Substrate specificity and reaction mechanism of human glycoasparaginase. The N-glycosidic linkage of various glycoasparagines is cleaved through a reaction mechanism similar to L-asparaginase.

Human glycoasparaginase (N4-(beta-N-acetyl-D-glucosaminyl)-L-asparaginase, EC 3.5.1.26) hydrolyzes a series of compounds that contain L-asparagine residue with free alpha-amino and alpha-carboxyl groups. Substrates include high mannose and complex type glycoasparagines as well as those that lack the di-N-acetylchitobiose moiety, L-aspartic acid beta-methyl ester and L-aspartic acid beta-hydroxamate. The enzyme is inactive toward L-asparagine and L-glutamine and glycoasparagines containing substituted alpha-amino and/or alpha-carboxyl groups. In the presence of the acyl acceptor hydroxylamine, glycoasparaginase catalyzes the synthesis of L-aspartic acid beta-hydroxamate from aspartyl-glucosamine, L-aspartic acid beta-methyl ester, and L-aspartic acid. 13C NMR studies using 18O-labeled L-aspartic acid demonstrate that glycoasparaginase catalyzes an oxygen exchange between water and the carboxyl group at C-4 of L-aspartic acid. These results indicate that glycoasparaginase reacts as an exo-hydrolase toward the L-asparagine moiety of the substrates and the free alpha-amino and alpha-carboxyl groups are required for the enzyme reaction. The results are consistent with an L-asparaginase-like reaction pathway which involves a beta-aspartyl enzyme intermediate. Since glycoasparaginase is active toward a series of structurally different glycoasparagines, we suggest the revised systematic name of N4-(beta-glycosyl)-L-asparaginase for the enzyme.     

Reversal of enzyme regiospecificity with alternative substrates for aspartokinase I from Escherichia coli.

The substrate specificity of aspartokinase I has been examined by using both steady-state kinetic analyses and phosphorus-31 NMR spectroscopic studies. Analogues in which the alpha-amino group is either derivatized or replaced are not substrates or inhibitors for the enzyme, indicating the importance of the alpha-amino group as a binding determinant. The alpha-carboxyl group is not required for substrate recognition, and the alpha-amide or alpha-esters are competent alternative substrates. In addition, beta-derivatized structural analogues, such as the beta-hydroxamate, the beta-amide, or beta-esters, were found to be viable substrates. This was unexpected since the beta-carboxyl group is the usual site of phosphorylation. The nature of the acyl phosphate products obtained from these beta-derivatized alternative substrates has been characterized by coupled enzyme assays, oxygen-18-labeling studies, and phosphorus-31 NMR spectroscopy. These beta-derivatized analogues are capable of productive binding to aspartokinase through a reversal of regiospecificity to make the alpha-carboxyl group available as a phosphoryl acceptor. Many, but not all, of these alpha-acyl phosphates have also been shown to be viable substrates for the next two enzyme-catalyzed steps in this metabolic pathway. This raises the possibility of producing enzyme-generated alternative substrates that can serve as antimetabolites for the downstream reactions in this biosynthetic pathway.     

Inhibition and alternate substrate studies on the mechanism of carbapenam synthetase from Erwinia carotovora

The Erwinia carotorova carA, carB, and carC gene products are essential for the biosynthesis of (5R)-carbapen-2-em-3-carboxylic acid, the simplest carbapenem beta-lactam antibiotic. CarA (hereafter named carbapenam synthetase) has been proposed to catalyze formation of (3S,5S)-carbapenam-3-carboxylic acid from (2S,5S)-5-carboxymethyl proline based on characterization of the products of fermentation experiments in Escherichia coli cells transformed with pET24a/carB and pET24a/carAB, and on sequence homology to beta-lactam synthetase, an enzyme that catalyzes formation of a monocyclic beta-lactam ring with concomitant ATP hydrolysis. In this study, we have purified recombinant carbapenam synthetase and shown in vitro that it catalyzes the ATP-dependent formation of (3S,5S)-carbapenam-3-carboxylic acid from (2S,5S)-5-carboxymethyl proline. The kinetic mechanism is Bi-Ter where ATP is the first substrate to bind followed by (2S,5S)-5-carboxymethyl proline and PPi is the last product released based on initial velocity, product and dead-end inhibition studies. The reactions catalyzed by carbapenam synthetase with different diastereomers of the natural substrate and with alternate alpha-amino diacid substrates were studied by HPLC, ESI mass spectrometry, and steady-state kinetic analysis. On the basis of these results, we have proposed a role for each moiety of (2S,5S)-5-carboxymethyl proline for binding to the active site of carbapenam synthetase. Coupled enzyme assays of AMP and pyrophosphate release in the reactions catalyzed by carbapenam synthetase with adipic and glutaric acid, which lack the alpha-amino group, in the presence and absence of hydroxylamine support the formation of an acyladenylate intermediate in the catalytic cycle.     

