分枝犁头霉α-半乳糖苷酶的氨基酸组成及化学修饰

α-半乳糖苷酶进行氨基酸组分分析,结果为含有较多的酸性及巯水性氨基酸,较少的组氨酸、酪氨酸及半胱氨酸。 用几种蛋白质侧链修饰试剂对α-半乳糖苷酶进行化学修饰。在一定条件下,当巯基及酪氨酸残基分别被NEM、IAA及NAI修饰后,酶活力不受影响,说明这些基团与活力无关。当羟基、组氨酸及色氨酸残基分别被EDC、DEP、NBS及HNBB修饰后,酶活力大幅度下降,说明这些基团或者参与了酯催化作用或者位于酯活性位区附近。     

Effect of inhibitors of trypsin-like proteolytic enzymes Bacillus cereus T spore germination.

The germination of Bacillus cereus T spore suspensions is partially prevented by several inhibitors of trypsin-like enzymes. Leupeptin, antipain, and tosyl-lysine-chloromethyl ketone are effective inhibitors, whereas chymostatin, elastatinal, and pepstatin are inactive. A synthetic substrate of trypsin, tosyl-arginine-methyl ester, also inhibits germination. Its inhibitory effect decreases as a function of incubation time in the presence of spores and is abolished by previous hydrolysis with trypsin. Germinating, but not dormant, spore suspensions hydrolyze tosyl-arginine-methyl ester; its hydrolysis is insensitive to chloramphenicol, sulfhydryl reagents, and EDTA. A crude extract of germinated B. cereus spores contains a trypsin-like enzyme whose activity, as measured by hydrolysis of benzoyl-arginine p-nitroanilide, is sensitive to germination-inhibitory compounds such as leupeptin, tosyl-arginine-methyl ester, and tosyl-lysine-chloromethyl ketone. Spore suspensions exposed to the above inhibitors under germination conditions lose only part of their heat resistance and some 10 to 30% of their dipicolinic acid content. Part of the germinating spore population becomes "phase grey" under phase optics. Based on a study of the inhibition of germination by protease inhibitors and the activity of a protease in germination spores and spore extracts, it is suggested that the activity of a trypsin-like enzyme may be involved in the mechanism of the breaking of dormancy in spores of B. cereus T.     

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.     

Effect of cadmium,mercury and copper on partially purified hepatic flavokinase of rat

The effect of cadmium (Cd2+), mercury (Hg2+) and copper (Cu2+) was studied with partially purified flavokinase (ATP:riboflavin 5-phosphotransferase EC 2.7.1.26) from rat liver. All the divalent heavy metal cations inhibited flavokinase activity in a concentration-dependent manner. The inhibitory effect of cadmium on the enzyme was completely reversed by increasing concentration, of Zinc (Zn2+) indicating a competition between Zn2+ and Cd2+ for binding with the enzyme. A competition between riboflavin and Cd2+ is also evident from the present investigation. These observations hint at the possibility that Zn2+ and Cd2+ probably compete for the same site on the enzyme where riboflavin binds. However, inhibition of flavokinase by Hg2+ could not be reversed by Zn2+. Our studies further reveal that hepatic flavokinase appears to contain an essential, accessible and functional thiol group(s) which is evident from a concentration dependent inhibition of activity by sulfhydryl reagent s like parachloromercuribenzoate (PCMB), 5,5-dithiobis (2-nitrobenzoic acid)(DTNB), and N-ethylmaleimide (NEM). Inhibition of flavokinase by sulfhydryl reagents were protected, except in case of NEM inhibition, when the enzyme was incubated with thiol protectors like glutathione (GSH) and dithiothreitol (DTT). Furthermore, the enzyme could also be protected from the inhibitory effect of Cd2+ and Hg2+ by GSH and DTT suggesting that Cd2+ probably interacts with a reactive thiol group at or near the active site of enzyme in bringing about its inhibitory effect. (Mol Cell Biochem 167: 73-80, 1997)     

The plasma membrane H+-ATPase of Neurospora crassa. Properties of two reactive sulfhydryl groups

