Reactivity of asparagine residue at the active site of the D105N mutant of fluoroacetate dehalogenase from Moraxella sp. B

Fluoroacetate dehalogenase from Moraxella sp. B (FAc-DEX) catalyzes cleavage of the carbon–fluorine bond of fluoroacetate, whose dissociation energy is among the highest found in natural products. Asp105 functions as the catalytic nucleophile that attacks the α-carbon atom of the substrate to displace the fluorine atom. In spite of the essential role of Asp105, we found that site-directed mutagenesis to replace Asp105 by Asn does not result in total inactivation of the enzyme. The activity of the mutant enzyme increased in a time- and temperature-dependent manner. We analyzed the enzyme by ion-spray mass spectrometry and found that the reactivation was caused by the hydrolytic deamidation of Asn105 to generate the wild-type enzyme. Unlike Asn10 of the l-2-haloacid dehalogenase (L-DEX YL) D10N mutant, Asn105 of the fluoroacetate dehalogenase D105N mutant did not function as a nucleophile to catalyze the dehalogenation.     

Purification, characterization, and gene cloning of a novel fluoroacetate dehalogenase from Burkholderia sp. FA1

Fluoroacetate dehalogenase catalyzes the hydrolytic defluorination of fluoroacetate to produce glycolate. The enzyme is unique in that it catalyzes the cleavage of the highly stable carbon–fluorine bond in an aliphatic compound. The bacterial isolate FA1, which was identified as Burkholderia, grew on fluoroacetate as the sole carbon source to produce fluoroacetate dehalogenase (FAc-DEX FA1). The enzyme was purified to homogeneity and characterized. The molecular weights were estimated to be 79,000 and 34,000 by gel filtration and SDS-polyacrylamide gel electrophoresis (PAGE), respectively, suggesting that the enzyme is a dimer. The purified enzyme was specific to haloacetates, and fluoroacetate was the best substrate. The activities toward chloroacetate and bromoacetate were less than 5% of the activity toward fluoroacetate. The K_m and V_max values for the hydrolysis of fluoroacetate were 5.1 mM and 11 μmol per minute milligram, respectively. The gene coding for the enzyme was isolated, and the nucleotide sequence was determined. The open reading frame consisted of 912 nucleotides, corresponding to 304 amino acid residues. Although FAc-DEX FA1 showed high sequence similarity to fluoroacetate dehalogenase from Moraxella sp. B (FAc-DEX H1) (61% identity), the substrate specificity of FAc-DEX FA1 was significantly different from that of FAc-DEX H1: FAc-DEX FA1 was more specific to fluoroacetate than FAc-DEX H1.     

Novel catalytic mechanism of nucleophilic substitution by asparagine residue involving cyanoalanine intermediate revealed by mass spectrometric monitoring of an enzyme reaction

l-2-Haloacid dehalogenase from Pseudomonas sp. YL catalyzes the hydrolytic dehalogenation, in which Asp(10) acts as a nucleophile to attack the alpha-carbon of l-2-haloalkanoates to form an ester intermediate, which is subsequently hydrolyzed to produce d-2-hydroxyalkanoates. Surprisingly, replacement of the catalytic residue, Asp(10), by Asn did not result in total inactivation of the enzyme (Kurihara, T., Liu, J.-Q., Nardi-Dei, V., Koshikawa, H., Esaki, N., and Soda, K. (1995) J. Biochem. 117, 1317-1322). In this study, we monitored the D10N mutant enzyme reaction by ion-spray mass spectrometry, and found that the enzyme shows a unique structural change when it was incubated with the substrate, l-2-chloropropionate. LC/MS and tandem MS/MS analyses revealed that Asn(10) attacks the substrate to form an imidate, and a proton and d-lactic acid are eliminated to produce a nitrile (beta-cyanoalanine residue), followed by hydrolysis to reproduce Asn(10). This is the first report of the function of Asn to catalyze nucleophilic substitution through its conversion to beta-cyanoalanine residue as an intermediate structure. Also, these results demonstrate that mass spectrometry is remarkably useful in monitoring enzyme reactions.     