Crystal structure of argininosuccinate synthetase from Thermus thermophilus HB8. Structural basis for the catalytic action

Argininosuccinate synthetase catalyzes the ATP-dependent condensation of a citrulline with an aspartate to give argininosuccinate. The three-dimensional structures of the enzyme from Thermus thermophilus HB8 in its free form, complexed with intact ATP, and complexed with an ATP analogue (adenylyl imidodiphosphate) and substrate analogues (arginine and succinate) have been determined at 2.3-, 2.3-, and 1.95-A resolution, respectively. The structure is essentially the same as that of the Escherichia coli argininosuccinate synthetase. The small domain has the same fold as that of a new family of "N-type" ATP pyrophosphatases with the P-loop specific for the pyrophosphate of ATP. However, the enzyme shows the P-loop specific for the gamma-phosphate of ATP. The structure of the complex form is quite similar to that of the native one, indicating that no conformational change occurs upon the binding of ATP and the substrate analogues. ATP and the substrate analogues are bound to the active site with their reaction sites close to one another and located in a geometrical orientation favorable to the catalytic action. The reaction mechanism so far proposed seems to be consistent with the locations of ATP and the substrate analogues. The reaction may proceed without the large conformational change of the enzyme proposed for the catalytic process.     

Crystal structure of glycerophosphodiester phosphodiesterase (GDPD) from Thermoanaerobacter tengcongensis, a metal ion-dependent enzyme: insight into the catalytic mechanism

Glycerophosphodiester phosphodiesterase (GDPD; EC 3.1.4.46) catalyzes the hydrolysis of a glycerophosphodiester to an alcohol and glycerol 3-phosphate in glycerol metabolism. It has an important role in the synthesis of a variety of products that participate in many biochemical pathways. We report the crystal structure of the Thermoanaerobacter tengcongensis GDPD (ttGDPD) at 1.91 A resolution, with a calcium ion and glycerol as a substrate mimic coordinated at this calcium ion (PDB entry 2pz0). The ttGDPD dimer with an intermolecular disulfide bridge and two hydrogen bonds is considered as the potential functional unit. We used site-directed mutagenesis to characterize ttGDPD as a metal ion-dependent enzyme, identified a cluster of residues involved in substrate binding and the catalytic reaction, and we propose a possible general acid-base catalytic mechanism for ttGDPD. Superposing the active site with the homologous structure GDPD from Agrobacterium tumefaciens (PDB entry 1zcc), which binds a sulfate ion in the active site, the sulfate ion can represent the phosphate moiety of the substrate, simulating the binding mode of the true substrate of GDPD.     

Studies on 3-deoxy-d-arabinoheptulosonate-7-phosphate synthetase(phe) from escherichia coli k12. 3. Structural studies.

1. Investigations with structural analogues of phenylalanine indicated an absolute requirement for the aromatic ring and both the alpha-carboxyl and alpha-amino groups of phenylalanine for inhibition of 3-deoxy-D-arabinoheptulosonate-7-phosphate synthetase(phe) activity. Replacement of the alpha-H atom with a methyl group does not decrease the inhibition greatly. Varying degrees of inhibition were observed with o, m and p mono-substituted fluoro, chloro and hydroxy phenylalanines. D-Phenylalanine and several metabolites of the aromatic biosynthetic pathways do not inhibit enzymic activity. 2. Circular dichroism studies indicated that the native enzyme possesses approximately 26% alpha-helix. Both circular dichroic and ultraviolet difference spectra indicated that the addition of phenylalanine to the synthetase induces a conformational change involving a small alteration of the secondary structure and large alterations in th interactions of some of the aromatic residues of the enzyme. In particular, a tryptophan residue moves from an extremly hydrophobic environment to one less hydrophobic. 3. Kd for the binding of phenylalanine to the enzyme was determined spectrophotometrically to be 75 muM. 4. Chemical modification studies suggested that a sulphydryl group and possibly a lysine residue may be implicated in the catalytic activity of the enzyme.     

