Chemical mechanism of beta-xylosidase from Trichoderma reesei QM 9414: pH-dependence of kinetic parameters.

The variation of kinetic parameters of beta-xylosidase from Trichoderma reesei QM 9414 with pH was used to elucidate the chemical mechanism of the p-nitrophenyl beta-D-xylopyranoside hydrolysis. The pH-dependence of V and V/K(m) showed that a group on the enzyme with a pK value of 3.20 must be unprotonated and a group with a pK value of 5.20 must be protonated for activity and both are involved in catalysis. Solvent-perturbation studies indicated that these groups are neutral acid type. Temperature dependence of kinetic parameters suggested the stickiness of the substrate at lower temperatures than the optimum and the calculated ionization enthalpies pointed to carboxyl groups as responsible for both pKs. Chemical modification with triethyloxonium tetrafluoroborate and protection with the substrate studies demonstrated essential carboxyl groups on the enzyme. Profiles of pK(i) for D-gluconic acid lactone indicated that a group with a pK value of 3.45 must be protonated for binding and it has been assigned to the carboxyl group of D-gluconic acid formed by lactone ring breakdown in solution.     

Ionic properties of an essential histidine residue in pig heart lactate dehydrogenase

1. Pig heart lactate dehydrogenase is inhibited by addition of one equivalent of diethyl pyrocarbonate. The inhibition is due to the acylation of a unique histidine residue which is 10-fold more reactive than free histidine. No other amino acid side chains are modified. 2. The carbethoxyhistidine residue slowly decomposes and the enzyme activity reappears. 3. The essential histidine residue is only slightly protected by the presence of NADH but is completely protected when substrate and substrate analogues bind to the enzyme-NADH complex. The protection is interpreted in terms of a model in which substrates can only bind to the enzyme in which the histidine residue is protonated and is thus not available for reaction with the acylating agent. 4. The apparent pK(a) of the histidine residue in the apoenzyme is 6.8+/-0.2. In the enzyme-NADH complex it is 6.7+/-0.2. 5. Acylated enzyme binds NADH with unchanged affinity. The enzyme is inhibited because substrates and substrate analogues cannot bind at the acylated histidine residue in the enzyme-NADH complex.     

The pH-dependence of the binding of dihydrofolate and substrate analogues to dihydrofolate reductase from Escherichia coli

The interaction of dihydrofolate reductase (EC 1.5.1.3) from Escherichia coli with dihydrofolate and folate analogues has been studied by means of binding and spectroscopic experiments. The aim of the investigation was to determine the number and identity of the binary complexes that can form, as well as pKa values for groups on the ligand and enzyme that are involved with complex formation. The results obtained by ultraviolet difference spectroscopy indicate that, when bound to the enzyme, methotrexate and 2,4-diamino-6,7-dimethylpteridine exist in their protonated forms and exhibit pKa values for their N-1 nitrogens of above 10.0. These values are about five pH units higher than those for the compounds in free solution. The binding data suggest that both folate analogues interact with the enzyme to yield a protonated complex which may be formed by reaction of ionized enzyme with protonated ligand and/or protonated enzyme with unprotonated ligand. The protonated complex formed with 2,4-diamino-6,7-dimethylpteridine can undergo further protonation to form a protonated enzyme-protonated ligand complex, while that formed with methotrexate can ionize to give an unprotonated complex. A group on the enzyme with a pKa value of about 6.3 is involved with the interactions. However, the ionization state of this group has little effect on the binding of dihydrofolate to the enzyme. For the formation of an enzyme-dihydrofolate complex it is essential that the N-3/C-4 amide of the pteridine ring of the substrate be in its neutral form. It appears that dihydrofolate is not protonated in the binary complex.     

Kinetic studies of L-aspartase from Escherichia coli: pH-dependent activity changes

The pH dependence of the kinetic parameters of the L-aspartase-catalyzed reaction have been examined in both the amination and the deamination directions. The enzyme isolated from Escherichia coli exists in a pH-dependent equilibrium between a higher pH form that has an absolute requirement for a divalent metal ion and for substrate activation, and a low pH form that does not require activation by either substrate or metal ions. The interconversion between these enzyme forms is observed near neutral pH in the profiles examined for the reaction in either direction. This pH-dependent activation has not been observed for other bacterial aspartases. Loss of activity is observed at high pH with a pK value of 9. The pH profiles of competitive inhibitors such as 3-nitropropionic acid and succinic acid have shown that the enzyme group responsible for this activity loss must be protonated for substrate binding at the active site. An enzymatic group has also been identified that must be protonated in the amination reaction, with a pK value near 6.5, and deprotonated in the deamination reaction. This group, tentatively assigned as a histidyl residue, fulfills the criteria for the acid-base catalyst at the active site of L-aspartase.     