Previous work with N-ethylmaleimide (NEM) has defined two sites on the Neurospora plasma membrane H+-ATPase. Modification of one (the "fast" site) by NEM is rapid but does not affect ATPase activity, while modification of the other (the "slow" site) inactivates the enzyme and is protectable by MgATP or MgADP. In the present study, a wider array of sulfhydryl reagents have been used to examine the properties of both sites. The results show the following. (a) Both fast and slow sites react preferentially with hydrophobic compounds (N-pyrenemaleimide, dithiobisnitropyridine greater than N-naphthylmaleimide, dithiobisnitrobenzoate greater than N-phenylmaleimide greater than N-ethylmaleimide) and are virtually insensitive to hydrophilic sulfhydryl reagents such as iodoacetamide and iodoacetic acid. (b) The reaction rate of the slow site with NEM is approximately 2000-fold less rapid than that of the fast site. The slow site also has an unusually high pKa (greater than 9.5). (c) Whether or not cysteine modification leads to inactivation of the ATPase depends upon the site and the reagent. For example, when the fast site reacts with NEM, enzymatic activity is retained; when it reacts with N-pyrenemaleimide, activity is lost. Likewise, when the slow site is modified by any of the maleimides or by dithiobisnitropyridine or dithiobisnitrobenzoate, the ATPase is inactivated; when it is modified by methylmethanethiosulfonate, activity remains intact. Thus, neither cysteine can be considered to play an essential role in the reaction cycle of the ATPase, but the introduction of a sufficiently bulky substituent at either site can disrupt activity. (d) Upon reaction of methylmethanethiosulfonate at the slow site, the K1/2 for MgATP hydrolysis is reduced from 0.65 to 0.25 mM. This result strengthens the evidence for a conformational relationship between the slow site cysteine and the nucleotide binding site of the ATPase.     

Deoxycytidylate hydroxymethylase: purification, properties, and the role of a thiol group in catalysis

Deoxycytidylate (dCMP) hydroxymethylase from Escherichia coli infected with a T-4 bacteriophage amber mutant has been purified to homogeneity. It is a dimer with a subunit molecular weight of 28,000. Chemical modification of the homogeneous enzyme with N-ethylmaleimide (NEM) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) leads to complete loss of enzyme activity. dCMP can protect the enzyme against NEM inactivation, but the dihydrofolate analogues methotrexate and aminopterin alone do not afford similar protection. Compared to dCMP alone, dCMP plus either methotrexate or aminopterin greatly enhances protection against NEM inactivation. DTNB inactivation is reversed by dithiothreitol. For both reagents, inactivation kinetics obey second-order kinetics. NEM inactivation is pH dependent with a pKa for a required thiol group of 9.15 +/- 0.11. Complete enzyme inactivation by both reagents involves the modification of one thiol group per mole of dimeric enzyme. There are two thiol groups in the totally denatured enzyme modified by either NEM or DTNB. Kinetic analysis of NEM inactivation cannot distinguish between these two groups; however, with DTNB kinetic analysis of 2-nitro-5-thiobenzoate release shows that enzyme inactivation is due to the modification of one fast-reacting thiol followed by the modification of a second group that reacts about 5-6-fold more slowly. In the presence of methotrexate, the stoichiometry of dCMP binding to the dimeric enzyme is 1:1 and depends upon a reduced thiol group. It appears that the two equally sized subunits are arranged asymmetrically, resulting in one thiol-containing active site per mole of dimeric enzyme.     

Multi-step analysis of Hg2+ ion inhibition of jack bean urease

We performed a multi-step analysis of the inhibition of jack bean urease by Hg(2+) ions that included residual activity measurements after incubation of the enzyme with the metal ion, reactivation of Hg(2+)-inhibited urease, protection of urease with thiol reagents prior to incubation with Hg(2+), progress curve analysis, and spectroscopic assay of thiol groups in urease-Hg(2+) complexes with a cysteine selective agent 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB). Hg(2+) ions were found to form stable complexes with urease that could rapidly be reversed only by the treatment with dithiotreitol, and not by dilution or dialysis. The residual activity data interpreted in terms of the Hill equation revealed the multisite Hg(2+) inhibition of urease, and along with the DTNB thiol-assay they demonstrated the involvement in the reaction with Hg(2+) of six cysteine residues per enzyme subunit, including the active-site flap cysteine. The molar ratios of the inhibitor and enzyme imply that the inhibition consists of the formation of RSHgX complexes, X being a water molecule or an anion. The time-dependent Hg(2+) inhibitory action on urease determined in the system without enzyme preincubation was best described by slow-binding mechanism with the steady-state inhibition constant K(i) = 1.9 nM (+/-10%).     