The structure of pepsin. II. Structure of the enzyme active site (at 2 angstroms resolution)

Detailed structure of the pepsin active site in the region of the active aspartic acid residues and substrate binding S1 and S1' sites is considered. At the active site of the enzyme crystals studied several molecules of ethanol were detected, which interact with active groups. The catalytic properties of aspartyl proteinases towards dipeptide substrates were explained on the base of the specific structure of S1 and S1' binding sites.     

Structural and functional analyses of the human-type corrinoid adenosyltransferase (PduO) from Lactobacillus reuteri

ATP:Co(I)rrinoid adenosyltransferase (ACA) catalyzes the conversion of cobalamin to coenzyme B12, an essential cofactor in animal metabolism. Several mutations of conserved residues in the active site of human ACA have been identified in humans with methylmalonic aciduria. However, the catalytic role of these residues remains unclear. To better understand the function of these residues and to determine how the enzyme promotes catalysis, several variants of a human-type ACA from the lactic acid bacterium Lactobacillus reuteri (LrPduO) were kinetically and structurally characterized. Kinetic analyses of a series of alternate nucleotides were also performed. Substrate inhibition was observed at subsaturating concentrations of ATP, consistent with an ordered binding scheme where ATP is bound first by the enzyme. Modification or elimination of an active site, inter-subunit salt bridge resulted in a reduced "on" rate for ATP binding, with a less significant disruption in the rate of subsequent catalytic steps. Kinetic and structural data demonstrate that residue Arg132 is not involved in orienting ATP in the active site but, rather, it stabilizes the altered substrate in the transition state. Two functional groups of ATP explain the reduced ability of the enzyme to use alternate nucleotides: the amino group at the C-6 position of ATP contributes approximately 6 kcal/mol of free energy to ground state binding, and the nitrogen at the N-7 position assists in coordinating the magnesium ion in the active site. This study provides new insight into the role of substrate binding determinants and active site residues in the reaction catalyzed by a human-type ACA.     

Effect of myo-inositol(1,4,5)trisphosphate on the hydrolysis of phytic acid by phytase

Phytase is a monomeric enzyme of molecular mass 160 kDa which catalyzes the hydrolysis of phytic acid (D-myo inositol hexakisphosphate, InsP6) in a stepwise manner to myo-inositol. The enzyme-InsPn (n = 1-6) interaction at the catalytic site has a dissociation constant in the micro molar range. There also exists in the enzyme, a non-catalytic site specific for InsP3 with dissociation constant in the nano molar range. We have probed the effect of the high affinity InsP3 binding on the dissociation constant (Kd) of the phytase-InsP6 interaction and the kinetics of hydrolysis. These studies demonstrate the effect exerted by the high affinity InsP3 binding on the catalytic site of the enzyme.     

The catalytic site of Escherichia coli aspartate transcarbamylase: interaction between histidine 134 and the carbonyl group of the substrate carbamyl phosphate

Previous pKa determinations indicated that histidine 134, present in the catalytic site of aspartate transcarbamylase, might be the group involved in the binding of the substrate carbamyl phosphate and, possibly, in the catalytic efficiency of this enzyme. In the present work, this residue was replaced by an asparagine through site-directed mutagenesis. The results obtained show that histidine 134 is indeed the group of the enzyme whose deprotonation increases the affinity of the catalytic site for carbamyl phosphate. In the wild-type enzyme this group can be titrated only by those carbamyl phosphate analogues that bear the carbonyl group. In the modified enzyme the group whose deprotonation increases the catalytic efficiency is still present, indicating that this group is not the imidazole ring of histidine 134 (pKa = 6.3). In addition, the pKa of the still unknown group involved in aspartate binding is shifted by one unit in the mutant as compared to the wild type.     

