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.     

Purification and characterization of human seminal plasma aminopeptidase

A 50.4-fold purification of aminopeptidase is achieved by alcohol precipitation, DEAE-cellulose, CM-cellulose and finally Sephadex G-200 chromatography. On polyacrylamide gel electrophoresis of the purified enzyme after molecular sieving on Sephadex G-200, only one band was obtained, suggesting that the enzyme preparation was obtained almost homogeneous by three steps of column chromatography. Aminopeptidase showed highest activity at pH 7.0, using a buffer system, of 70 mM Na-phosphate. The enzyme was found to be active at 40 degrees C, even at 60 degrees C (80% activity), suggesting that the human seminal plasma enzyme is fairly thermostable. Amongst the various aminoacyl derivatives evaluated as substrates in the present study, L-alanine beta-naphthylamide hydrochloride was found to have the highest rate of hydrolysis. Ovalbumin showed effective cleavage in comparison to that of other natural substrates. The Km value for the purified seminal plasma aminopeptidase towards L-alanine beta-naphthylamide hydrochloride was 4 x 10(-4) M. Hg+2 showed highest inhibitory effect than other metal ions tested in the present study. Concentration causing 50% inhibition of the enzyme (I50) by Hg2+ was 4.7 x 10(-6) M. Inhibition by EDTA at 1 mM concentration in the incubation system was higher than by EGTA and sodium azide, suggesting that the enzyme contains a metallo group at the active site. A 50% inhibition of the enzyme by EDTA was obtained at 5.11 x 10(-3) M. The Ackerman and Potter plot for EDTA inhibition suggests that EDTA is a reversible inhibitor of seminal plasma aminopeptidase. A single molecular form of aminopeptidase was found to be present in human seminal plasma as shown by polyacrylamide activity gel electrophoresis.     

Human-liver alanine aminopeptidase. A kinin-converting enzyme sensitive to beta-lactam antibiotics

Human liver alanine aminopeptidase (EC 3.4.11.14; L-alpha-aminoacyl-peptide hydrolase) catalyzes the stepwise hydrolysis of methionyl-lysyl-bradykinin to yield methionine, lysine, and the limit nonapeptide, bradykinin which is resistant to further hydrolytic cleavage by this enzyme. Alanine aminopeptidase also catalyzes the hydrolysis of various neutral amino acid beta-naphthylamides. This enzyme cleaves N-terminal arginyl residues unless the adjacent penultimate residue is proline as is the case for bradykinin. The properties are consistent with the requirements of a kinin converting enzyme. Human alanine aminopeptidase activity is reduced by several beta-lactam antibiotics, with the cloxacillin, oxacillin, and methicillin Ki values being 0.51 mM, 1.6 mM, and 2.4 mM respectively. Our experiments with radioactively labelled penicillin indicate that two moles of antibiotic are bound per mole of enzyme. Neither chromatography of the penicillin-treated enzyme on G-25 Sephadex, treatment of penicillin-G-treated enzyme with penicillinase, nor extensive dilution of cloxacillin-treated enzyme diminished the degree of inactivation produced. Inhibition was obtained with 6-aminopenicillanic acid, which indicated that the penicillin nucleus itself was being bound, but substitutions, as in cloxacillin, could enhance the binding.     

Characterization of the zinc binding site of bacterial phosphotriesterase.

The bacterial phosphotriesterase has been found to require a divalent cation for enzymatic activity. This enzyme catalyzes the detoxification of organophosphorus insecticides and nerve agents. In an Escherichia coli expression system significantly higher concentrations of active enzyme could be produced when 1.0 mM concentrations of Mn2+, Co2+, Ni2+, and Cd2+ were included in the growth medium. The isolated enzymes contained up to 2 equivalents of these metal ions as determined by atomic absorption spectroscopy. The catalytic activity of the various metal enzyme derivatives was lost upon incubation with EDTA, 1,10-phenanthroline, and 8-hydroxyquinoline-5-sulfonic acid. Protection against inactivation by metal chelation was afforded by the binding of competitive inhibitors, suggesting that at least one metal is at or near the active site. Apoenzyme was prepared by incubation of the phosphotriesterase with beta-mercaptoethanol and EDTA for 2 days. Full recovery of enzymatic activity could be obtained by incubation of the apoenzyme with 2 equivalents of Zn2+, Co2+, Ni2+, Cd2+, or Mn2+. The 113Cd NMR spectrum of enzyme containing 2 equivalents of 113Cd2+ showed two resonances at 120 and 215 ppm downfield from Cd(ClO4)2. The NMR data are consistent with nitrogen (histidine) and oxygen ligands to the metal centers.     

