidized at cysteines whereas in the wild-type enzyme, one thiol group was derivatized. Each site-directed replacement caused a conformational change in d-amino acid oxidase, detected with an assortment of probes, and resulted in a turnover number for the O₂-dependent reaction with D-Met which in comparison with the corresponding wild-type value was decreased two- and threefold for C108S and C108D, respectively. Kinetic analysis of thermal denaturation at 50 °C was used to measure the relative contributions of partial unfolding and cofactor dissociation to the overall inactivation rate in each of the three enzymes. Unlike wild-type, C108S and C108D released the cofactor in a quasi-irreversible manner and were therefore not stabilized by external FAD against loss of activity. The results support a role of the anionic side chain of Cys108 in the fine-tuning of activity and stability of d-amino acid oxidase, explaining why C108S was a surprisingly poor mimic of the native enzyme.     

Catalysis by the isolated tryptophan tryptophylquinone-containing subunit of aromatic amine dehydrogenase is distinct from native enzyme and synthetic model compounds and allows further probing of TTQ mechanism

Para-substituted benzylamines are poor reactivity probes for structure-reactivity studies with TTQ-dependent aromatic amine dehydrogenase (AADH). In this study, we combine kinetic isotope effects (KIEs) with structure-reactivity studies to show that para-substituted benzylamines are good reactivity probes of TTQ mechanism with the isolated TTQ-containing subunit of AADH. Contrary to the TTQ-containing subunit of methylamine dehydrogenase (MADH), which is catalytically inactive, the small subunit of AADH catalyzes the oxidative deamination of a variety of amine substrates. Observed rate constants are second order with respect to substrate and inhibitor (phenylhydrazine) concentration. Kinetic studies with para-substituted benzylamines and their dideuterated counterparts reveal KIEs (>6) larger than those observed with native AADH (KIEs approximately unity). This is attributed to formation of the benzylamine-derived iminoquinone requiring structural rearrangement of the benzyl side chain in the active site of the native enzyme. This structural reorganization requires motions from the side chains of adjacent residues (which are absent in the isolated small subunit). The position of Phealpha97 in particular is responsible for the conformational gating (and hence deflated KIEs) observed with para-substituted benzylamines in the native enzyme. Hammett plots for the small subunit exhibit a strong correlation of structure-reactivity data with electronic substituent effects for para-substituted benzylamines and phenethylamines, unlike native AADH for which a poor correlation is observed. TTQ reduction in the isolated subunit is enhanced by electron withdrawing substituents, contrary to structure-reactivity studies reported for synthetic TTQ model compounds in which rate constants are enhanced by electron donating substituents. We infer that para-substituted benzylamines are good reactivity probes of TTQ mechanism with the isolated small subunit. This is attributed to the absence of structural rearrangement prior to H-transfer that limits the rate of TTQ reduction by para-substituted benzylamines in native enzyme.     

Mechanism of the conversion of xanthine dehydrogenase to xanthine oxidase: identification of the two cysteine disulfide bonds and crystal structure of a non-convertible rat liver xanthine dehydrogenase mutant

Mammalian xanthine dehydrogenase can be converted to xanthine oxidase by modification of cysteine residues or by proteolysis of the enzyme polypeptide chain. Here we present evidence that the Cys(535) and Cys(992) residues of rat liver enzyme are indeed involved in the rapid conversion from the dehydrogenase to the oxidase. The purified mutants C535A and/or C992R were significantly resistant to conversion by incubation with 4,4'-dithiodipyridine, whereas the recombinant wild-type enzyme converted readily to the oxidase type, indicating that these residues are responsible for the rapid conversion. The C535A/C992R mutant, however, converted very slowly during prolonged incubation with 4,4'-dithiodipyridine, and this slow conversion was blocked by the addition of NADH, suggesting that another cysteine couple located near the NAD(+) binding site is responsible for the slower conversion. On the other hand, the C535A/C992R/C1316S and C535A/C992R/C1324S mutants were completely resistant to conversion, even on prolonged incubation with 4,4'-dithiodipyridine, indicating that Cys(1316) and Cys(1324) are responsible for the slow conversion. The crystal structure of the C535A/C992R/C1324S mutant was determined in its demolybdo form, confirming its dehydrogenase conformation.     