Covalent modification of cysteine 193 impairs ATPase function of nucleotide-binding domain of a Candida drug efflux pump

N-ethylmaleimide (NEM) impairs the ATPase function of N-terminal NBD of Candida drug resistance gene product Cdr1p. To identify the reactive cysteine(s) for such a contribution, we adopted a three-arm approach that included covalent modification, cysteine mutagenesis, and structure homology modeling. The covalent modification results clearly indicate the ability of NEM and iodoacetic acid (IAA) to potently inhibit the ATPase activity of N-terminal NBD. Since this domain contains five cysteine residues in its sequence, we mutated each and found four of these (C325A, C363A, C402A, and C462A) to stay sensitive to NEM/IAA modification and influence ATPase activity, while C193A mutation completely abrogated the catalytic function. The structural homology modeling data further validate these biochemical findings by ruling out any plausible interactions within the cysteine residues, and deriving the importance of Cys-193 in lying at a bond length clearly feasible to interact with ATP and divalent cation to critically influence ATP hydrolysis.     

Sulfhydryl groups of an extramitochondrial acetyl-CoA hydrolase from rat liver

An extramitochondrial acetyl-CoA hydrolase (EC 3.1.2.1) purified from rat liver was inactivated by heavy metal cations (Hg2+, Cu2+, Cd2+ and Zn2+), which are known to be highly reactive with sulfhydryl groups. Their order of potency for enzyme inactivation was Hg2+ greater than Cu2+ greater than Cd2+ greater than Zn2+. This enzyme was also inactivated by various sulfhydryl-blocking reagents such as p-hydroxymercuribenzoate (PHMB), N-ethylmaleimide (NEM), 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB), and iodoacetate (IAA). DL-Dithiothreitol (DTT) reversed the inactivation of this enzyme by DTNB markedly, and that by PHMB slightly, but did not reverse the inactivations by NEM, DTNB and IAA. Benzoyl-CoA (a substrate-like competitive inhibitor) and ATP (an activator) greatly protected acetyl-CoA hydrolase from inactivation by PHMB, NEM, DTNB and IAA. These results suggest that the essential sulfhydryl groups are on or near the substrate binding site and nucleotide binding site. The enzyme contained about four sulfhydryl groups per mol of monomer, as estimated with DTNB. When the enzyme was denatured by 4 M guanidine-HCl, about seven sulfhydryl groups per mol of monomer reacted with DTNB. Two of the four sulfhydryl groups of the subunit of the native enzyme reacted with DTNB first without any significant inactivation of the enzyme, but its subsequent reaction with the other two sulfhydryl groups seemed to be involved in the inactivation process.     

Reactivity and pH dependence of thiol conjugation to N-ethylmaleimide: detection of a conformational change in chalcone isomerase

The reactivity of simple alkyl thiolates with N-ethylmaleimide (NEM) follows the Br?nsted equation, log kS- = log G + beta pK, with G = 790 M-1 min-1 and beta = 0.43. The rate constant for the reaction of the thiolate of 2-mercaptoethanol with NEM is 10(7) M-1 min-1, whereas the rate constant for the reaction of the protonated thiol is less than 0.0002 M-1 min-1. The intrinsic reactivity of the protonated thiol (SH) is over (5 X 10(10]-fold less than the thiolate (S-) and makes a negligible contribution to the reactivity of thiols toward NEM. The rate of NEM modification of chalcone isomerase was conveniently measured by following the concomitant loss in enzymatic activity. The pseudo-first-order rate constants for inactivation show a linear dependence on the concentration of NEM up to 200 mM and yield no evidence for noncovalent binding of NEM to the enzyme. Evidence is presented demonstrating that the modification of chalcone isomerase by NEM is limited to a single cysteine residue over a wide range of pH. Kinetic protection against inactivation and modification by NEM is provided by competitive inhibitors and supports the assignment of this cysteine residue to be at or near the active site of chalcone isomerase. The pH dependence of inactivation of the enzyme by NEM indicates a pK of 9.2 for the cysteine residue in chalcone isomerase. At high pH, the enzymatic thiolate is only (3 X 10(-5))-fold as reactive as a low molecular weight alkyl thiolate of the same pK, suggesting a large steric inhibition of reaction on the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Affinity purification and characterization of 2,4-dichlorophenol hydroxylase from Pseudomonas cepacia