Interaction of gelonin with zinc

Gelonin, a plant protein which inactivates eukaryotic ribosomes, binds to zinc chelate Sepharose from which it is eluted with EDTA or histidine. After purification by metal chelate affinity chromatography, gelonin maintains the associated zinc-dependent proteinase activity previously described. In equilibrium dialysis about 4 moles of zinc bind per mole of gelonin with a dissociation constant of 0.96 mM. Ca2+ behaves as a mixed competitive and non-competitive inhibitor of the binding of zinc with Ki = 29 mM.     

Site-specific effects of zinc on the activity of family II pyrophosphatase

Family II pyrophosphatases (PPases), recently found in bacteria and archaebacteria, are Mn(2+)-containing metalloenzymes with two metal-binding subsites (M1 and M2) in the active site. These PPases can use a number of other divalent metal ions as the cofactor but are inactive with Zn(2+), which is known to be a good cofactor for family I PPases. We report here that the Mg(2+)-bound form of the family II PPase from Streptococcus gordonii is nearly instantly activated by incubation with equimolar Zn(2+), but the activity thereafter decays on a time scale of minutes. The activation of the Mn(2+)-form by Zn(2+) was slower but persisted for hours, whereas activation was not observed with the Ca(2+)- and apo-forms. The bound Zn(2+) could be removed from PPase by prolonged EDTA treatment, with a complete recovery of activity. On the basis of the effect of Zn(2+) on PPase dimerization, the Zn(2+) binding constant appeared to be as low as 10(-12) M for S. gordonii PPase. Similar effects of Zn(2+) and EDTA were observed with the Mg(2+)- and apo-forms of Streptococcus mutans and Bacillus subtilis PPases. The effects of Zn(2+) on the apo- and Mg(2+)-forms of HQ97 and DE15 B. subtilis PPase variants (modified M2 subsite) but not of HQ9 variant (modified M1 subsite) were similar to that for the Mn(2+)-form of wild-type PPase. These findings can be explained by assuming that (a) the PPase tightly binds Mg(2+) and Mn(2+) at the M2 subsite; (b) the activation of the corresponding holoenzymes by Zn(2+) results from its binding to the M1 subsite; and (c) the subsequent inactivation of Mg(2+)-PPase results from Zn(2+) migration to the M2 subsite. The inability of Zn(2+) to activate apo-PPase suggests that Zn(2+) binds more tightly to M2 than to M1, allowing direct binding to M2. Zn(2+) is thus an efficient cofactor at subsite M1 but not at subsite M2.     

Competitive inhibition of cathepsin C by guanidinium ions and reexamination of substrate inhibition

Cathepsin C, a lysosomal dipeptidyl aminopeptidase, is competitively and reversibly inhibited by guanidinium ions with a Ki approximately 1.5 mM. Loss of activity is not the result of conformational change, subunit dissociation or altered mobility of the enzyme, but rather reflects a specific binding of guanidinium ions to the active site. The finding that cathepsin C is not inhibited by substrate has allowed the kinetic parameters in the presence of guanidinium ion to be determined. Guanidinium significantly decreases the Km of substrate hydrolysis, without changing Vmax. In a novel application of the transferase reaction, the Km of the nucleophile substrate has been determined (11 mM) and found not to be affected by guanidinium, indicating its inhibition of substrate binding to the S, but not the S', site. Inhibition is suggested to be the result of shielding a negative charge on the enzyme important for interaction with the substrate.     

Modification of an arginine residue essential for the activity of NAD-malic enzyme from Ascaris suum

Purified NAD-malic enzyme from Ascaris suum is rapidly inactivated by the arginine reagent, 2,3-butanedione, and this inactivation is facilitated by 30 mM borate. Determination of the inactivation rate as a function of butanedione concentration suggests a second-order process overall, which is first order in butanedione. A second-order rate constant of 0.6 M-1 s-1 at pH 9 is obtained for the butanedione reaction. The inactivation is reversed by removal of the excess reagent upon dialysis. The enzyme is protected against inactivation by saturating amounts of malate in the presence and absence of borate. The divalent metal Mg2+ affords protection in the presence of borate but has no effect in its absence. The nucleotide reactant NAD+ has no effect on the inactivation rate in either the presence or absence of borate. A dissociation constant of 24 mM is obtained for E:malate from the decrease in the inactivation rate as a function of malate concentration. An apparent Ki of 0.5 mM is obtained for oxalate (an inhibitor competitive vs malate) from E:Mg:oxalate while no significant binding is observed for oxalate using the butanedione modified enzyme. The pH dependence of the first-order rate of inactivation by butanedione gives a pKa of 9.4 +/- 0.1 for the residue(s) modified, and this pK is increased when NAD is bound. The arginine(s) modified is implicated in the binding of malate.     