Structural and functional roles of cysteine residues of Bacillus polymyxa beta-amylase.

Bacillus polymyxa beta-amylase contains three cysteine residues at positions 83, 91, and 323, which can react with sulfhydryl reagents. To determine the role of cysteine residues in the catalytic reaction, cysteine residues were mutated to construct four mutant enzymes, C83S, C91V, C323S, and C-free. Wild-type and mutant forms of the enzyme were expressed in, and purified to homogeneity from, Bacillus subtilis. A disulfide bond between Cys83 and Cys91 was identified by isolation of tryptic peptides bearing a fluorescent label, IAEDANS, from wild-type and C91 V enzymes followed by amino acid sequencing. Therefore, only Cys323 contains a free SH group. Replacement of cysteine residues with serine or valine residues resulted in a significant decrease in the kcat/Km value of the enzyme. C323S, containing no free SH group, however, retained a high specific activity, approximately 20% of the wild-type enzyme. None of the cysteine residues participate directly in the catalytic reaction.     

Stepwise modulation of ATPase activity, nucleotide trapping, and sliding motility of myosin S1 by modification of the thiol region with residues of increasing size

Rabbit muscle myosin S1 was modified either at SH1 alone or at both SH1 and SH2, using a series of alkylthiolating reagents of increasing size, designed for correlating gradually changing structural disturbances in the thiol region with functional impairments in the myosin head. The reagents were of the type H(CH(2))(n)()-S-NTB, (NTB = 2-nitro-5-thiobenzoate) (n = 1, 2, 5, 8, 9, 10, 11, and 12). Modification of only SH1 led to the expected activation of the Ca(2+)-ATPase, but only with small reagents, while reagents with n > or = 10 caused inhibition of the Ca(2+)-ATPase. Modification of both SH1 and SH2 showed the expected inhibition of Ca(2+)-ATPase but likewise allowed considerable residual Ca(2+)-ATPase activity if the residues were small. Trapping of the nucleotide, known to occur with cross-linking reagents, was seen also with monovalent reagents, provided their length exceeded n = 9 or 10. All S1 derivatives prepared in this study possessed an affinity for actin comparable to native S1 but lacked sliding motility in in vitro motility assays. The biochemical data of this study can be related to existing models of myosin S1 and recent structural data [Houdusse, A., Kalabokis, V. N., Himmel, D., Szent-Gy?rgyi, A. G., and Cohen, C. (1999) Cell 97, 459-470] by making the assumptions that modification at SH1 prevents the formation of the SH1 helix mandatory for the transmission of conformational energy and that mobility of the thiol region is a prerequisite for ATPase activity. Immobilization of the thiol region by residues of increasing size apparently leads to lower enzyme activity and, finally, to inhibition of nucleotide exchange.     

A conserved cysteine in molybdenum oxotransferases

The amino acid sequences of peptides derived from rat hepatic sulfite oxidase have been determined by a combination of amino acid analysis and Edman degradation of the purified protein. The data obtained showed the rat liver enzyme contained 3 cysteine residues which was confirmed by thiol modification studies using 4,4'-dithiodipyridine of the native enzyme. Combining these data with that previously published for chicken liver sulfite oxidase (Neame, P. J., and Barber, M. J. (1989) J. Biol. Chem. 264, 20894-20901) indicates that 2 cysteines (Cys186 and Cys430, based upon the numbering for the chicken sequence) are conserved in both chicken and rat liver enzymes with all the cysteine residues being present in the molybdenum-containing domain. Further comparison of the sequences of the molybdenum domains of rat and chicken liver sulfite oxidase with the amino acid sequences published for the molybdenum domains of a variety of assimilatory nitrate reductases suggests that only a single cysteine residue (Cys186) is conserved in all these enzymes, indicating that it may play a role in the binding of Mo-pterin to the protein.     

