A thermostable <Emphasis Type="SmallCaps">L</Emphasis>-aminoacylase from<Emphasis Type="Italic"> Thermococcus litoralis</Emphasis>: cloning,overexpression, characterization,and applications in biotransformations

A thermostable L-aminoacylase from Thermococcus litoralis was cloned, sequenced, and overexpressed in Escherichia coli. The enzyme is a homotetramer of 43 kDa monomers and has an 82% sequence identity to an aminoacylase from Pyrococcus horikoshii and 45% sequence identity to a carboxypeptidase from Sulfolobus solfataricus. It contains one cysteine residue that is highly conserved among aminoacylases. Cell-free extracts of the recombinant enzyme were characterized and were found to have optimal activity at 85 degrees C in Tris-HCl at pH 8.0. The recombinant enzyme is thermostable, with a half-life of 25 h at 70 degrees C. Aminoacylase inhibitors, such as mono-tert-butyl malonate, had only a slight effect on activity. The enzyme was partially inhibited by EDTA and p-hydroxymercuribenzoate, suggesting that the cysteine residue and a metal ion are important, but not essential, for activity. Addition of Zn2+ and Co2+ to the apoenzyme increased the enzyme activity, whereas Sn4+ and Cu2+ almost completely abolished enzyme activity. The enzyme was most specific for substrates containing N-benzoyl- or N-chloroacetyl-amino acids. preferring substrates containing hydrophobic, uncharged, or weakly charged amino acids such as phenylalanine, methionine, and cysteine.     

Reactivities of sulfhydryl groups in native and metal-free aminoacylase I

Aminoacylase I from porcine kidney (EC 3.5.1.14) contains seven cysteine residues per subunit. Three sulfhydryl groups are accessible to modification by 4-hydroxymercuribenzoate (p-MB). The kinetics of the reaction suggest that only one of these groups affects acylase activity when modified by p-MB. Its reaction rate increases 2-3-fold when the essential metal ion of aminoacylase is removed. Modification of metal-free apoenzyme by N-ethylmaleimide (NEM) abolishes its activity without impairing Zn2+ binding. This indicates that the sulfhydryl group reacting with NEM is not directly coordinated to the metal. DTNB (5,5'-Dithio-bis(2-nitrobenzoate), Ellman's reagent) also modifies three sulfhydryl groups per subunit. In this case, the reactivities of native aminoacylase and apoenzyme are not significantly different. N-Hydroxy-2-aminobutyrate, a strong aminoacylase inhibitor, substantially increases the reactivity of the slowest reacting sulfhydryl in both native enzyme and metal-free aminoacylase. It appears that binding of the inhibitor or removal of the metal ion induces conformational changes of the amino-acylase active site that render a buried sulfhydryl group more accessible to modification.     

Mono- and binuclear Zn2+-beta-lactamase. Role of the conserved cysteine in the catalytic mechanism

When expressed by pathogenic bacteria, Zn2+-beta-lactamases induce resistance to most beta-lactam antibiotics. A possible strategy to fight these bacteria would be a combined therapy with non-toxic inhibitors of Zn2+-beta-lactamases together with standard antibiotics. For this purpose, it is important to verify that the inhibitor is effective under all clinical conditions. We have investigated the correlation between the number of zinc ions bound to the Zn2+-beta-lactamase from Bacillus cereus and hydrolysis of benzylpenicillin and nitrocefin for the wild type and a mutant where cysteine 168 is replaced by alanine. It is shown that both the mono-Zn2+ (mononuclear) and di-Zn2+ (binuclear) Zn2+-beta-lactamases are catalytically active but with different kinetic properties. The mono-Zn2+-beta-lactamase requires the conserved cysteine residue for hydrolysis of the beta-lactam ring in contrast to the binuclear enzyme where the cysteine residue is not essential. Substrate affinity is not significantly affected by the mutation for the mononuclear enzyme but is decreased for the binuclear enzyme. These results were derived from kinetic studies on two wild types and the mutant enzyme with benzylpenicillin and nitrocefin as substrates. Thus, targeting drug design to modify this residue might represent an efficient strategy, the more so if it also interferes with the formation of the binuclear enzyme.     