Computational evidence for the catalytic mechanism of glutaminyl cyclase. A DFT investigation

The results of a DFT theoretical investigation on the catalytic mechanism of the QC enzyme are presented. A rather large model-system is used. It includes the most important residues that are believed to play a key-role in the catalysis. The computational results show that the rate-determining step of the catalytic process is not the nucleophilic attack leading to the cycle formation (a very easy and fast process with a negligible barrier of 0.8 kcal mol(-1)), but a proton transfer, which is assisted by the Glu201 residue acting as a proton shuttle (general base and general acid). A complex network of hydrogen bonds (involving Asp248 and other residues) contribute to lower the activation barrier for the proton shift which affords the formation of an ammonia molecule bonded to the substrate. The ammonia molecule is a good leaving group which is easily expelled from the substrate in the last step of the catalytic cycle, but remains anchored to the enzyme as a ligand of the zinc cation. The metal plays a key-role in assisting the nucleophilic attack (electrostatic catalysis) since it polarizes the substrate gamma-amide carbonyl group (its electrophilic character increases). Also, the strength of the nucleophilic nitrogen (substrate alpha-amino group) is enhanced by hydrogen bonds involving the Glu201 residue. The computations outline the important role of Trp329 in helping the substrate binding process and stabilizing the cyclization transition state.     

Relocation of the catalytic carboxylate group in class A beta-lactamase: the structure and function of the mutant enzyme Glu166-->Gln:Asn170-->Asp.

The hydrolysis of beta-lactam antibiotics by the serine-beta-lactamases proceeds via an acyl-enzyme intermediate. In the class A enzymes, a key catalytic residue, Glu166, activates a water molecule for nucleophilic attack on the acyl-enzyme intermediate. The active site architecture raises the possibility that the location of the catalytic carboxylate group may be shifted while still maintaining close proximity to the hydrolytic water molecule. A double mutant of the Staphylococcus aureus PC1 beta-lactamase, E166Q:N170D, was produced, with the carboxylate group shifted to position 170 of the polypeptide chain. A mutant protein, E166Q, without a carboxylate group and with abolished deacylation, was produced as a control. The kinetics of the two mutant proteins have been analyzed and the crystal structure of the double mutant protein has been determined. The kinetic data confirmed that deacylation was restored in E166Q:N170D beta-lactamase, albeit not to the level of the wild-type enzyme. In addition, the kinetics of the double mutant enzyme follows progressive inactivation, characterized by initial fast rates and final slower rates. The addition of ammonium sulfate increases the size of the initial burst, consistent with stabilization of the active form of the enzyme by salt. The crystal structure reveals that the overall fold of the E166Q:N170D enzyme is similar to that of native beta-lactamase. However, high crystallographic temperature factors are associated with the ohm-loop region and some of the side chains, including Asp170, are partially or completely disordered. The structure provides a rationale for the progressive inactivation of the Asp170-containing mutant, suggesting that the flexible ohm-loop may be readily perturbed by the substrate such that Asp170's carboxylate group is not always poised to facilitate hydrolysis.     

Identification of Asp174 and Asp175 as the key catalytic residues of human O-GlcNAcase by functional analysis of site-directed mutants