Purification and properties of human intestine alanine aminopeptidase

Human intestinal alanine aminopeptidase has been purified to greater than 90% homogeneity. The enzyme was released from mucosal cell membranes by Triton X-100 treatment. The native enzyme had a molecular weight of 206,000 in dilute buffer and 108,000 in the presence of sodium dodecyl sulfate. The enzyme was inhibited by chelators suggesting the presence of a metal ion in the enzyme. The most potent chelator inhibitor tested, o-phenanthroline, gave mixed kinetics (Ki = 67 micro M). Activity was restored by removal of the chelator. The enzyme was inhibited competitively by amino acids having hydrophobic side chains such as L-phenylalanine (Ki = 0.67 mM). Puromycin and methicillin also inhibited the enzyme in the competitive (Ki = 12.5 micro M) and noncompetitive (Ki = 4.6 mM) manner, respectively. Kinetic analysis of several amino acid beta-naphthylamides as substrates demonstrated the preference for substrates having hydrophobic or basic amino terminal residues with no beta-branching. L-Methionyl-beta-naphthylamide was the most tightly bound with L-alanyl-beta-naphthylamide was the most rapidly hydrolyzed.     

An arginine residue is essential for stretching and binding of the substrate on UDP-glucose-4-epimerase from Escherichia coli. Use of a stacked and quenched uridine nucleotide fluorophore as probe.

In the previous paper we demonstrated that uridine-5'-beta-1-(5-sulfonic acid) naphthylamidate (UDPAmNS) is a stacked and quenched fluorophore that shows severalfold enhancement of fluorescence in a stretched conformation. UDPAmNS was found to be a powerful competitive inhibitor (Ki = 0.2 mM) for UDP-glucose-4-epimerase from Escherichia coli. This active site-directed fluorophore assumed a stretched conformation on the enzyme surface, as was evidenced by full enhancement of fluorescence in saturating enzyme concentration. Complete displacement of the fluorophore by UDP suggested it to bind to the substrate binding site of the active site. Analysis of inactivation kinetics in presence of alpha,beta-diones such as phenylglyoxal, cyclohaxanedione, and 2,3-butadione suggested involvement of the essential arginine residue in the overall catalytic process. From spectral analysis, loss of activity could also be directly correlated with modification of only one arginine residue. Protection experiments with UDP showed the arginine residue to be located in the uridyl phosphate binding subsite. Unlike the native enzyme, the modified enzyme failed to show any enhancement of fluorescence with UDPAmNS clearly demonstrating the role of the essential arginine residue in stretching and binding of the substrate. The potential usefulness of such stacked and quenched nucleotide fluorophores has been discussed.     

Kinetics of inactivation of green crab (Scylla Serrata) alkaline phosphatase during removal of zinc ions by ethylenediaminetetraacetic acid disodium

Green crab (Scylla Serrata) alkaline phosphatase (EC 3.1.3.1.) is a metalloenzyme, the each active site in which contains a tight cluster of two zinc ions and one magnesium ion. The kinetic theory of the substrate reaction during irreversible inhibition of enzyme activity previously described by Tsou has been applied to a study on the kinetics of the course of inactivation of the enzyme by ethylenediaminetetraacetic acid disodium (EDTA). The kinetics of the substrate reaction with different concentrations of the substrate p-nitrophenyl phosphate (PNPP) and inactivator EDTA suggested a complexing mechanism for inactivation by, and substrate competition with, EDTA at the active site. The inactivation kinetics are single phasic, showing the initial formation of an enzyme-EDTA complex is a relatively rapid reaction, followed a slow inactivation step that probably involves a conformational change of the enzyme. Zinc ions are finally removed from the enzyme. The presence of metal ions apparently stabilizes an active-site conformation required for enzyme activity.     