Studies on the interactions of glycerol dehydrogenase from Bacillus stearothermophilus with Zn2+ ions and NADH

The interactions of the essential divalent cation, Zn2+, with the binary complex formed between glycerol dehydrogenase (glycerol:NAD+ 2-oxidoreductase, EC 1.1.1.6) and its coenzyme NADH have been examined by fluorescence spectroscopy. Both the metallo and non-metallo form of the enzyme bind the coenzyme NADH. The addition of Zn2+ ions to a solution of the binary complex formed between metal-depleted enzyme and NADH results in a rapid increase in fluorescence emission at 430 nm. This has been used to determine the on rate for Zn2+ to the enzyme/binary complex. A dissociation constant of 3.02 +/- 0.25.10(-9) M for the equilibrium between Zn2+ ions and the enzyme has been determined.     

Assignment of catalytically essential cysteine residues in aspartase by selective chemical modification with N-(7-dimethylamino-4-methylcoumarynyl)maleimide

N-(7-Dimethylamino-4-methylcoumarynyl)maleimide (DACM), a fluorescent reagent for sulfhydryl groups, was employed to determine the functionally essential cysteine residues in aspartase from Escherichia coli. Analysis of the tryptic peptides containing DACM-labeled residues by reverse phase HPLC revealed that Cys-140 and Cys-430 were selectively modified, among 11 residues whose loci were recently determined by a DNA sequencing study (Takagi, J.S., et al. (1985) Nucl. Acids Res. 13, 2063-2074). When the modification was carried out in the presence of Mg2+ and L-aspartate, the enzyme activity remained unchanged and no cysteine residue was modified. This suggests that two cysteine residues are located at the L-aspartate binding site and that at least one of them is involved in the catalytic reaction.     

Metal ion requirements for sequence-specific endoribonuclease activity of the Tetrahymena ribozyme

A shortened form of the self-splicing intervening sequence RNA of Tetrahymena thermophila acts as an enzyme, catalyzing sequence-specific cleavage of RNA substrates. We have now examined the metal ion requirements of this reaction. Mg2+ and Mn2+ are the only metal ions that by themselves give RNA enzyme activity. Atomic absorption spectroscopy indicates that Zn, Cu, Co, and Fe are not present in amounts equimolar to the RNA enzyme and when added to reaction mixtures do not facilitate cleavage. Thus, these ions can be eliminated as cofactors for the reaction. While Ca2+ has no activity by itself, it alleviates a portion of the Mg2+ requirement; 1 mM Ca2+ reduces the Mg2+ optimum from 2 to 1 mM. These results, combined with studies of the reactivity of mixtures of metal ions, lead us to postulate that two classes of metal ion binding sites are required for catalysis. Class 1 sites have more activity with Mn2+ than with Mg2+, with the other divalent ions and Na+ and K+ having no activity. It is not known if ions located at class 1 sites have specific structural roles or are directly involved in active-site chemistry. Class 2 sites, which are presumably structural, have an order of preference Mg2+ greater than or equal to Ca2+ greater than Mn2+ and Ca2+ greater than Sr2+ greater than Ba2+, with Zn2+, Cu2+, Co2+, Na+, and K+ giving no detectable activity over the concentration range tested.     

Chemical Modification of Specific Active Site Amino Acid Residues of Enterobacter aerogenes Glycerol Dehydrogenase