Kinetic models for the action of cytosolic and mitochondrial inorganic pyrophosphatases of rat liver

Initial rates of PPi hydrolysis by cytosolic and mitochondrial inorganic pyrophosphatases of rat liver have been measured in the presence of 0.2-100 microM MgPPi and 0.01-50 mM Mg2+ at pH 7.2 to 9.3. The apparently simplest model consistent with the data for both enzymes implies that they bind substrate, in the form of MgPPi, and three Mg2+ ions, of which two are absolutely required for activity. The third metal ion facilitates substrate binding but decreases maximal velocity for the cytosolic enzyme, while substrate binding is only modulated for the mitochondrial enzyme. The model is also applicable to bovine heart mitochondrial pyrophosphatases. The active form of the substrate for the cytosolic pyrophosphatase is MgP2O7(-2); the catalytic and metal-binding steps require a protonated group with pKa = 9.2 and an unprotonated group with pKa = 8.8, respectively. The results indicate that the mitochondrial pyrophosphatase is more sensitive to variations of Mg2+ concentration in rat liver cells than is the cytosolic one.     

Isolation and characterization of NADP+-linked isocitrate dehydrogenase of germinating pea seeds (Pisum sativum)

NADP+-linked isocitrate dehydrogenase (E.C.1.1.1.42) has been purified to homogeneity from germinating pea seeds. The enzyme is a tetrameric protein (mol wt, about 146,000) made up of apparently identical monomers (subunit mol wt, about 36,000). Thermal inactivation of purified enzyme at 45 degrees and 50 degrees C shows simple first order kinetics. The enzyme shows optimum activity at pH range 7.5-8. Effect of substrate [S] on enzyme activity at different pH (6.5-8) suggests that the proton behaves formally as an "uncompetitive inhibitor". A basic group of the enzyme (site) is protonated in this pH range in the presence of substrate only, with a pKa equal to 6.78. On successive dialysis against EDTA and phosphate buffer, pH 7.8 at 0 degrees C, yields an enzymatically inactive protein showing kinetics of thermal inactivation identical to the untreated (native) enzyme. Maximum enzyme activity is observed in presence of Mn2+ and Mg2+ ions (3.75 mM). Addition of Zn2+, Cd2+, Co2+ and Ca2+ ions brings about partial recovery. Other metal ions Fe2+, Cu2+ and Ni2+ are ineffective.     

Inhibition of the recBC enzyme of Escherichia coli by specific binding of pyridoxal 5'-phosphate to DNA binding site.

Pyridoxal 5'-phosphate rapidly abolished the DNA-hydrolyzing activities as well as DNA-dependent ATP-ase activity of the recBC enzyme of Escherichia coli. Pyridoxal also had an inhibitory effect on the enzyme but less effective than that of pyridoxal 5'-phosphate. Pyridoxamine 5'-phosphate, pyridoxamine, or pyridoxine had no effect on the activities of the enzyme. The inhibition was rapidly reversed by dilution but could be made irreversible by reduction with sodium borohydride prior to dilution. This suggests the formation of Schiff base between pyridoxal 5'-phosphate and an epsilon-amino group of a lysine residue which is essential for the enzyme activity. Pyridoxal 5'-phosphate is a competitive inhibitor of DNA substrate but not of ATP. Furthermore, the presence of DNA substrate protected the enzyme from inactivation by the reduction but the presence of ATP showed no effect. Thus, the recBC enzyme appears to have an essential lysine residue at or near the DNA binding site of the enzyme, and the enzyme possesses two independent catalytic sites, such as a DNA binding site and an ATP binding site.     

The hepatic adenylate cyclase system. II. Substrate binding and utilization and the effects of magnesium ion and pH.