C3 convertase of the alternative complement pathway. Demonstration of an active, stable C3b, Bb (Ni) complex

The purposes of this study were to demonstrate the C3 convertase complex, C3b, Bb (EC 3.4.21.47), of the alternative pathway of complement by ultracentrifugation and to determine whether the metal ion required for enzyme formation is present in the active enzyme complex. It has been shown previously that C3b,Bb formed with Ni2+ rather than Mg2+ exhibits enhanced stability. Using sucrose density gradient ultracentrifugation, an enzymatically active C3b,Bb(Ni) complex could be demonstrated which has a sedimentation coefficient of 10.7 S and which is stable in 10 mM EDTA. Upon formation of the enzyme with the radioisotope 63Ni2+, the ultracentrifugal distribution of the metal correlated with that of the enzyme complex. The molar ratio of Ni to C3b,Bb was 1:1. Displacement of Ni by Mg during formation of the enzyme indicated that both metals may bind to the same site in the enzyme. Binding of 63Ni to the catalytic site bearing fragment Bb was significantly stronger than its binding to C3b or to the zymogen, Factor B. It is proposed that there is one metal-binding site in the C3b,Bb enzyme which is not susceptible to chelation by EDTA and which is located in the Bb subunit.     

The slow, tight binding of bestatin and amastatin to aminopeptidases

Bestatin reversibly inhibits Aeromonas aminopeptidase (EC 3.4.11.10) in a process that is remarkable for its unusual degree of time dependence. The binding of bestatin by both Aeromonas aminopeptidase and cytosolic leucine aminopeptidase (EC 3.4.11.1) is slow and tight, with Ki values (determined from rate constants) of 1.8 X 10(-8) and 5.8 X 10(-10) M, respectively. In contrast, microsomal aminopeptidase (EC 3.4.11.2) binds bestatin in a rapidly reversible process with a Ki value of 1.4 X 10(-6) M. Kinetic analysis of the slow inhibition observed is facilitated by the use of a variety of experimental treatments, primarily measurements made during pre-equilibrium; however, careful selection of conditions permits use also of steady state observations. When titrated with bestatin, 1 mol of cytosolic leucine aminopeptidase (containing 6 g atoms each of zinc and manganese) is rendered 80% inactive by 1 mol of inhibitor, thus suggesting that enzymatic activity depends on one active site/hexamer; titration of Aeromonas aminopeptidase by bestatin reveals a 1:1 stoichiometry. Amastatin inhibits all three aminopeptidases through the mechanism of slow, tight binding with Ki values ranging from 3.0 X 10(-8) to 2.5 X 10(-10) M. This behavior of microsomal aminopeptidase contrasts sharply with its rapidly reversible inhibition by bestatin. The slow, tight binding observed with five of the six aminopeptidase-inhibitor pairs investigated suggests the formation of a transition state analog complex between the enzyme and inhibitor. Physical evidence consistent with this possibility was provided by the observation that both bestatin and amastatin perturb the absorption spectrum of cobalt Aeromonas aminopeptidase.     

Mechanism-based inactivation of 17 beta,20 alpha-hydroxysteroid dehydrogenase by an acetylenic secoestradiol

14,15-Secoestra-1,3,5(10)-trien-15-yne-3,17 beta-diol (1) is a mechanism-based inactivator of human placental 17 beta,20 alpha-hydroxysteroid dehydrogenase (estradiol dehydrogenase, EC 1.1.1.62). Inactivation with alcohol 1 requires NAD-dependent enzymic oxidation and follows approximately pseudo-first-order kinetics with a limiting t1/2 of 82 min and a "Ki" of 2.0 microM at pH 9.2 and 25 degrees C. At saturating concentrations of NAD, the initial rate of inactivation is slower than in the presence of 5 microM NAD, suggesting that cofactor binding to free enzyme impedes the inactivation process. Glutathione completely protects the enzyme from inactivation at both cofactor concentrations. Inactivation with 45 microM tritiated alcohol 1 followed by dialysis and gel filtration demonstrates a covalent interaction and affords an estimated stoichiometry of 1.4 molecules of steroid per subunit (2.8 per dimer). Chemically prepared 3-hydroxy-14,15-secoestra-1,3,5(10)-trien-15-yn-17-one (2) rapidly inactivates estradiol dehydrogenase with biphasic kinetics. From the latter phase, a Ki of 2.8 microM and a limiting t1/2 of 12 min at pH 9.2 were determined. Estradiol, NADH, and NAD all retard this latter inactivation phase. We propose that enzymatically generated ketone 2 inactivates estradiol dehydrogenase after its release from and return to the active site of free enzyme.     