Enterobacter aerogenes glycerol dehydrogenase (GlDH EC 1.1.1.6), a tetrameric NAD + specific enzyme catalysing the interconversion of glycerol and dihydroxyacetone, was inactivated on reaction with pyridoxal 5′-phosphate (PLP) and o -phthalaldehyde (OPA). Fluorescence spectra of PLP-modified, sodium borohydride-reduced GlDH indicated the specific modification of ? -amino groups of lysine residues. The extent of inhibition was concentration and time dependent. NAD + and NADH provided complete protection against enzyme inactivation by PLP, indicating the reactive lysine is at or near the coenzyme binding site. Modification of GlDH by the bifunctional reagent OPA, which reacts specifically with proximal ? -NH 2 group of lysines and -SH group of cysteines to form thioisoindole derivatives, inactivated the enzyme. Molecular weight determinations of the modified enzyme indicated the formation of intramolecular thioisoindole formation. Glycerol partially protected the enzyme against OPA inactivation, whereas NAD + was ineffective. These results show that the lysine involved in the OPA reaction is different from the PLP-reactive lysine, which is at or near the coenzyme binding site. DTNB titration showed the presence of only a single cysteine residue per monomer of GlDH. This could be participating with a proximal lysine residue to form a thioisoindole derivative observed as a result of OPA modification.     

L-threonine dehydrogenase from Escherichia coli. Identification of an active site cysteine residue and metal ion studies

Pure L-threonine dehydrogenase from Escherichia coli is a tetrameric protein (Mr = 148,000) with 6 half-cystine residues/subunit; its catalytic activity as isolated is stimulated 5-10-fold by added Mn2+ or Cd2+. The peptide containing the 1 cysteine/subunit which reacts selectively with iodoacetate, causing complete loss of enzymatic activity, has been isolated and sequenced; this cysteine residue occupies position 38. Neutron activation and atomic absorption analyses of threonine dehydrogenase as isolated in homogeneous form now show that it contains 1 mol of Zn2+/mol of enzyme subunit. Removal of the Zn2+ with 1,10-phenanthroline demonstrates a good correlation between the remaining enzymatic activity and the zinc content. Complete removal of the Zn2+ yields an unstable protein, but the native metal ion can be exchanged by either 65Zn2+, Co2+, or Cd2+ with no change in specific catalytic activity. Mn2+ added to and incubated with the native enzyme, the 65Zn2(+)-, the Co2(+)-, or the Cd2(+)- substituted form of the enzyme stimulates dehydrogenase activity to the same extent. These studies along with previously observed structural homologies further establish threonine dehydrogenase of E. coli as a member of the zinc-containing long chain alcohol/polyol dehydrogenases; it is unique among these enzymes in that its activity is stimulated by Mn2+ or Cd2+.     

Modification of the cysteine residues of cytochrome P-450cam with 2-bromoacetamido-4-nitrophenol

The Pseudomonas putida cytochrome P-450 was alkylated with the SH-reagent, 2-bromoacetamido-4-nitrophenol. One out of eight cysteine residues present in the enzyme reacted rapidly while another 3 ～ 4 cysteine residues were gradually alkylated at longer reaction times. The derivative in which the most reactive cysteine residue was labeled with this reagent was hydrolyzed with trypsin and a tryptic peptide isolated. From the amino acid composition and end group analysis of the peptide, the rapidly reacting cysteine residue was shown to be Cys 355. This cysteine residue is probably exposed on the surface and is involved in the dimerization of the enzyme. The amino acid sequence about cysteine 355 shows sequence homology with residues 429–445 of the rat liver cytochrome P-450-LM-2.     