The kinetic characteristics of substrate utilization by hepatic adenylate cyclase were investigated under a variety of incubation conditions, including veriations in pH, [substrate], [Mg2+], and in the absence or presence of glucagon. Activities were compared with ATP and 5'-adenylylimidodiphosphate (App(NH)p) as substrates. The Km for both substrates was about 50 muM; Vmax given with App(NH)p was about 40% lower than obtained with ATP as substrate. In the presence of a saturating concentration of substrate (1 mM), basal activity was increased 4-fold by increasing [Mg2+] from 5 to 50 mM. The stimulatory effect of Mg2+ was not due to an allosteric action since basal activity was only marginally enhanced (40%) when the substrate concentration was reduced to 10 muM. As suggested by deHaen ((1974 J. Biol. Chem. 249, 2756), it is likely that Mg2+ increases enzyme activity by decreasing the concentration of an inhibitory, unchelated form of substrate that competes with the productive magnesium-substrate complex at the active site. Activity-pH profiles differed with ATP and App(NH)p as substrates; a shift in pH optimum was observed which correlated with the different pKa of the terminal phosphate groups of ATP and App(nh)p, and which reflect the concentration of protonated substrate (ATPH-3 minus) present in the incubation medium. Accordingly, protonated substrate is the predominant inhibitory species of unchelated substrate and probably has a considerably higher affinity for the active site than does the magnesium-substrate complex. Glucagon-stimulated activity was less susceptible to inhibition by protonated substrate than is the basal state as evidenced by lower stimulatory effect when the [Mg2+] was increased from 5 to 20 mM. However, increasing the [Mg2+] from 20 to 50 mM resulted in marked inhibition of glucagon-stimulated activity, particularly in the presence of 10 muM substrate. Conversely, at a fixed [Mg2+], concentrations of substrate at least 20-fold higher than the Km were required to achieve maximal hormone-stimulated activity. These findings suggest that the unchelated, fully ionized form of substrate serves as an activating ligand, as has been observed with guanine nucleotides at considerably lower concentrations. Thus, Mg2+ affects adenylate cyclase activity by forming the productive substrate complex and by titrating the inhibitory protonated and activating free forms of substrate. As a result of these effects of unchelated substrate, it proved difficult to evaluate the kinetic parameters involved in substrate binding and utilization and the effects of hormone thereon when substrate was added as the only source of activating ligand. However, linear Michaelis kinetic data were obtained by adding the activating ligand 5'-guanylylimidodiphosphate with glucagon and by making appropriate adjustments of pH and [Mg2+]. Vmax was increased 4-fold without changes in Km by the actions of 5'-guanylylimidodiphosphate and glucagon.     

Kinetics of modification of the mitochondrial succinate-ubiquinone reductase by 5,5′-dithiobis-(2-nitro-benzoic acid)

The kinetic theory of the substrate reaction during modification of enzyme activity previously described by Tsou [Tsou (1988),Adv. Enzymol. Relat. Areas Mol. Biol. 61, 381–436] has been applied to a study of the kinetics of the course of inactivation of the mitochondrial succinate-ubiquinone reductase by 5,5′-dithiobis-(2-nitro-benzoic acid) (DTNB). The results show that the inactivation of this enzyme by DTNB is a conformation-change-type inhibition which involves a conformational change of the enzyme before inactivation. The microscopic rate constants were determined for the reaction of the inactivator with the enzyme. The presence of the substrate provides marked protection of this enzyme against inactivation by DTNB. The modification reaction of the enzyme using DTNB was shown to follow a triphasic course by following the absorption at 412 nm. Among these reactive thiol groups, the fast-reaction thiol group is essential for the enzyme activity. The results suggest that the essential thiol group is situated at the succinate-binding site of the mitochondrial succinate-ubiquinone reductase.     

Interaction between the carboxyl groups of Asp127 and Asp129 in the active site of Escherichia coli phosphofructokinase.