Chloride as allosteric effector of yeast aminopeptidase I

Activation of yeast aminopeptidase I by chloride was studied by kinetic methods. Several effects contributed to overall activity enhancement: At low concentrations of Zn2+ (an essential component of aminopeptidase I) chloride increased the amounts of active enzyme by reducing the cooperativity of metal binding. In addition, substrate turnover was enhanced due to increased kcat and a moderate decrease of Km. At high concentrations of Zn2+ substrate saturation curves were sigmoidal. Under these conditions chloride activated by restoring Michaelis-Menten kinetics of substrate turnover. At the same time, reconstitution of active enzyme from apoprotein and Zn2+ was substantially accelerated and its inactivation due to loss of Zn2+ was retarded. Co2+-Substituted aminopeptidase I, although catalytically active, was much less sensitive to chloride activation. Apparent binding constants for chloride, as estimated from its effects on metal binding and catalysis, respectively, were different. This suggests that two independent activation mechanisms may be operative. Both appear to be mediated by conformational changes of the enzyme protein.     

Inactivation of rabbit muscle glyceraldehyde-3-phosphate dehydrogenase by koningic acid

Koningic acid, a sesquiterpene antibiotic, is a specific inhibitor of the enzyme glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate:NAD+ oxidoreductase (phosphorylating), EC 1.2.1.12). In the presence of 3 mM of NAD+, koningic acid irreversibly inactivated the enzyme in a time-dependent manner. The pseudo-first-order rate constant for inactivation (kapp) was dependent on koningic acid concentration in saturate manner, indicating koningic acid and enzyme formed a reversible complex prior to the formation of an inactive, irreversible complex; the inactivation rate (k 3) was 5.5.10(-2) s-1, with a dissociation constant for inactivation (Kinact) of 1.6 microM. The inhibition was competitive against glyceraldehyde 3-phosphate with a Ki of 1.1 microM, where the Km for glyceraldehyde 3-phosphate was 90 microM. Koningic acid inhibition was uncompetitive with respect to NAD+. The presence of NAD+ accelerated the inactivation. In its absence, the charcoal-treated NAD+-free enzyme showed a 220-fold decrease in apparent rate constant for inactivation, indicating that koningic acid sequentially binds to the enzyme next to NAD+. The enzyme, a tetramer, was inactivated when maximum two sulfhydryl groups, possibly cysteine residues at the active sites of the enzyme, were modified by the binding of koningic acid. These observations demonstrate that koningic acid is an active-site-directed inhibitor which reacts predominantly with the NAD+-enzyme complex.     

Reduced ferredoxin: CO2 oxidoreductase from Clostridium pasteurianum. Effect of ligands to transition metals on the activity and the stability of the enzyme.

Reduced ferredoxin: CO2 oxidoreductase (CO2-reductase) from Clostridium pasteurianum catalyzes the reduction of CO2 to formate at the expense of reduced ferredoxin, an isotopic exchange between CO2 and formate in the absence of ferredoxin, and the oxidation of formate to CO2 with oxidized ferredoxin. The three activities were found to be equally affected by monovalent anions known to be ligands to transition metals: The enzyme was reversibly inhibited by azide (Ki = 0.004mM), cyanate (Ki = 0.3 mM), thiocyanate (Ki = 1mM), nitrite (Ki = 0.4mM), nitrate (Ki = 6mM), chlorate (Ki = 3mM), fluoride (Ki = 5mM), and by chloride, bromide, iodide (Ki greater than 5mM). There was no observable effect of pH on the inhibition constants. The enzyme was not inhibited by carbon monoxide. The enzyme was irreversibly inactivated by low concentrations (10muM) of cyanide. The rate of inactivation increased with increasing pH with an inflection point near pH 9.5. Reduced ferredoxin and formate rather than oxidized ferredoxin or CO2 protected the enzyme from inactivation by cyanide. The enzyme was protected by azide and cyanate from inactivation. In the presence of high concentrations of the monovalent anions the rate of inactivation by heat (55 degrees C), by molecular oxygen, and by cyanide was decreased by a factor of more than 100. Half maximal protection was observed at the Ki concentrations of the two reversible inhibitors. The data are interpreted to indicate that a transition metal of weak "a class" character and a disulfide are catalytically significant groups of CO2-reductase from C. pasteurianum.     