Catalytic zinc site and mechanism of the metalloenzyme PR-AMP cyclohydrolase

The enzyme N(1)-(5'-phosphoribosyl) adenosine-5'-monophosphate cyclohydrolase (PR-AMP cyclohydrolase) is a Zn(2+) metalloprotein encoded by the hisI gene. It catalyzes the third step of histidine biosynthesis, an uncommon ring-opening of a purine heterocycle for use in primary metabolism. A three-dimensional structure of the enzyme from Methanobacterium thermoautotrophicum has revealed that three conserved cysteine residues occur at the dimer interface and likely form the catalytic site. To investigate the functions of these cysteines in the enzyme from Methanococcus vannielii, a series of biochemical studies were pursued to test the basic hypothesis regarding their roles in catalysis. Inactivation of the enzyme activity by methyl methane thiosulfonate (MMTS) or 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) also compromised the Zn(2+) binding properties of the protein inducing loss of up to 90% of the metal. Overall reaction stoichiometry and the potassium cyanide (KCN) induced cleavage of the protein suggested that all three cysteines were modified in the process. The enzyme was protected from DTNB-induced inactivation by inclusion of the substrate N(1)-(5'-phosphoribosyl)adenosine 5'-monophosphate; (PR-AMP), while Mg(2+), a metal required for catalytic activity, enhanced the rate of inactivation. Site-directed mutations of the conserved C93, C109, C116 and the double mutant C109/C116 were prepared and analyzed for catalytic activity, Zn(2+) content, and reactivity with DTNB. Substitution of alanine for each of the conserved cysteines showed no measurable catalytic activity, and only the C116A was still capable of binding Zn(2+). Reactions of DTNB with the C109A/C116A double mutant showed that C93 is completely modified within 0.5 s. A model consistent with these data involves a DTNB-induced mixed disulfide linkage between C93 and C109 or C116, followed by ejection of the active site Zn(2+) and provides further evidence that the Zn(2+) coordination site involves the three conserved cysteine residues. The C93 reactivity is modulated by the presence of the Zn(2+) and Mg(2+) and substantiates the role of this residue as a metal ligand. In addition, Mg(2+) ligand binding site(s) indicated by the structural analysis were probed by site-directed mutagenesis of three key aspartate residues flanking the conserved C93 which were shown to have a functional impact on catalysis, cysteine activation, and metal (zinc) binding capacity. The unique amino acid sequence, the dynamic properties of the cysteine ligands involved in Zn(2+) coordination, and the requirement for a second metal (Mg(2+)) are discussed in the context of their roles in catalysis. The results are consistent with a Zn(2+)-mediated activation of H(2)O mechanism involving histidine as a general base that has features similar to but distinct from those of previously characterized purine and pyrimidine deaminases.     

Chemical modification of specific active site amino acid residues of Enterobacter aerogenes glycerol dehydrogenase

Enterobacter aerogenes glycerol dehydrogenase (G1DH EC 1.1.1.6), a tetrameric NAD+ specific enzyme catalysing the interconversion of glycerol and dihydroxyacetone, was inactivated on reaction with pyridoxal 5-phosphate (PLP) and o-phthalaldehyde (OPA). Fluorescence spectra of PLP-modified, sodium borohydride-reduced G1DH indicated the specific modification of epsilon-amino groups of lysine residues. The extent of inhibition was concentration and time dependent. NAD+ and NADH provided complete protection against enzyme inactivation by PLP, indicating the reactive lysine is at or near the coenzyme binding site. Modification of G1DH by the bifunctional reagent OPA, which reacts specifically with proximal epsilon-NH2 group of lysines and -SH group of cysteines to form thioisoindole derivatives, inactivated the enzyme. Molecular weight determinations of the modified enzyme indicated the formation of intramolecular thioisoindole formation. Glycerol partially protected the enzyme against OPA inactivation, whereas NAD+ was ineffective. These results show that the lysine involved in the OPA reaction is different from the PLP-reactive lysine, which is at or near the coenzyme binding site. DTNB titration showed the presence of only a single cysteine residue per monomer of G1DH. This could be participating with a proximal lysine residue to form a thioisoindole derivative observed as a result of OPA modification.     

Cysteine in the manganous-isocitrate binding site of pig heart TPN-specific isocitrate dehydrogenase: I. Kinetics of chemical modification and properties of thiocyano enzyme