The pH dependence of the enzymic properties of the phosphofructokinase from Escherichia coli was compared to those of two mutants in which one carboxyl group of the active site has been removed from either Asp127 or Asp129. All measurements of activity were made in the presence of allosteric activator ADP or GDP to eliminate any cooperative process. Asp129 is a crucial residue for the activity of phosphofructokinase since its conversion to Ser decreases the catalytic activity by 2-3 orders of magnitude in both the forward and reverse reactions, but the ionization of Asp129 is not directly related the pH dependence of phosphofructokinase activity. This pH dependence is however modified by the Asp129----Ser mutation, which decreases the pK of another residue, Asp127, by as much as pH of 1.5. The side chain of Asp127 has the catalytic role proposed earlier: its deprotonated form acts as a base in the forward reaction, and its protonated form acts as an acid in the reverse reaction. The protonated form of Asp127 is also required for the binding of fructose 1,6-bisphosphate. The electrostatic interaction between the carboxyl groups of Asp127 and Asp129 seems different in free phosphofructokinase to that in enzyme/substrate complexes, suggesting that a conformational change occurs upon substrate binding. The pH dependence of phosphofructokinase activity involves one other ionizable group with a pK of approximately 6 which does not belong to the side chains of Asp127 or Asp129.     

Characterization of the PLP-dependent aminotransferase NikK from Streptomyces tendae and its putative role in nikkomycin biosynthesis

As inhibitors of chitin synthase, nikkomycins have attracted interest as potential antibiotics. The biosynthetic pathway to these peptide nucleosides in Streptomyces tendae is only partially known. In order to elucidate the last step of the biosynthesis of the aminohexuronic building block, we have heterologously expressed a predicted aminotransferase encoded by the gene nikK from S. tendae in Escherichia coli. The purified protein, which is essential for nikkomycin biosynthesis, has a pyridoxal-5'-phosphate cofactor bound as a Schiff base to lysine 221. The enzyme possesses aminotransferase activity and uses several standard amino acids as amino group donors with a preference for glutamate (Glu > Phe > Trp > Ala > His > Met > Leu). Therefore, we propose that NikK catalyses the introduction of the amino group into the ketohexuronic acid precursor of nikkomycins. At neutral pH, the UV-visible absorbance spectrum of NikK has two absorbance maxima at 357 and 425 nm indicative of the presence of the deprotonated and protonated aldimine with an estimated pK(a) of 8.3. The rate of donor substrate deamination is faster at higher pH, indicating that an alkaline environment favours the deamination reaction.     

Irreversible kinetics of β-N-acetyl-d-glucosaminidase from prawn (Penaeus vannamei) inactivated by mercuric ion

Cysteine residues in prawn (Penaeus vannamei) β-N-acetyl-d-glucosaminidase (NAGase, EC 3.2.1.52) have been modified by p-chloromercuribenzoate (PCMB). The results show that sulfhydryl group is essential for the activity of the enzyme. Inactivation kinetics of the enzyme by mercuric chloride (HgCl₂) has been studied using the kinetic method of the substrate reaction during inactivation of enzyme previously described by Tsou. The kinetic results show that the inactivation of the enzyme is an irreversible reaction. The microscopic rate constants for the reaction of Hg²⁺ with free enzyme and with the enzyme-substrate complex are determined. Comparison of these rate constants indicates that the presence of substrate offers marked protection of this enzyme against inactivation by Hg²⁺. The above results suggest that the cysteine residue is essential for activity.     

The role of amino acid residues in the active site of a midgut microvillar aminopeptidase from the beetle Tenebrio molitor

Aminopeptidases are major enzymes in the midgut microvillar membranes of most insects and are targets of insecticidal Bacillus thuringiensis crystal delta-endotoxins. Sequence analysis and substrate specificity studies showed that these enzymes resemble mammalian aminopeptidase N, although information on the organization of their active site is lacking. The effect of pH at different temperatures on the kinetic parameters of Tenebrio molitor (Coleoptera) larval aminopeptidase showed that enzyme catalysis depend on a deprotonated (pK 7.6; DeltaH degrees (ion), 7.6 kJ/mol) and a protonated (pK 8.2; DeltaH degrees (ion), 16.8 kJ/mol) group. 1-Ethyl-3-(3-dimethylaminopropyl) carbodiimide and diethylpyrocarbonate inactivate the enzyme by modifying a pK 5.8 carboxylate and a imidazole group, respectively, with a reaction order around 1. Tetranitromethane changes the K(m) of the enzyme without affecting its V(max) by modifying a phenol group. The presence of a competitive inhibitor decrease the inactivation reaction rates in all these cases. EDTA inactivation of the aminopeptidase is affected by pH and temperature suggesting the involvement in metal binding of at least one deprotonated imidazole group (pK 5.8, DeltaH degrees (ion), 20 kJ/mol). The data support the hypothesis that T. molitor aminopeptidase catalysis depends on a catalytic metal and on a carboxylate and a protonated imidazole group, whereas substrate binding relies in one phenol and one carboxylate groups. The insect aminopeptidase shares common features with mammalian aminopeptidase N, although differing in details of substrate binding and in residues directly involved in catalysis.     