O-GlcNAcase is a family 84 beta-N-acetylglucosaminidase catalyzing the hydrolytic cleavage of beta-O-linked 2-acetamido-2-deoxy-d-glycopyranose (O-GlcNAc) from serine and threonine residues of posttranslationally modified proteins. O-GlcNAcases use a double-displacement mechanism involving formation and breakdown of a transient bicyclic oxazoline intermediate. The key catalytic residues of any family 84 enzyme facilitating this reaction, however, are unknown. Two mutants of human O-GlcNAcase, D174A and D175A, were generated since these residues are highly conserved among family 84 glycoside hydrolases. Structure-reactivity studies of the D174A mutant enzyme reveals severely impaired catalytic activity across a broad range of substrates alongside a pH-activity profile consistent with deletion of a key catalytic residue. The D175A mutant enzyme shows a significant decrease in catalytic efficiency with substrates bearing poor leaving groups (up to 3000-fold), while for substates bearing good leading groups the difference is much smaller (7-fold). This mutant enzyme also cleaves thioglycosides with essentially the same catalytic efficiency as the wild-type enzyme. As well, addition of azide as an exogenous nucleophile increases the activity of this enzyme toward a substrate bearing an excellent leaving group. Together, these results allow unambiguous assignment of Asp(174) as the residue that polarizes the 2-acetamido group for attack on the anomeric center and Asp(175) as the residue that functions as the general acid/base catalyst. Therefore, the family 84 glycoside hydrolases use a DD catalytic pair to effect catalysis.     

Mechanism of action of cutinase: chemical modification of the catalytic triad characteristic for serine hydrolases

Cutinase from Fusarium solani f. sp. pisi was inhibited by diisopropyl fluorophosphate and phenylboronic acid, indicating the involvement of an active serine residue in enzyme catalysis. Quantitation of the number of phosphorylated serines showed that modification of one residue resulted in complete loss of enzyme activity. One essential histidine residue was modified with diethyl pyrocarbonate. This residue was buried in native cutinase and became accessible to chemical modification only after unfolding of the enzyme by sodium dodecyl sulfate. The modification of carboxyl groups with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide in the absence of sodium dodecyl sulfate did not result in inactivation of the enzyme; however, such modifications in the presence of sodium dodecyl sulfate resulted in complete loss of enzyme activity. The number of residues modified was determined by incorporation of [14C]glycine ethyl ester. Modification of cutinase in the absence of sodium dodecyl sulfate and subsequent unfolding of the enzyme with detergent in the presence of radioactive glycine ester showed that one buried carboxyl group per molecule of cutinase resulted in complete inactivation of the enzyme. Three additional peripheral carboxyl groups were modified in the presence of sodium dodecyl sulfate. Carbethoxylation of the essential histidine and subsequent incubation with the esterase substrate p-nitrophenyl [1-14C]acetate revealed that carbethoxycutinase was about 10(5) times less active than the untreated enzyme. The acyl-enzyme intermediate was stabilized under these conditions and was isolated by gel permeation chromatography. The results of the present chemical modification study indicate that catalysis by cutinase involves the catalytic triad and an acyl-enzyme intermediate, both characteristic for serine proteases.     

Identification of the principal catalytically important acidic residue of 3-hydroxy-3-methylglutaryl coenzyme A reductase