N-(phenylacetyl)glycyl-D-aziridine-2-carboxylate, an acyclic amide substrate of beta-lactamases: importance of the shape of the substrate in beta-lactamase evolution

Certain acyclic depsipeptides, but not peptides, are substrates of typical beta-lactamases [Pratt, R.F., & Govardhan, C.P. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1302]. This may reflect either the greater chemical reactivity of depsipeptides (and of beta-lactams, the natural substrates) than peptides or the greater ease of distortion of the depsipeptide (ester) than the peptide (amide) group into a penicillin-like conformation. The latter explanation has been shown to be more likely by employment of a novel beta-lactamase substrate. N-(phenylacetyl)glycyl-D-aziridine-2-carboxylate, which combines a high chemical reactivity with a close to tetrahedral amide nitrogen atom. Although this substrate was better (higher kcat/KM) than a comparable depsipeptide for beta-lactamases, it was poorer than the depsipeptide for the Streptomyces R61 D-alanyl-D-alanine peptidase (which catalyzes specific peptide hydrolysis). It therefore seems likely that one vital feature of the putative evolution of a DD-peptidase into a beta-lactamase would have been modification of the active site to, on one hand, accommodate bicyclic beta-lactams and, on the other, exclude productive binding of planar acyclic amides. Certain serine beta-lactamases and the R61 DD-peptidase also catalyze methanolysis and aminolysis by D-phenylalanine of the N-acylaziridine. The latter reaction, the first amide aminolysis shown to be catalyzed by a beta-lactamase, is a very close analogue of the transpeptidase reaction of DD-peptidases. The methanolysis reaction appeared to proceed by way of the same acyl-enzyme intermediate as formed from depsipeptides possessing the same acyl moiety as the aziridine. The kinetics of methanolysis were employed to determine whether acylation or deacylation was rate limiting to the hydrolysis reaction under saturating substrate concentrations. The kinetics of the aminolysis reaction, catalyzed by the Enterobacter cloacae P99 beta-lactamase, showed the characteristics of, and were interpreted in terms of, a sequential mechanism previously deduced for depsipeptides and this enzyme [Pazhanisamy, S., & Pratt, R. F. (1989) Biochemistry 28, 6875-6882]. This mechanism features two separate binding sites, only one of which is productive. Strikingly, the binding of the N-acylaziridine to the nonproductive site was very tight, such that essentially all hydrolysis at substrate concentrations above 0.1Km proceeded via the ternary complex; this could also be true of penicillins.     

Covalent modification of the catalytic sites of the H(+)-ATPase from chloroplasts, CF(0)F(1), with 2-azido-[alpha-(32)P]ADP: modification of the catalytic site 2 (loose) and the catalytic site 3 (open) impairs multi-site, but not uni-site catalysis of both ATP synthesis and ATP hydrolysis

The H(+)-ATPase from chloroplasts, CF(0)F(1), was isolated and purified. The enzyme contained one endogenous ADP at a catalytic site, and two endogenous ATP at non-catalytic sites. Incubation with 2-azido-[alpha-(32)P]AD(T)P leads to a tight binding of the azido-nucleotides. Free nucleotides were removed by three consecutive passages through centrifugation columns, and after UV-irradiation, the label was covalently bound. The labelled enzyme was digested by trypsin, the peptides were separated by ion exchange chromatography into nitreno-AMP, nitreno-ADP and nitreno-ATP labelled peptides, and these were then separated by reversed phase chromatography. Amino acid sequence analysis was used to identify the type of the nucleotide binding site. After incubation with 2-azido-[alpha-(32)P]ADP, the covalently bound label was found exclusively at beta-Tyr-362, i.e. binding occurs only to catalytic sites. Incubation conditions with 2-azido-[alpha-(32)P]ADP were varied, and conditions were found which allow selective binding of the label to different catalytic sites, either to catalytic site 2 or to catalytic site 3. For measurements of the degree of inhibition by covalent modification, CF(0)F(1) was reconstituted into phosphatidylcholine liposomes, and the membranes were energised by an acid-base transition in the presence of a K(+)/valinomycin diffusion potential. The rate of ATP synthesis was 120 s(-1), and the rate of ATP hydrolysis was 20 s(-1), both measured under multi-site conditions. Covalent modification of either catalytic site 2 or catalytic site 3 inhibited both ATP synthesis and ATP hydrolysis, the degree of inhibition being proportional to the degree of modification. Extrapolation to complete inhibition indicates that modification of one catalytic site, either site 2 or site 3, is sufficient to completely block multi-site ATP synthesis and ATP hydrolysis. The rate of ATP synthesis and the rate of ATP hydrolysis were measured as a function of the substrate concentration from multi-site to uni-site conditions with covalently modified CF(0)F(1) and with non-modified CF(0)F(1). The result was that uni-site ATP synthesis and ATP hydrolysis were not inhibited by covalent modification of either catalytic site 2 or site 3. The results indicate cooperative interactions between catalytic nucleotide binding sites during multi-site catalysis, whereas neither uni-site ATP synthesis nor uni-site ATP hydrolysis require interaction with other sites.     