Pig heart TPN-dependent isocitrate dehydrogenase is inactivated by reaction with 5,5′-dithiobis (2-nitrobenzoic acid) (DTNB). The dependence of the rate constant for inactivation on the reagent concentration is nonlinear, and can be analyzed in terms of the existence of two mechanisms for reaction with the enzyme, one involving reversible binding prior to inactivation and the other a bimolecular reaction. Cyanide reacts with the inactive modified enzyme to yield thiocyano-isocitrate dehydrogenase without increasing the catalytic activity; this result suggests that inactivation by DTNB is not due to steric hindrance by the bulky thionitrobenzoate group bound to the enzyme. The inactive thiocyano enzyme binds manganous ion normally. In contrast to its effect on native enzyme, however, isocitrate does not strengthen the binding of Mn²⁺ to the thiocyano enzyme; the tightened binding of manganous-isocitrate may be critical for the catalytic activity of the enzyme. Protection against inactivation by DTNB is provided by isocitrate plus the activator, manganous ion, or the competitive inhibitor, calcium ion. The concerted inhibitors oxalacetate and glyoxylate, when present together with Mn²⁺ and TPN, also protect against loss of activity. A marked decrease in the inactivation rate constant to a finite limiting value is caused by saturating concentrations of TPNH and Mn²⁺, indicating that these ligands do not bind directly at the sites attacked by DTNB. The number of cysteine residues which react with DTNB concomitant with inactivation depends on the ligands present in the reaction mixture. In all cases, the equivalent of one -SH reacts without affecting activity. In the presence of Mn²⁺ and α-ketoglutarate, which do not appreciably affect the inactivation rate, loss of activity is proportional to reaction with two -SH groups. These results suggest that the integrity of a maximum of two cysteine residues is essential for the function of the pig heart isocitrate dehydrogenase, and that at least one cysteine residue may be located within the manganous-isocitrate binding site.     

Identification of the reactive cysteinyl residue and ATP binding site in Bacillus cereus glutamine synthetase by chemical modification

Bacillus cereus glutamine synthetase was modified by reaction with a fluorescent SH reagent, N-[[(iodoacetyl)amino]ethyl]-5-naphthylamine-1-sulfonic acid (IAEDANS), or an ATP analog, 5'-p-fluorosulfonylbenzoyladenosine (FSBA). The locations of the specific binding sites of these reagents were identified. IAEDANS inactivated Mg2(+)-dependent activity and activated Mn2(+)-dependent activity. FSBA inactivated only Mn2(+)-dependent activity. Mg2+ plus Mn2(+)-dependent activity was inactivated by IAEDANS or FSBA. Amino acid sequence analysis of the single AEDANS-labeled proteolytic fragment showed the cysteinyl residue at position 306 to be the site of modification. Cys 306 is one of three cysteines that are unique to Bacillus glutamine synthetase. The result suggested that the cysteine has a role in the active site of the enzyme. We also report that the amino acid residue modified by FSBA was the lysyl residue at position 43.     

Substrate recognition and fidelity of strand joining by an archaeal DNA ligase.

We have previously identified a DNA ligase (LigTk) from a hyperthermophilic archaeon, Thermococcus kodakaraensis KOD1. The enzyme is the only characterized ATP-dependent DNA ligase from a hyperthermophile, and allows the analysis of enzymatic DNA ligation reactions at temperatures above the melting point of the substrates. Here we have focused on the interactions of LigTk with various DNA substrates, and its specificities toward metal cations. LigTk could utilize Mg2+, Mn2+, Sr2+ and Ca2+ as a metal cation, but not Co2+, Zn2+, Ni2+, or Cu2+. The enzyme displayed typical Michaelis-Menten steady-state kinetics with an apparent Km of 1.4 microm for nicked DNA. The kcat value of the enzyme was 0.11*s-1. Using various 3' hydroxyl group donors (L-DNA) and 5' phosphate group donors (R-DNA), we could detect ligation products as short as 16 nucleotides, the products of 7 + 9 nucleotide or 8 + 8 nucleotide combinations at 40 degrees C. An elevation in temperature led to a decrease in reaction efficiency when short oligonucleotides were used, suggesting that the formation of a nicked, double-stranded DNA substrate preceded enzyme-substrate recognition. LigTk was not inhibited by the addition of excess duplex DNA, implying that the enzyme did not bind strongly to the double-stranded ligation product after nick-sealing. In terms of reaction fidelity, LigTk was found to ligate various substrates with mismatched base-pairing at the 5' end of the nick, but did not show activity towards the 3' mismatched substrates. LigTk could not seal substrates with a 1-nucleotide or 2-nucleotide gap. Small amounts of ligation products were detected with DNA substrates containing a single nucleotide insertion, relatively more with the 5' insertions. The results revealed the importance of proper base-pairing at the 3' hydroxyl side of the nick for the ligation reaction by LigTk.     