Kinetic analysis of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase has implicated a glutamate or aspartate residue in (i) formation of mevaldate thiohemiacetal by proton transfer to the carbonyl oxygen of mevaldate and (ii) enhanced ionization of CoASH by the resulting enzyme carboxylate anion, facilitating attack by CoAS- on the carbonyl carbon of mevaldate (Veloso, D., Cleland, W. W., and Porter, J. W. (1981) Biochemistry 81, 887-894). Although neither the identity of this acidic residue nor its location is known, the catalytic domains of 11 sequenced HMG-CoA reductases contain only 3 conserved acidic residues. For HMG-CoA reductase of Pseudomonas mevalonii, these residues are Glu52, Glu83, and Asp183. To identify the acidic residue that functions in catalysis, we generated mutants having alterations in these residues. The mutant proteins were expressed, purified, and characterized. Mutational alteration of residues Glu52 or Asp183 of P. mevalonii HMG-CoA reductase yielded enzymes with significant, but in some cases reduced, activity (Vmax = 100% Asp183----Ala, 65% Asp183----Asn, and 15% Glu52----Gln of wild-type activity, respectively). Although the activity of mutant enzymes Glu52----Gln and Asp183----Ala was undetectable under standard assay conditions, their Km values for substrates were 4-300-fold higher than those for wild-type enzyme. Km values for wild-type enzyme and for mutant enzymes Glu52----Gln and Asp183----Ala were, respectively: 0.41, 73, and 120 mM [R,S)-mevalonate); 0.080, 4.4, and 2.0 mM (coenzyme A); and 0.26, 4.4, and 1.0 mM (NAD+). By these criteria, neither Glu52 nor Asp183 is the acidic catalytic residue although each may function in substrate recognition. During chromatography on coenzyme A agarose or HMG-CoA agarose, mutant enzymes Asp183----Asn and Glu83----Gln behaved like wild-type enzyme. By contrast, and in support of a role for these residues in substrate recognition, mutant enzymes Glu52----Gln and Asp183----Ala exhibited impaired ability to bind to either support. Despite displaying Km values for substrates and chromatographic behavior on substrate affinity supports comparable to wild-type enzyme, only mutant enzyme Glu83----Gln was essentially inactive under all conditions studied (Vmax = 0.2% that of wild-type enzyme). Glutamate residue 83 of P. mevalonii HMG-CoA reductase, and consequently the glutamate of the consensus Pro-Met-Ala-Thr-Thr-Glu-Gly-Cys-Leu-Val-Ala motif of the catalytic domains of eukaryotic HMG-CoA reductases, is judged to be the acidic residue functional in catalysis.     

Involvement of the Arg-Asp-His catalytic triad in enzymatic cleavage of the phosphodiester bond

Phosphatidylinositol-specific phospholipase C (PI-PLC) catalyzes the cleavage of the P-O bond in phosphatidylinositol via intramolecular nucleophilic attack of the 2-hydroxyl group of inositol on the phosphorus atom. Our earlier stereochemical and site-directed mutagenesis studies indicated that this reaction proceeds by a mechanism similar to that of RNase A, and that the catalytic site of PI-PLC consists of three major components analogous to those observed in RNase A, the His32 general base, the His82 general acid, and Arg69 acting as a phosphate-activating residue. In addition, His32 is associated with Asp274 in forming a catalytic triad with inositol 2-hydroxyl, and His82 is associated with Asp33 in forming a catalytic diad. The focus of this work is to provide a global view of the mechanism, assess cooperation between various catalytic residues, and determine the origin of enzyme activation by the hydrophobic leaving group. To this end, we have investigated kinetic properties of Arg69, Asp33, and His82 mutants with phosphorothioate substrate analogues which feature leaving groups of varying hydrophobicity and pK(a). Our results indicate that interaction of the nonbridging pro-S oxygen atom of the phosphate group with Arg69 is strongly affected by Asp33, and to a smaller extent by His82. This result in conjunction with those obtained earlier can be rationalized in terms of a novel, dual-function triad comprised of Arg69, Asp33, and His82 residues. The function of this triad is to both activate the phosphate group toward the nucleophilic attack and to protonate the leaving group. In addition, Asp33 and His82 mutants displayed much smaller degrees of activation by the fatty acid-containing leaving group as compared to the wild-type (WT) enzyme, and the level of activation was significantly reduced for substrates featuring the leaving group with low pK(a) values. These results strongly suggest that the assembly of the above three residues into the fully catalytically competent triad is controlled by the hydrophobic interactions of the enzyme with the substrate leaving group.     

Increasing the thermal stability of euphauserase. A cold-active and multifunctional serine protease from Antarctic krill.