Analysis of free sulfhydryl groups and disulfide bonds in Na+,K+-ATPase

The content of free SH groups and disulfide bonds in the purified pig kidney Na+,K+-ATPase was determined by ammetric titration with silver nitrate. In the native enzyme, most of the free SH groups are masked due to their location in the polypeptide chain regions poorly accessible to SH reagents. Denaturation with 5% SDS and 8 M urea makes these regions accessible thus revealing 22 free SH groups/mol of the protein. After complete blocking of free SH groups with silver ions, 8 SH groups/mol of the protein are being released upon sulfitolysis which indicates the presence of four disulfide bonds in the enzyme. At least one disulfide bridge is located in the alpha-subunit whereas the beta-subunit contains three disulfide bonds.     

Identification by site-directed mutagenesis and chemical modification of three vicinal cysteine residues in rat mitochondrial carnitine/acylcarnitine transporter

The proximity of the Cys residues present in the mitochondrial rat carnitine/acylcarnitine carrier (CAC) primary structure was studied by using site-directed mutagenesis in combination with chemical modification. CAC mutants, in which one or more Cys residues had been replaced with Ser, were overexpressed in Escherichia coli and reconstituted into liposomes. The effect of SH oxidizing, cross-linking, and coordinating reagents was evaluated on the carnitine/carnitine exchange catalyzed by the recombinant reconstituted CAC proteins. All the tested reagents efficiently inhibited the wild-type CAC. The inhibitory effect of diamide, Cu(2+)-phenanthroline, or phenylarsine oxide was largely reduced or abolished by the double substitutions C136S/C155S, C58S/C136S, and C58S/C155S. The decrease in sensitivity to these reagents was much lower in double mutants in which Cys(23) was substituted with Cys(136) or Cys(155). No decrease in inhibition was found when Cys(89) and/or Cys(283) were replaced with Ser. Sb(3+), which coordinates three cysteines, inhibited only the Cys replacement mutants containing cysteines 58, 136, and 155 of the six native cysteines. In addition, the mutant C23S/C89S/C155S/C283S, in which double tandem fXa recognition sites were inserted in positions 65-72, i.e. between Cys(58) and Cys(136), was not cleaved into two fragments by fXa protease after treatment with diamide. These results are interpreted in light of the homology model of CAC based on the available x-ray structure of the ADP/ATP carrier. They indicate that Cys(58), Cys(136), and Cys(155) become close in the tertiary structure of the CAC during its catalytic cycle.     

Reinvestigation of metal ion specificity for quinone cofactor biogenesis in bacterial copper amine oxidase

The topa quinone (TPQ) cofactor of copper amine oxidase is generated by copper-assisted self-processing of the precursor protein. Metal ion specificity for TPQ biogenesis has been reinvestigated with the recombinant phenylethylamine oxidase from Arthrobacter globiformis. Besides Cu2+ ion, some divalent metal ions such as Co2+, Ni2+, and Zn2+ were also bound to the metal site of the apoenzyme so tightly that they were not replaced by excess Cu2+ ions added subsequently. Although these noncupric metal ions could not initiate TPQ formation under the atmospheric conditions, we observed slow spectral changes in the enzyme bound with Co2+ or Ni2+ ion under the dioxygen-saturating conditions. Resonance Raman spectroscopy and titration with phenylhydrazine provided unambiguous evidence for TPQ formation by Co2+ and Ni2+ ions. Steady-state kinetic analysis showed that the enzymes activated by Co2+ and Ni2+ ions were indistinguishable from the corresponding metal-substituted enzymes prepared from the native copper enzyme (Kishishita, S., Okajima, T., Kim, M., Yamaguchi, H., Hirota, S., Suzuki, S., Kuroda, S., Tanizawa, K., and Mure, M. (2003) J. Am. Chem. Soc. 125, 1041-1055). X-ray crystallographic analysis has also revealed structural identity of the active sites of Co- and Ni-activated enzymes with Cu-enzyme. Thus Cu2+ ion is not the sole metal ion assisting TPQ formation. Co2+ and Ni2+ ions are also capable of forming TPQ, though much less efficiently than Cu2+.     