2,4-Dichlorophenol hydroxylase, a flavoprotein monooxygenase from Pseudomonas cepacia grown on 2,4-dichlorophenoxyacetic acid (2,4-D) as the sole source of carbon, was purified to homogeneity by a single-step affinity chromatography on 2,4-DCP-Sepharose CL-4B. The enzyme was eluted from the affinity matrix with the substrate 2,4-dichlorophenol. The enzyme has a molecular weight of 275,000 consisting of four identical subunits of molecular weight 69,000 and requires exogenous addition of FAD for its complete catalytic activity. The enzyme required an external electron donor NADPH for hydroxylation of 2,4-dichlorophenol to 3,5-dichlorocatechol. NADPH was preferred over NADH. The enzyme had Km value of 14 microM for 2,4-dichlorophenol, and 100 microM for NADPH. The enzyme activity was significantly inhibited by heavy metal ions like Hg2+ and Zn2+ and showed marked inhibition with thiol reagents. Trichlorophenols inhibited the enzyme competitively. The hydroxylase activity decreased as a function of increasing concentrations of Cibacron blue and Procion red dyes. The apoenzyme prepared showed complete loss of FAD when monitored spectrophotometrically and had no enzymatic activity. The inactive apoenzyme was reconstituted with exogenous FAD which completely restored the enzyme activity.     

Comparative effects of sulfhydryl reagents on membrane-bound and solubilized UDP-glucose:ceramide glucosyltransferase from Golgi membranes. Evidence for partial involvement of a thiol group in the nucleotide sugar binding site of the solubilized enzyme

We have studied the inactivation of membrane-bound and solubilized UDP-glucose:ceramide glucosyltransferase from Golgi membranes by various types of sulfhydryl reagents. The strong inhibition of the membrane-bound form by the non-penetrant mercurial-type reagents clearly corroborated the fact that in sealed and right-side-out Golgi vesicles the ceramide glucosyltransferase is located on the cytoplasmic face. No significant differences in the susceptibility to the various sulfhydryl reagents were noted when solubilized enzyme was assayed, showing that solubilization does not reveal other critical SH groups. The different results obtained must be interpreted with regard to several thiol groups, essential for enzyme activity. No protection by the substrate UDP-glucose against mercurial-type reagents was obtained indicating that these thiol groups were not located in the nucleotide sugar binding domain. A more thorough investigation of the thiol inactivation mechanism was undertaken with NEM (N-ethylmaleimide), an irreversible reagent. The time dependent inactivation followed first order kinetics and provided evidence for the binding of 1 mol NEM per mol of enzyme. UDP-Glucose protected partially against NEM inactivation, indicating that the thiol groups may be situated in or near the substrate binding domain. Inactivation experiments with disulfide reagents showed that increased hydrophobicity led to more internal essential SH groups which are not obviously protected by the substrate UDP-glucose, thus not implicated in the substrate binding domain, but rather related to conformational changes of the enzyme during the catalytic process.Abbreviations Chaps 3-[(3-cholamidopropyl)dimethylammonio] 1-propanesulfonate - Mops 4-morpholinepropanesulfonic acid - PC phosphatidylcholine - NEM N-ethylmaleimide - CPDS carboxypyridine disulfide (dithio-6,6-dinicotinic acid) - DTNB 5,5-dithiobis-(2-nitrobenzoic acid) - DTP dithiodipyridine - p-HMB para-hydroxymercuribenzoate - DTT dithiothreitol - BAL British anti-Lewisite (dimercaptopropanol) - Zw 3–14 Zwittergent 3–14     

A sulfhydryl presumed essential is not required for catalysis by an aminoacyl-tRNA synthetase