A molecular model of Antarctic krill euphauserase based on the known crystal structure of its fiddler crab analog, collagenase I, indicates that the core structure of these enzymes is almost identical. Euphauserase is a cold-active and thermally sensitive enzyme with a high affinity for Lys, Arg and large hydrophobic amino acids. Residue Phe137 in euphauserase, localized in loop D (autolysis loop), is highly exposed on the surface of the molecule. Therefore, it appeared to be an easy target for autolysis. The broadly specific euphauserase has a low affinity for negatively charged residues. In order to increase the stability of the enzyme, two mutants were created in which residue Phe137 was replaced by a Glu and an Asp residue. Both mutations resulted in increased stability of the recombinant euphauserase towards thermal inactivation.     

Functional analysis of conserved aspartate and histidine residues located around the type 2 copper site of copper-containing nitrite reductase

A heterologous expression system of the blue copper-containing nitrite reductase from Alcaligenes xylosoxidans GIFU1051 (AxgNIR) was constructed, and the purified recombinant enzyme was characterized. All the characteristic spectroscopic properties and enzyme activity of native AxgNIR were retained in the copper-reconstituted recombinant protein expressed in Escherichia coli, indicating the correct coordination of two types of Cu (type 1 and 2) in the recombinant enzyme. Moreover, two conserved noncoordinate residues, Asp98 and His255, located near the type 2 Cu site were replaced to elucidate the catalytic residue(s) of NIR. The Asp98 residue hydrogen-bonded to the water molecule ligating the type 2 Cu was changed to Ala, Asn, or Glu, and the His255 residue hydrogen-bonded to Asp98 through the water molecule was replaced with Ala, Lys, or Arg. The catalytic rate constants of all mutants were decreased to 0.4-2% of those of the recombinant enzyme, and the apparent K(m) values for nitrite were greatly increased in the Asp98 mutants. All the steady-state kinetic data of the mutants clearly demonstrate that both Asp98 and His255 are involved not only in the catalytic reaction but also in the substrate anchoring.     

Crystal structures representing the Michaelis complex and the thiouronium reaction intermediate of Pseudomonas aeruginosa arginine deiminase

L-arginine deiminase (ADI) catalyzes the irreversible hydrolysis of L-arginine to citrulline and ammonia. In a previous report of the structure of apoADI from Pseudomonas aeruginosa, the four residues that form the catalytic motif were identified as Cys406, His278, Asp280, and Asp166. The function of Cys406 in nucleophilic catalysis has been demonstrated by transient kinetic studies. In this study, the structure of the C406A mutant in complex with L-arginine is reported to provide a snapshot of the enzyme.substrate complex. Through the comparison of the structures of apoenzyme and substrate-bound enzyme, a substrate-induced conformational transition, which might play an important role in activity regulation, was discovered. Furthermore, the position of the guanidinium group of the bound substrate relative to the side chains of His278, Asp280, and Asp166 indicated that these residues mediate multiple proton transfers. His278 and Asp280, which are positioned to activate the water nucleophile in the hydrolysis of the S-alkylthiouronium intermediate, were replaced with alanine to stabilize the intermediate for structure determination. The structures determined for the H278A and D280A mutants co-crystallized with L-arginine provide a snapshot of the S-alkylthiouronium adduct formed by attack of Cys406 on the guanidinium carbon of L-arginine followed by the elimination of ammonia. Asp280 and Asp166 engage in ionic interactions with the guanidinium group in the C406A ADI. L-arginine structure and might orient the reaction center and participate in proton transfer. Structure determination of D166A revealed the apoD166A ADI. The collection of structures is interpreted in the context of recent biochemical data to propose a model for ADI substrate recognition and catalysis.     