Contribution to Catalysis and to Stability of the Essential Cysteine Residue at the Active Site of d-Glucosaminate Dehydratase from Pseudomonas fluorescens

Chemical modification of purified d-glucosaminate dehydratase (GADH) apoenzyme by N-ethyl-maleimide (NEM) and by 7-chloro-4-aminobenzo-2-oxa-1,3-diazole (NBDC1) resulted in the time- and concentration-dependent inactivation of the enzyme in each case. The inactivation followed pseudo-first-order kinetics and a double-logarithmic plot of the observed pseudo-first-order rate constant against reagent concentration proved evidence for an approximately first-order reaction, suggesting that the modification of a single cysteine residue per mole of enzyme resulted in inactivation. Amino acid analysis of the NEM-inactivated enzyme showed that three moles of cysteine residues among six moles per mole of subunit were modified under these conditions, therefore one of the three cysteine residues modified by NEM may be essential for activity. Pyridoxal 5′-phosphate (PLP) and D-glucosaminate (GlcNA) protected the enzyme against inactivation by NEM and NBDCI. The apoenzyme was inactivated by EDTA and activity of enzyme was restored by incubation with Mn²⁺ in the presence of PLP. Incubation of the EDTA-treated enzyme with NEM inhibited the restoration of activity. These results suggest that one of the cysteine residues of GADH may be chelated to a Mn²⁺ at or near the active site of GADH, contributing to formation of the active enzyme.     

Thermoanaerobacter brockii alcohol dehydrogenase: characterization of the active site metal and its ligand amino acids.

The active-site metal ion and the associated ligand amino acids in the NADP-linked, tetrameric enzyme Thermoanaerobacter brockii alcohol dehydrogenase (TBADH) were characterized by atomic absorption spectroscopy analysis and site-directed mutagenesis. Our preliminary results indicating the presence of a catalytic zinc and the absence of a structural metal ion in TBADH (Peretz & Burstein. 1989. Biochemistry 28:6549-6555) were verified. To determine the role of the putative active-site zinc, we investigated whether exchanging the zinc for other metal ions would affect the structural and/or the enzymatic properties of the enzyme. Substituting various metal ions for zinc either enhanced or diminished enzymatic activity, as follows: Mn2+ (240%); Co2+ (130%); Cd2+ (20%); Cu2+ or V3+ (< 5%). Site-directed mutagenesis to replace any one of the three putative zinc ligands of TBADH, Cys 37, His 59, or Asp 150, with the non-chelating residue, alanine, abolished not only the metal-binding capacity of the enzyme but also its catalytic activity, without affecting the overall secondary structure of the enzyme. Replacing the three putative catalytic zinc ligands of TBADH with the respective chelating residues serine, glutamine, or cysteine damaged the zinc-binding capacity of the mutated enzyme and resulted in a loss of catalytic activity that was partially restored by adding excess zinc to the reaction. The results imply that the zinc atom in TBADH is catalytic rather than structural and verify the involvement of Cys 37, His 59, and Asp 150 of TBADH in zinc coordination.     