Several aminoacyl-tRNA synthetases are sensitive to reagents that modify sulfhydryl groups. We report here the significance of N-ethylmaleimide (NEM)-mediated inactivation of Escherichia coli glycyl-tRNA synthetase, and alpha 2 beta 2 enzyme. We confirmed earlier observations that NEM abolishes synthetase-catalyzed aminoacylation with pseudo-first order kinetics and provided a second method of proof that the site of inactivation is located in the beta-subunit. Using oligonucleotide-directed mutagenesis of the glyS gene, each beta-subunit cysteine codon (positions 98, 395, and 450) was replaced, individually, by an alanine codon. The three resulting mutant proteins are each active in vivo, and their in vitro aminoacylation activities are comparable to that of the native enzyme. A mutant incorporating all three amino acid substitutions is also active in vivo and in vitro. These results establish conclusively that a beta-subunit cysteine thiol is not required for the catalysis of aminoacylation. The Cys98----Ala and Cys450----Ala mutants are inactivated by NEM with the same kinetics as the wild-type protein. However, the Cys395----Ala mutant is refractory to NEM. This suggests that NEM inactivation of the native enzyme is due to alkylation of Cys395. Aware that inactivation may result from steric effects, we constructed a mutant with a bulkier amino acid residue at position 395 (Cys395----Gln). The aminoacylation activity of this protein is less than 10% of that of the wild-type enzyme. The glutamine substitution affects only the tRNA-dependent step of the reaction--the rate of glycyl adenylate synthesis is not lowered. In these features, the mutant resembles the NEM-inactivated protein. We propose that the NEM sensitivity of glycyl-tRNA synthetase, and possibly of other synthetases, arises from steric or conformational effects of the alkylated cysteine side chain.     

Structural comparison of human monoamine oxidases A and B: mass spectrometry monitoring of cysteine reactivities

Monoamine oxidases (MAO) A and B are approximately 60-kDa outer mitochondrial membrane flavoenzymes catalyzing the degradation of neurotransmitters and xenobiotic arylalkyl amines. Despite 70% identity of their amino acid sequences, both enzymes exhibit strikingly different properties when exposed to thiol-modifying reagents. Human MAO A and MAO B each contain 9 cysteine residues (7 in conserved sequence locations). MAO A is inactivated by N-ethylmaleimide (NEM) much faster (tau(1/2) = approximately 3 min) than MAO B (tau(1/2) = approximately 8 h). These differences in thiol reactivities are also demonstrated by monitoring the NEM modification stoichiometries by electrospray mass spectrometry. Inactivation of either enzyme with acetylenic inhibitors results in alterations of their thiol reactivities. Cys5 and Cys266 were identified as the only residues modified by biotin-derivatized NEM in clorgyline-inactivated MAO A and pargyline-inactivated MAO B, respectively. The x-ray structure of MAO B (Binda, C., Newton-Vinson, P., Hubalek, F., Edmondson, D. E., and Mattevi, A. (2002) Nat. Struct. Biol. 9, 22-26) shows that Cys5 is located on the surface of the molecule opposite to the membrane-binding region. Cys266 in MAO A is predicted to be located in the same region of the molecule. These thiol residues are also modified by biotin-derivatized NEM in the mitochondrial membrane-bound MAO A and MAO B. This study shows that the MAO A structure is "more flexible" than that of MAO B and that clorgyline and pargyline inactivation of MAO A and B, respectively, increases the structural stability of both enzymes. No evidence is found for the presence of disulfide bonds in either enzyme, contrary to a previous suggestion.     

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.     

An essential cysteine residue located in the vicinity of the FAD-binding site in short-chain, medium-chain, and long-chain acyl-CoA dehydrogenases from rat liver mitochondria