Catalytic Mechanism of Retaining α-Galactosidase Belonging to Glycoside Hydrolase Family 97

Glycoside hydrolase family 97 (GH 97) is a unique glycoside family that contains inverting and retaining glycosidases. Of these, BtGH97a (SusB) and BtGH97b (UniProtKB/TrEMBL entry Q8A6L0), derived from Bacteroides thetaiotaomicron, have been characterized as an inverting α-glucoside hydrolase and a retaining α-galactosidase, respectively. Previous studies on the three-dimensional structures of BtGH97a and site-directed mutagenesis indicated that Glu532 acts as an acid catalyst and that Glu439 and Glu508 function as the catalytic base in the inverting mechanism. However, BtGH97b lacks base catalysts but possesses a putative catalytic nucleophilic residue, Asp415. Here, we report that Asp415 in BtGH97b is the nucleophilic catalyst based on the results of crystal structure analysis and site-directed mutagenesis study. Structural comparison between BtGH97b and BtGH97a indicated that OD1 of Asp415 in BtGH97b is located at a position spatially identical with the catalytic water molecule of BtGH97a, which attacks on the anomeric carbon from the β-face (i.e., Asp415 is poised for nucleophilic attack on the anomeric carbon). Site-directed mutagenesis of Asp415 leads to inactivation of the enzyme, and the activity is rescued by an external nucleophilic azide ion. That is, Asp415 functions as a nucleophilic catalyst. The multiple amino acid sequence alignment of GH 97 members indicated that almost half of the GH 97 enzymes possess base catalyst residues at the end of β-strands 3 and 5, while the other half of the family show a conserved nucleophilic residue at the end of β-strand 4. The different positions of functional groups on the β-face of the substrate, which seem to be due to “hopping of the functional group” during evolution, have led to divergence of catalytic mechanism within the same family.     

Mutational analysis of Cvab, an ABC transporter involved in the secretion of active colicin V

CvaB is the central membrane transporter of the colicin V secretion system that belongs to an ATP-binding cassette superfamily. Previous data showed that the N-terminal and C-terminal domains of CvaB are essential for the function of CvaB. N-terminal domain of CvaB possesses Ca(2+)-dependent cysteine proteolytic activity, and two critical residues, Cys32 and His105, have been identified. In this study, we also identify Asp121 as being the third residue of the putative catalytic triad within the active site of the enzyme. The Asp121 mutants lose both their colicin V secretion activity and N-terminal proteolytic activity. The adjacent residue Pro122 also appears to play a critical role in the colicin V secretion. However, the reversal of the two residues D121P - P122D results in loss of activity. Based on molecular modeling and protein sequence alignment, several residues adjacent to the critical residues, Cys32 and His105, were also examined and characterized. Site-directed mutagenesis of Trp101, Asp102, Val108, Leu76, Gly77, and Gln26 indicate that the neighboring residues around the catalytic triad affect colicin V secretion. Several mutated CvaB proteins with defective secretion were also tested, including Asp121 and Pro122, and were found to be structurally stable. These results indicate that the residues surrounding the identified catalytic triad are functionally involved in the secretion of biologically active colicin V.     

His ... Asp catalytic dyad of ribonuclease A: histidine pKa values in the wild-type, D121N, and D121A enzymes

Bovine pancreatic ribonuclease A (RNase A) has a conserved His ... Asp catalytic dyad in its active site. Structural analyses had indicated that Asp121 forms a hydrogen bond with His119, which serves as an acid during catalysis of RNA cleavage. The enzyme contains three other histidine residues including His12, which is also in the active site. Here, 1H-NMR spectra of wild-type RNase A and the D121N and D121A variants were analyzed thoroughly as a function of pH. The effect of replacing Asp121 on the microscopic pKa values of the histidine residues is modest: none change by more than 0.2 units. There is no evidence for the formation of a low-barrier hydrogen bond between His119 and either an aspartate or an asparagine residue at position 121. In the presence of the reaction product, uridine 3'-phosphate (3'-UMP), protonation of one active-site histidine residue favors protonation of the other. This finding is consistent with the phosphoryl group of 3'-UMP interacting more strongly with the two active-site histidine residues when both are protonated. Comparison of the titration curves of the unliganded enzyme with that obtained in the presence of different concentrations of 3'-UMP shows that a second molecule of 3'-UMP can bind to the enzyme. Together, the data indicate that the aspartate residue in the His ... Asp catalytic dyad of RNase A has a measurable but modest effect on the ionization of the adjacent histidine residue.     