Effects of di-isopropyl phosphorofluoridate on rat liver microsomal and lysosomal beta-glucuronidase

N-Bromosuccinimide completely inactivated the cellulase, and titration experiments showed that oxidation of one tryptophan residue per cellulase molecule coincided with 100% inactivation. CM-cellulose protected the enzyme from inactivation by N-bromosuccinimide. The cellulase was inhibited by active benzyl halides, and reaction with 2-hydroxy-5-nitrobenzyl bromide resulted in the incorporation of 2.3 hydroxy-5-nitrobenzyl groups per enzyme molecule; one tryptophan residue was shown to be essential for activity. Diazocarbonyl compounds in the presence of Cu2+ ions inhibited the enzyme. The pH-dependence of inactivation was consistent with the reaction occurring with a protonated carboxyl group. Carbodi-imide inhibited the cellulase, and kinetic analysis indicated that there was an average of 1 mol of carbodi-imide binding to the cellulase during inactivation. Treatment of the cellulase with diethyl pyrocarbonate resulted in the modification of two out of the four histidine residues present in the cellulase. The modified enzyme retained 40% of its original activity. Inhibition of cellulase activity by the metal ions Ag+ and Hg2+ was ascribed to interaction with tryptophan residues, rather than with thiol groups.     

The active site sulfhydryl of aconitase is not required for catalytic activity

Previous reports have demonstrated that aconitase has a single reactive sulfhydryl at or near the active site (Johnson, P. G., Waheed, A., Jones, L., Glaid, A. J., and Gawron, O. (1977) Biochem. Biophys. Res. Commun. 74, 384-389). On the basis of experiments with phenacyl bromide in which enzyme activity was abolished while substrate afforded protection, it was concluded that this group was an essential sulfhydryl. We have further examined the reactivity of this group and confirmed the result that, when reagents with bulky groups (e.g. N-ethylmaleimide or phenacyl bromide) modify the protein at the reactive sulfhydryl, activity is lost. However, when smaller groups, e.g. the SCH3 from methylmethanethiosulfonate or the CH2CONH2 from iodoacetamide, are introduced, there is only partial (50%) or no loss of activity. Experiments were performed to obtain evidence that these reagents are modifying the same residue. Methylmethanethio-sulfonate-treated enzyme showed an increase in the Km for citrate from 200 to 330 microM. EPR spectra were taken of the reduced N-ethylmaleimide- and iodoacetamide-modified enzyme in the presence of substrate. The former gave a spectrum typical of the substrate-free enzyme, while the spectrum of the latter was identical to enzyme with bound substrate. We, therefore, conclude that modification of this sulfhydryl affects activity by interfering with the binding of substrate to the active site and is not essential in the catalytic process.     

Interaction of pantetheinase with sulfhydryl reagents and disulfides

The effect of many thiol reagents and disulfides on pantetheinase (E.C. 3.5.1.-; pantetheine hydrolase) was studied in the presence or absence of S-pantetheine-3-pyruvate as substrate. Iodoacetamide, iodoacetate, bromopyruvate and N-ethylmaleimide irreversibly inactivate the enzyme at very different rates. Inactivation constants, corrected for the different reactivity of halogeno derivatives with non-protein thiols, suggest the presence of an essential sulfhydryl group in the enzyme and a negatively charged environment near this group. p-Chloromercuribenzoate is the most effective inhibitor; 2-nitro-5-thiocyanobenzoate, o-iodosobenzoate and hydrogen peroxide give a biphasic inhibition pattern, indicating the existence of two sulfhydryl groups whose modification affects activity. Organic arsenicals decrease activity to about 50%. Neutral and positively charged disulfides are effective inhibitors. Substrate protects the enzyme from inactivation, except in the case of negatively charged disulfides, where the presence of substrate enhances the inhibitory effect. Titration with Ellman's reagent or 4,4'-dithiodipyridine under various experimental conditions demonstrated the existence of two sulfhydryls and three disulfides in the fully active enzyme. Pantetheinase may become inactive during purification with concomitant loss of one titrable sulfhydryl group.     