Potato tuber succinate semialdehyde dehydrogenase: purification and characterization

Succinate semialdehyde dehydrogenase (SSADH) has been purified from potato tubers with 39% yield, 832-fold purification, and a specific activity of 6.5 units/mg protein. The final preparation was homogeneous as judged from native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Gel filtration on Sepharose 6B gave a relative molecular mass (Mr) of 145,000 for the native enzyme. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis gave a single polypeptide band of Mr 35,000. Thus the enzyme appears to be a tetramer of identical subunits. Chromatofocusing of the enzyme gave a pI of 8.7. The enzyme was maximally active at pH 9.0 in 100 mM sodium pyrophosphate buffer. In 100 mM Tris-HCl buffer, pH 9.0, the enzyme gave only 20% of the activity found in pyrophosphate buffer and had a shorter linear rate. The enzyme was specific for succinate semialdehyde (SSA) as substrate and could not utilize acetaldehyde, glyceraldehyde 3-phosphate, malonaldehyde, lactate, or ethanol as substrates. The enzyme was also specific for NAD+ as cofactor and NADP+ and 3-acetylpyridine adenine dinucleotide could not serve as cofactors. Potato SSADH had a Km of 4.6 microM for SSA when assayed in pyrophosphate buffer and was inhibited by that substrate at concentrations greater than 120 microM. The Km for NAD+ was found to be 31 microM. The enzyme required exogenous addition of a thiol compound for maximal activity and was inhibited by the thiol-directed reagents p-hydroxymercuribenzoate, dithionitrobenzoate, and N-ethyl-maleimide, by heavy metal ions Hg2+, Cu2+, Cd2+, and Zn2+, and by arsenite. These results indicate a requirement of a SH group for catalytic activity.     

Effect of cysteine residues on the activity of arginyl-tRNA synthetase from Escherichia coli.

Arginyl-tRNA synthetase (ArgRS) from Escherichia coli (E. coli) contains four cysteine residues. In this study, the role of cysteine residues in the enzyme has been investigated by chemical modification and site-directed mutagenesis. Titration of sulfhydryl groups in ArgRS by 5, 5'-dithiobis(2-nitro benzoic acid) (DTNB) suggested that a disulfide bond was not formed in the enzyme and that, in the native condition, two DTNB-sensitive cysteine residues were located on the surface of ArgRS, while the other two were buried inside. Chemical modification of the native enzyme by iodoacetamide (IAA) affected only one DTNB-sensitive cysteine residue and resulted in 50% loss of enzyme activity, while modification by N-ethylmeimide (NEM) affected two DTNB-sensitive residues and caused a complete loss of activity. These results, when combined with substrate protection experiments, suggested that at least the two cysteine residues located on the surface of the molecule were directly involved in substrates binding and catalysis. However, changing Cys to Ala only resulted in slight loss of enzymatic activity and substrate binding, suggesting that these four cysteine residues in E. coli ArgRS were not essential to the enzymatic activity. Moreover, modifications of the mutant enzymes indicated that the two DTNB- and NEM-sensitive residues were Cys(320) and Cys(537) and the IAA-sensitive was Cys(320). Our study suggested that inactivation of E. coli ArgRS by sulfhydryl reagents is a result of steric hindrance in the enzyme.     

The modification of sulfhydryl groups of glutamine synthetase from Bacillus stearothermophilus with 5, 5'-dithiobis(2-nitrobenzoic acid).

The SH groups of glutamine synthetase [EC 6.3.1.2] from Bacillus stearothermophilus were modified with 5, 5'-dithiobis(2-nitrobenzoic acid) in order to determine the number of SH groups in the molecule as well as the effect of the modification on the enzyme activity. Three SH groups per subunit were detected after complete denaturation of the enzyme with 6 M urea, one of which was essential for the enzyme activity in view of its reactivity with 5, 5'-dithiobis(2-nitrobenzoic acid) on addition of MgCl2 with loss of the activity. The CD spectra of the modified enzyme in the near ultraviolet region changed from that of the native enzyme, indicating that aromatic amino acid residues were affected by modification of the SH group. The fluorescence derived from tryptophanyl residue(s) was quenched depending on the extent of modification of the SH group, suggesting that the tryptophanyl residue(s) was located in the proximity of the SH group. The thermostability of the enzyme was remarkably decreased by modification of the SH group.