The role of alpha-amino group of the N-terminal serine of beta subunit for enzyme catalysis and autoproteolytic activation of glutaryl 7-aminocephalosporanic acid acylase

Glutaryl 7-aminocephalosporanic acid (GL-7-ACA) acylase of Pseudomonas sp. strain GK16 catalyzes the cleavage of the amide bond in the GL-7-ACA side chain to produce glutaric acid and 7-aminocephalosporanic acid (7-ACA). The active enzyme is an (alphabeta)(2) heterotetramer of two non-identical subunits that are cleaved autoproteolytically from an enzymatically inactive precursor polypeptide. In this study, we prepared and characterized a chemically modified enzyme, and also examined an effect of the modification on enzyme catalysis and autocatalytic processing of the enzyme precursor. We found that treatment of the enzyme with cyanate ion led to a significant loss of the enzyme activity. Structural and functional analyses of the modified enzyme showed that carbamylation of the free alpha-amino group of the N-terminal Ser-199 of the beta subunit resulted in the loss of the enzyme activity. The pH dependence of the kinetic parameters indicates that a single ionizing group is involved in enzyme catalysis with pK(a) = 6.0, which could be attributed to the alpha-amino group of the N-terminal Ser-199. The carbamylation also inhibited the secondary processing of the enzyme precursor, suggesting a possible role of the alpha-amino group for the reaction. Mutagenesis of the invariant N-terminal residue Ser-199 confirmed the key function of its side chain hydroxyl group in both enzyme catalysis and autoproteolytic activation. Partial activity and correct processing of a mutant S199T were in agreement with the general mechanism of N-terminal nucleophile hydrolases. Our results indicate that GL-7-ACA acylase utilizes as a nucleophile Ser-199 in both enzyme activity and autocatalytic processing and most importantly its own alpha-amino group of the Ser-199 as a general base catalyst for the activation of the hydroxyl group both in enzyme catalysis and in the secondary cleavage of the enzyme precursor. All of the data also imply that GL-7-ACA acylase is a member of a novel class of N-terminal nucleophile hydrolases that have a single catalytic center for enzyme catalysis.     

Interaction of monodispersed and micellar phospholipids with an Agkistrodon halys blomhoffii phospholipase A2, in which the alpha-amino group had been modified to an alpha-keto group

The pH dependence of the binding constant of Ca2+ to a phospholipase A2 of Agkistrodon halys blomhoffii, in which the alpha-amino group had been selectively modified to an alpha-keto group, was studied at 25 degrees C and ionic strength 0.1 by the tryptophyl fluorescence method. The dependence was compared with the results for the intact enzyme (Ikeda et al. (1981) J. Biochem. 90, 1125-1130). The pH-dependence curve could be well interpreted in terms of the participation of the two ionizable groups Asp 49 and His 48, with pK values of 4.70 and 6.69, respectively. These values were slightly different from the respective pK values for the intact enzyme, 5.15 and 6.45. Ca2+ binding to the intact enzyme involves the participation of an additional ionizable group with a pK value of 7.30, which was thus assigned as alpha-amino group. The pH dependence of the binding constant of monodispersed n-dodecylphosphorylcholine (n-C12PC) to the alpha-NH2-modified enzyme was studied at 25 degrees C and ionic strength 0.1 by the aromatic circular dichroism (CD) method. The pH-dependence curve for the modified apoenzyme was interpreted as reflecting the participation of a single ionizable group with a pK value of 4.7, which was assigned to Asp 49 (to which a Ca2+ ion can coordinate) since the curve for the Ca2+ complex lacked this transition: the binding constant was independent of pH. The pH-dependence curves for the intact apoenzyme and its Ca2+ complex involve the participation of an additional ionizable group with pK values of 7.30 and 6.30, respectively (Ikeda & Samejima (1981) J. Biochem. 90, 799-804), which was assigned as the alpha-amino group. The hydrolysis of monodispersed 1,2-dihexanoyl-sn-glycero-3-phosphorylcholine (diC6PC), catalyzed by the intact and the alpha-NH2-modified enzymes was studied by the pH stat method at 25 degrees C, pH 8.2, and ionic strength 0.1 in the presence of 3 mM Ca2+. The Km value for the modified enzyme was found to be very similar to that for the intact enzyme: this was compatible with the results of the direct binding study on the monodispersed n-C12PC under the same conditions. However, the kcat value was about 43% of the value for the intact enzyme, suggesting that the alpha-keto group introduced by the chemical modification perturbed the network of hydrogen bonds in the active site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Isomaltulose synthase (PalI) of Klebsiella sp. LX3. Crystal structure and implication of mechanism