Inhibition of human NTPDase 2 by modification of an intramembrane cysteine by p-chloromercuriphenylsulfonate and oxidative cross-linking of the transmembrane domains

Human NTPDase 2 is a cell surface integral membrane glycoprotein that is anchored to the membranes by two transmembrane domains while the bulk of the protein containing the active site faces the extracellular milieu. It contains 10 conserved cysteine residues in the extracellular domain that are involved in disulfide bond formation and one free cysteine residue, C26, which is located in the N-terminal transmembrane domain. The human NTPDase 2 activity is inactivated by membrane perturbation that disrupts interaction of the transmembrane domains and is inhibited by p-chloromercuriphenylsulfonate (pCMPS), a sulfhydryl reagent. In this report, we show that C26 is the target of pCMPS modification, since a mutant in which C26 was replaced with a serine was no longer inhibited by pCMPS. Mutants in which cysteine residues are placed in the C-terminal transmembrane domain near the extracellular surface were still modified by pCMPS, but the degree of inhibition of their ATPase activity was lower than that of the wild-type enzyme. Thus, loss of the ATPase activity of human NTPDase 2 in the presence of pCMPS probably results from the disturbance of both transmembrane domain interaction and its active site. Inhibition of human NTPDase 2 activity by pCMPS and membrane perturbation is attenuated when the enzyme is cross-linked by glutaraldehyde. On the other hand, NTPDase 2 dimers formed from oxidative cross-linking of the wild-type enzyme and mutants containing a single cysteine residue in the C-terminal transmembrane domain displayed reduced ATPase activity. A similar reduction in activity was also obtained upon intramolecular disulfide formation in mutants that contain a cysteine residue in each of the two transmembrane domains. These results indicate that the mobility of the transmembrane helices is necessary for maximal catalysis.     

Kinetics and mechanisms of the recombination of Zn2+, Co2+, and Ni2+ with the metal-depleted catalytic site of horse liver alcohol dehydrogenase

The kinetics of the recombination of the metal-depleted active site of horse liver alcohol dehydrogenase (LADH) with metal ions have been studied over a range of pH and temperature. The formation rates were determined optically, by activity measurements, or by using the pH change during metal incorporation with a pH-indicator as monitor. The binding of Zn2+, Co2+, and Ni2+ ions occurs in a two-step process. The first step is a fast equilibrium reaction, characterized by an equilibrium constant K1. The spectroscopic and catalytic properties of the native or metal-substituted protein are recovered in a slow, monomolecular process with the rate constant k2. The rate constants k2 5.2 X 10(-2) sec-1 (Zn2+), 1.1 X 10(-3) sec-1 (Co2+), and 2 X 10(-4) sec-1 (Ni2+). The rate constants increase with increasing pH. Using temperature dependence, the activation parameters for the reaction with Co2+ and Ni2+ were determined. Activation energies of 51 +/- 2.5 kJ/mol (0.033 M N-Tris-(hydroxymethyl)methyl-2-aminomethane sulfonic acid (TES), pH 6, 9) for Co2+ and 48.5 +/- 4 kJ/mol (0.033 M TES, pH 7, 2) for Ni2+ at 23 degrees C were found. The correspondent activation entropies are - 146 +/- 10 kJ/mol K for Co2+ and - 163 +/- 9 kJ/mol K for Ni2+. Two protons are released during the binding of Zn2+ to H4Zn(n)2 LADH in the pH range 6.8-8.1. The binding of coenzyme, either reduced or oxidized, prevents completely the incorporation of metal ions, suggesting that the metal ions enter the catalytic site via the coenzyme binding domain and not through the hydrophobic substrate channel.     

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

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

Inactivation of Lipoxygenase by Hydrogen Peroxide,Cysteine and Some Other Reagents

The polarographic data show that H₂O₂ is not formed during the course of the coupled oxidation of antioxidants by lipoxygenase from defatted soybean meal. A lower concentration of H₂O₂ or autoxidizing cysteine has been found to induce an irreversible inactivation of the enzyme. Inactivation activity of cysteine is reduced either by the addition of catalase or under anaerobic condition. These facts are indicative of the oxidative function of autoxidizing cysteine for the enzyme. The inactivation by cysteine and H₂O₂ respectively is in additive and is impeded by the addition of competitive inhibitors such as linolelaidic and conjugated linoleic acids, indicating a possible reaction with a certain amino acid residue involved in the enzymic catalysis. The experimental evidences obtained with H₂O₂ and some other modifying reagents have been integrated to furnish a basis of later identification of the residue that is exerting the specific catalytic function.