Medium-chain and long-chain acyl-CoA dehydrogenases from rat liver have been purified in two forms, holoenzymes containing FAD and apoenzymes which do not contain this cofactor. In contrast, short-chain acyl-CoA dehydrogenase can only be isolated as the holoenzyme. Marked differences in the reactivity to organic sulfhydryl reagents were observed between the apo and holo forms of these enzymes. While the two apoenzymes were severely inactivated by N-ethylmaleimide (NEM), p-chloromercuribenzoate (pCMB), and iodoacetate (IAA), the two corresponding holoenzymes were not susceptible to these reagents. The inactivation of the two apoenzymes by NEM followed pseudo-first order kinetics. Incubation of the apoenzymes with FAD completely prevented the inactivation by the organic sulfhydryl reagents. Methylmercury halides (iodide or chloride) inactivated both the apo and holo forms of medium-chain and long-chain acyl-CoA dehydrogenases. On the other hand, holo-short-chain acyl-CoA dehydrogenase behaved somewhat differently from the other two holoenzymes in that it was inactivated by pCMB (but not NEM or IAA) following a pseudo-first order process. The titration of the two apoenzymes with [14C]NEM and that of the holo-short-chain acyl-CoA dehydrogenase with [14C]pCMB indicated that all three acyl-CoA dehydrogenases contain a single essential cysteine residue/subunit. In the inactivation of holo-medium-chain and holo-long-chain acyl-CoA dehydrogenases with methylmercury halide, the same essential cysteine residue was modified without perturbing or releasing the enzyme-bound FAD. The inactivations of the three holoenzymes by appropriate organic sulfhydryl reagents were prevented by prior incubation with substrate. These experimental results indicate that the essential cysteine residue is located in the vicinity of the FAD- and substrate-binding sites within the active center of the enzymes. It appears, however, that this cysteine residue does not participate directly in FAD binding.     

The functional role of zinc in angiotensin converting enzyme: implications for the enzyme mechanism

Zinc is essential to the catalytic activity of angiotensin converting enzyme. The enzyme contains one g-atom of zinc per mole of protein. Chelating agents abolish activity by removing the metal ion to yield the inactive, metal-free apoenzyme. Zinc does not stabilize protein structure since the native and apoenzymes are equally susceptible to heat denaturation. Addition of either Zn2+, Co2+, or Mn2+ to the apoenzyme generates an active metalloenzyme; Fe2+, Ni2+, Cu2+, Cd2+, and Hg2+ fail to restore activity. The activities of the metalloenzymes follow the order Zn greater than Co greater than Mn. The protein binds Zn2+ more firmly than it does Co2+ or Mn2+. Hydrolysis of the chromophoric substrate, furanacryloyl-Phe-Gly-Gly, by the active metalloenzymes is subject to chloride activation; the activation constant is not metal dependent. Metal replacement mainly affects Kcat with very little change in Km, indicating that the role of zinc is to catalyze peptide hydrolysis.     

The role of zinc with special reference to the essential thiol groups in delta-aminolevulinic acid dehydratase of bovine liver.

delta-Aminolevulinic acid dehydratase (5-aminolevulinic acid hydro-lyase (adding 5-aminolevulinic acid and cyclizing), EC 4.2.1.24 purified from bovine liver in the presence of both SH-reducing reagent and zinc during the purification contained one zinc atom and eight SH groups/subunit. This preparation showed the full enzymatic activity even in the absence of thiol activator. It was found that two cysteine residues, one zinc atom and two histidine residues were involved in the active site. The enzyme was fullly active as long as two SH groups in the active site remained in the reduced form even in the absence of zinc. However, the enzymatic activity was completely lost, with a concomitant loss of bound zinc, upon oxidation of the SH groups to a disulfide bond, modification of SH groups with chemical reagents, or mercaptide formation by heavy metals. Thus, it is apparent that the activity depends on the essential SH groups. The zinc is not absolutely essential for the activity but may be required to prevent the essential SH groups from autooxidation by coordination. Binding experiments indicated that there was one binding site of zinc/subunit. Photooxidation of histidine residues diminished both enzymatic activity and bound zinc, suggesting that the histidine residues not only constituted the active site but also served as a possible ligand to zinc.     

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.     

Serratia Protease

Protease from a strain of Serratia contained one gram atom of zinc ion per mole and the zinc ion was essential for the activity. Also zinc-free apoenzyme was isolated as a crystalline form from the native-enzyme. Several metalloenzymes were prepared by the addition of corresponding metal ions to the apoenzyme. Studies on activities toward the hydrolysis of casein showed that relative activities of native- (zinc), cobalt- and manganese-enzyme were 1.0, 1.2 and 0.8, respectively. Toward the hydrolysis of hippurylleucinamide, however, specific activity of cobalt-enzyme was about 10 times that of the native- (zinc-) enzyme. Spectroscopic studies did not reveal any significant differences in conformations among native-enzyme, apoenzyme and the other metalloenzymes.