Isomaltulose synthase from Klebsiella sp. LX3 (PalI, EC 5.4.99.11) catalyzes the isomerization of sucrose to produce isomaltulose (alpha-D-glucosylpyranosyl-1,6-D-fructofuranose) and trehalulose (alpha-D-glucosylpyranosyl-1,1-d-fructofuranose). The PalI structure, solved at 2.2-A resolution with an R-factor of 19.4% and Rfree of 24.2%, consists of three domains: an N-terminal catalytic (beta/alpha)8 domain, a subdomain between N beta 3 and N alpha 3, and a C-terminal domain having seven beta-strands. The active site architecture of PalI is identical to that of other glycoside hydrolase family 13 members, suggesting a similar mechanism in substrate binding and hydrolysis. However, a unique RLDRD motif in the proximity of the active site has been identified and shown biochemically to be responsible for sucrose isomerization. A two-step reaction mechanism for hydrolysis and isomerization, which occurs in the same pocket is proposed based on both the structural and biochemical data. Selected C-terminal truncations have been shown to reduce and even abolish the enzyme activity, consistent with the predicted role of the C-terminal residues in the maintenance of enzyme conformation and active site topology.     

Mechanism of the reaction catalyzed by isoaspartyl dipeptidase from Escherichia coli

Isoaspartyl dipeptidase (IAD) is a member of the amidohydrolase superfamily and catalyzes the hydrolytic cleavage of beta-aspartyl dipeptides. Structural studies of the wild-type enzyme have demonstrated that the active site consists of a binuclear metal center positioned at the C-terminal end of a (beta/alpha)(8)-barrel domain. Steady-state kinetic parameters for the hydrolysis of beta-aspartyl dipeptides were obtained at pH 8.1. The pH-rate profiles for the hydrolysis of beta-Asp-Leu were obtained for the Zn/Zn-, Co/Co-, Ni/Ni-, and Cd/Cd-substituted forms of IAD. Bell-shaped profiles were observed for k(cat) and k(cat)/K(m) as a function of pH for all four metal-substituted forms. The pK(a) of the group that must be unprotonated for catalytic activity varied according to the specific metal ion bound in the active site, whereas the pK(a) of the group that must be protonated for catalytic activity was relatively independent of the specific metal ion present. The identity of the group that must be unprotonated for catalytic activity was consistent with the hydroxide that bridges the two divalent cations of the binuclear metal center. The identity of the group that must be protonated for activity was consistent with the free alpha-amino group of the dipeptide substrate. Kinetic constants were obtained for the mutant enzymes at conserved residues Glu77, Tyr137, Arg169, Arg233, Asp285, and Ser289. The catalytic properties of the wild-type and mutant enzymes, coupled with the X-ray crystal structure of the D285N mutant complexed with beta-Asp-His, are consistent with a chemical reaction mechanism for the hydrolysis of dipeptides that is initiated by the polarization of the amide bond via complexation to the beta-metal ion of the binuclear metal center. Nucleophilic attack by the bridging hydroxide is facilitated by abstraction of its proton by the side chain carboxylate of Asp285. Collapse of the tetrahedral intermediate and cleavage of the carbon-nitrogen bond occur with donation of a proton from the protonated form of Asp285.     