Studies of the mechanism of glutamine synthetase utilizing pH-dependent behavior in catalysis and binding

The pKa values of enzyme groups of Escherichia coli glutamine synthetase which affect catalysis and/or substrate binding were determined by measuring the pH dependence of Vmax and V/K. Analysis of these data revealed that two enzyme groups are required for catalysis with apparent pKa values of approximately 7.1 and 8.2. The binding of ATP is essentially independent of pH in the range studied while the substrate ammonia must be deprotonated for the catalytic reaction. Using methylamine and hydroxylamine in place of ammonia, the pKa value of the deprotonated amine substrate as expressed in the V/K profiles was shifted to a lower pKa value for hydroxylamine and a higher pKa value for methylamine. These data indicate that the amine substrate must be deprotonated for binding. Hydroxylamine is at least as good a substrate as ammonia judged by the kinetic parameters whereas methylamine is a poor substrate as expressed in both the V and V/K values. Glutamate binding was determined by monitoring fluorescence changes of the enzyme and the data indicate that a protonated residue (pKa = 8.3 +/- 0.2) is required for glutamate binding. Chemical modification by reductive methylation with HCHO indicated that the group involved in glutamate binding most likely is a lysine residue. In addition, the Ki value for the transition state analog, L-3-amino-3-carboxy-propanesulfonamide was measured as a function of pH and the results indicate that an enzyme residue must be protonated (pKa = 8.2 +/- 0.1) to assist in binding. A mechanism for the reaction catalyzed by glutamine synthetase is proposed from the kinetic data acquired herein. A salt bridge is formed between the gamma-phosphate group of ATP and an enzyme group prior to attack by the gamma-carboxyl of glutamate on ATP to form gamma-glutamyl phosphate. The amine substrate subsequently attacks gamma-glutamyl phosphate resulting in formation of the tetrahedral adduct before phosphate release. A base on the enzyme assists in the deprotonation of ammonia during its attack on gamma-glutamyl phosphate or after the protonated carbinol amine is formed. Based on the kinetic data with the three amine substrates, catalysis is not rate-limiting through the pH range 6-9.     

Structure of a Michaelis complex analogue: propionate binds in the substrate carboxylate site of alanine racemase

The structure of alanine racemase from Bacillus stearothermophilus with the inhibitor propionate bound in the active site was determined by X-ray crystallography to a resolution of 1.9 A. The enzyme is a homodimer in solution and crystallizes with a dimer in the asymmetric unit. Both active sites contain a pyridoxal 5'-phosphate (PLP) molecule in aldimine linkage to Lys39 as a protonated Schiff base, and the pH-independence of UV-visible absorption spectra suggests that the protonated PLP-Lys39 Schiff base is the reactive form of the enzyme. The carboxylate group of propionate bound in the active site makes numerous interactions with active-site residues, defining the substrate binding site of the enzyme. The propionate-bound structure therefore approximates features of the Michaelis complex formed between alanine racemase and its amino acid substrate. The structure also provides evidence for the existence of a carbamate formed on the side-chain amino group of Lys129, stabilized by interactions with one of the residues interacting with the carboxylate group of propionate, Arg136. We propose that this novel interaction influences both substrate binding and catalysis by precisely positioning Arg136 and modulating its charge.     

Purification, properties and induction of a specific benzoate-4-hydroxylase from Aspergillus niger (UBC 814).

An inducible benzoate-4-hydroxylase has been partially purified from crude extracts of the mycelial felts of Aspergillus niger. This enzyme catalyzes the transformation of benzoate to p-hydroxybenzoate with equimolar consumption of NADPH and O2. It requires tetrahydropteridine as a prosthetic group. The optimum activity was found at pH 6.2 with a Km value at 30 degrees C of 1.6-10-minus 4 for NADPH and 1.3-10-minus 4 M for benzoate. Fe-2+ (iron) is required for the enzyme activity. The enzyme is stabilized by the inclusion of benzoate, EDTA and glutathione in the extracting buffer. The enzyme is specific for benzoate as substrate. Sulfhydryl groups(s) are essential for enzyme activity as indicated by p-chloromercuri-benzoate and N-ethylmaleimide inactivation. Benzoate-4-hydroxylase activity is decreased in the mycelial felts of Aspergillus niger grown in the presence of higher concentrations of benzoate. Maximum activity of the enzyme was observed at 36 h after inoculation.