Cosubstrate binding site of Pseudomonas sp. AK1 gamma-butyrobetaine hydroxylase. Interactions with structural analogs of alpha-ketoglutarate

Forty-one aromatic and aliphatic analogs of alpha-ketoglutarate were studied kinetically for their interaction with the alpha-ketoglutarate binding site of gamma-butyrobetaine hydroxylase obtained from Pseudomonas sp. AK1. Together, the compounds represent structural permutations probing the contribution of: 1) the C5 carboxyl group of alpha-ketoglutarate (domain I); 2) the C1-C2 keto acid moiety of alpha-ketoglutarate (domain II); 3) the distance between domains I and II; and 4) the spatial relationship of the two domains required for optimal interaction with the cosubstrate binding site. All compounds were competitive inhibitors for alpha-ketoglutarate (Km 0.018 mM). Functionally, two subsites of the cosubstrate binding site were evident: subsite I for polar interaction with the C5 carboxyl group, and subsite II, comprising of two distinct cis-oriented coordination sites of the catalytic ferrous ion which interact with the C1-C2 keto acid moiety. The most efficient inhibitors were pyridine 2,4-dicarboxylate (Ki 0.0002 mM) and 3,4-dihydroxybenzoate (Ki 0.0006 mM). Both compounds contain a carboxyl group and a chelating moiety corresponding to domains I and II of alpha-ketoglutarate, respectively. The fixed orientation of these groups in both analogs was used to assess intersubsite distance and spatial relationship required for optimal interaction with the cosubstrate binding site. Binding at subsite I and chelation at subsite II were indispensible for effective competitive inhibition. The distance between these two domains also helped determine whether attachment at the cosubstrate binding site would be catalytically productive. This was emphasized by the failure of either oxaloacetate or alpha-ketoadipinate to promote hydroxylation. Optimal interdomain distance, however, was not sufficient for cosubstrate utilization, as pyridine 2,4-dicarboxylate, with an interdomain distance identical to alpha-ketoglutarate in its staggered conformation, did not sustain hydroxylation. In the overall, these studies suggest that alpha-ketoglutarate utilization occurs in a ligand reaction at the active site ferrous ion of gamma-butyrobetaine hydroxylase. This is of particular interest since the delineated stereochemical mode of oxidative decarboxylation could generate the reactive oxo-iron species that was shown experimentally to promote gamma-butyrobetaine hydroxylation by an abstraction-recombination mechanism (Blanchard, J. S., and Englard, S. (1983) Biochemistry 22, 5922-5928; Englard, S., Blanchard, J. S., and Midelfort, C. F. (1985) Biochemistry 24, 1110-1116).     

A probe of the active site acidity of carboxypeptidase A

The substrate analogue 2-(1-carboxy-2-phenylethyl)-4-phenylazophenol is a potent competitive inhibitor of carboxypeptidase A. Upon ligation to the active site, the azophenol moiety undergoes a shift of pKa from a value of 8.76 to a value of 4.9; this provides an index of the Lewis acidity of the active site zinc ion. Examination of the pH dependence of Ki for the inhibitor shows maximum effectiveness in neutral solution (limiting Ki = 7.6 X 10(-7) M), with an increase in Ki in acid (pK1 = 6.16) and in alkaline solution (pK2 = 9.71, pK3 = 8.76). It is concluded that a proton-accepting enzymic functional group with the lower pKa (6.2) controls inhibitor binding, that ionization of this group is also manifested in the hydrolysis of peptide substrates (kcat/Km), and that the identity of this group is the water molecule that binds to the active site metal ion in the uncomplexed enzyme (H2OZn2+L3). Reverse protonation state inhibition is demonstrated, and conventional concepts regarding the mechanism of peptide hydrolysis by the enzyme are brought into question.     

Isolation of the leucine aminopeptidase gene from Aeromonas proteolytica. Evidence for an enzyme precursor.

The leucine aminopeptidase of Aeromonas proteolytica (EC 3.4.11.10) is a monomeric metalloenzyme having the capacity to bind two Zn2+ atoms in the active site. Structural information of this relatively small aminopeptidase that could illuminate the catalytic mechanism of the metal ions is lacking; hence, we have obtained sequences from the purified enzyme, cloned the corresponding gene, and expressed the recombinant protein in Escherichia coli. The deduced primary amino acid sequence of this secreted protease suggests a potential signal peptide at the NH2 terminus. Expression of the recombinant and native proteins in E. coli and in extracts of culture media of A. proteolytica indicates that the aminopeptidase is secreted as an active and thermosensitive 43-kDa protein that is rapidly transformed to thermostable forms of 30 and 32 kDa. Comparison of the deduced amino acid sequence of the A. proteolytica leucine aminopeptidase with other Zn(2+)-binding metalloenzymes failed to show homologies to the consensus binding sequence His-Glu-X-X-His for the metal ion.