Catalysis by dienelactone hydrolase: A variation on the protease mechanism

Dienelactone hydrolase (DLH), an enzyme from the β-ketoadipate pathway, catalyzes the hydrolysis of dienelactone to maleylacetate. Our inhibitor binding studies suggest that its substrate, dienelactone, is held in the active site by hydrophobic interactions around the lactone ring and by the ion pairs between its carboxylate and Arg-81 and Arg-206. Like the cysteine/serine proteases, DLH has a catalytic triad (Cys-123, His-202, Asp-171) and its mechanism probably involves the formation of covalently bound acyl intermediate via a tetrahedral intermediate. Unlike the proteases, DLH seems to protonate the incipient leaving group only after the collapse of the first tetrahedral intermediate, rendering DLH incapable of hydrolyzing amide analogues of its ester substrate. In addition, the triad His probably does not protonate the leaving group (enolate) or deprotonate the water for deacylation; rather, the enolate anion abstracts a proton from water and, in doing so, supplies the hydroxyl for deacylation. © 1993 Wiley-Liss, Inc.     

Examination of the mechanism of human brain aspartoacylase through the binding of an intermediate analogue

Canavan disease is a fatal neurological disorder caused by the malfunctioning of a single metabolic enzyme, aspartoacylase, that catalyzes the deacetylation of N-acetyl-L-aspartate to produce L-aspartate and acetate. The structure of human brain aspartoacylase has been determined in complex with a stable tetrahedral intermediate analogue, N-phosphonomethyl-L-aspartate. This potent inhibitor forms multiple interactions between each of its heteroatoms and the substrate binding groups arrayed within the active site. The binding of the catalytic intermediate analogue induces the conformational ordering of several substrate binding groups, thereby setting up the active site for catalysis. The highly ordered binding of this inhibitor has allowed assignments to be made for substrate binding groups and provides strong support for a carboxypeptidase-type mechanism for the hydrolysis of the amide bond of the substrate, N-acetyl- l-aspartate.     

Porcine liver aminopeptidase B. Substrate specificity and inhibition by amino acids

Porcine liver aminopeptidase B[EC 3.4.11.6] is highly specific for hydrolysis of beta-naphthylamides of basic L-amino acids; the Km values for L-arginine beta-naphthylamide and L-lysine beta-naphthylamide were 0.035 and 0.12 mM, respectively. The enzyme was inhibited by various alpha-amino acids. Among basic amino acids, L-homoarginine and L-arginine were the most potent inhibitors, L-lysine and L-norarginine (alpha-amino-gamma-guanidinobutyric acid) being less inhibitory. Hydrophobic amino acids also inhibited the enzyme competitively. This suggests that there is a hydrophobic region that binds the side chain of the substrates or inhibitors in the specificity site of the enzyme. Studies on the inhibitions by L-arginine derivatives showed that blocking of the alpha-carboxyl or the alpha-amino group reduced the inhibitory effect of L-arginine. Porcine liver aminopeptidase B was not inhibited by puromycin, whereas bestatin inhibited the enzyme competitively with a Ki value of 1.4 X 10(-8) M. This enzyme had no kinin-converting activity.     

Isomerization couples chemistry in the ATP sulfurylase-GTPase system.

ATP sulfurylase catalyzes and couples the free energies of two reactions: GTP hydrolysis and the synthesis of activated sulfate, or APS. The GTPase active site undergoes changes during its catalytic cycle that are driven by events that occur at the APS-forming active site, which is located in a separate subunit. GTP responds to its changing environment by moving along its reaction path. The response, which may change the affinity or reactivity of GTP, can, in turn, produce alterations at the APS active site that drive APS synthesis. The resulting stepwise progression of the two reactions couples their free energies. The mechanism of ATP sulfurylase involves an enzyme isomerization that precedes and rate limits cleavage of the beta,gamma-bond of GTP. These fluorescence studies demonstrate that the isomerization is controlled by the binding of activators that drive ATP sulfurylase into forms that mimic different stages of the APS reaction. Only certain activators elicit the isomerization, suggesting that the APS reaction must proceed to a specific point in the catalytic cycle before the conformational "switch" that controls GTP hydrolysis is thrown. The isomerization is shown to require occupancy of the gamma-phosphate subsite of the GTP binding pocket. This requirement establishes that the isomerization results in a change in the interaction between the enzyme and the gamma-phosphate of GTP that emerges in the catalytic cycle during the transition from the nonisomerized to the isomerized E.GTP complex. The newly formed contact(s) appears to carry into the bond-breaking transition state, and to be essential for the enhanced affinity and reactivity of the nucleotide.