Mutation of a unique aspartate residue abolishes the catalytic activity but not substrate binding of the mouse N-methylpurine-DNA glycosylase (MPG)

N-Methylpurine-DNA glycosylase (MPG) initiates base excision repair in DNA by removing a variety of alkylated purine adducts. Although Asp was identified as the active site residue in various DNA glycosylases based on the crystal structure, Glu-125 in human MPG (Glu-145 in mouse MPG) was recently proposed to be the catalytic residue. Mutational analysis for all Asp residues in a truncated, fully active MPG protein showed that only Asp-152 (Asp-132 in the human protein), which is located near the active site, is essential for catalytic activity. However, the substrate binding was not affected in the inactive Glu-152, Asn-152, and Ala-152 mutants. Furthermore, mutation of Asp-152 did not significantly affect the intrinsic tryptophan fluorescence of the enzyme and the far UV CD spectra, although a small change in the near UV CD spectra of the mutants suggests localized conformational change in the aromatic residues. We propose that in addition to Glu-145 in mouse MPG, which functions as the activator of a water molecule for nucleophilic attack, Asp-152 plays an essential role either by donating a proton to the substrate base and, thus, facilitating its release or by stabilizing the steric configuration of the active site pocket.     

Mass spectrometric analysis of the reactions catalyzed by -2-haloacid dehalogenase mutants and implications for the roles of the catalytic amino acid residues

-2-Haloacid dehalogenase catalyzes the hydrolytic dehalogenation of -2-haloalkanoic acids to produce the corresponding -2-hydroxyalkanoic acids. Asp10 of -2-haloacid dehalogenase from Pseudomonas sp. YL nucleophilically attacks the α-carbon atom of the substrate to form an ester intermediate, which is subsequently hydrolyzed by an activated water molecule. We previously showed that the replacement of Thr14, Arg41, Ser118, Lys151, Tyr157, Ser175, Asn177, and Asp180 causes significant loss in the enzyme activity, indicating the involvement of these residues in catalysis. In the present study, we tried to determine which process these residues are involved in by monitoring the formation of the ester intermediate by measuring the molecular masses of the mutant enzymes using ionspray mass spectrometry. When the wild-type enzyme and the T14A, S118D, K151R, Y157F, S175A, and N177D mutant enzymes were mixed with the substrate, the ester intermediate was immediately produced. In contrast, the R41K, D180N, and D180A mutants formed the intermediate much more slowly than the wild-type enzyme, indicating that Arg41 and Asp180 participate in the formation of the ester intermediate. This study presents a new method to analyze the roles of amino acid residues in catalysis.     

Identification of catalytic residues of pepstatin-insensitive carboxyl proteinases from prokaryotes by site-directed mutagenesis.

Pepstatin-insensitive carboxyl proteinases from Pseudomonas sp. (PCP) and Xanthomonas sp. (XCP) have no conserved catalytic residue sequences, -Asp*-Thr-Gly- (Asp is the catalytic residue) for aspartic proteinases. To identify the catalytic residues of PCP and XCP, we selected presumed catalytic residues based on their high sequence similarity, assuming that such significant sites as catalytic residues will be generally conserved. Several Ala mutants of Asp or Glu residues were constructed and analyzed. The D170A, E222A, and D328A mutants for PCP and XD79A, XD169A, and XD348A mutants for XCP were not converted to mature protein after activation, and no catalytic activity could be detected in these mutants. The specificity constants toward chromogenic substrate of the other PCP and XCP mutants, except for the D84A mutant of PCP, were similar to that of wild-type PCP or XCP. Coupled with the result of chemical modification (Ito, M., Narutaki, S., Uchida, K., and Oda, K. (1999) J. Biochem. (Tokyo) 125, 210-216), a pair of Asp residues (170 and 328) for PCP and a pair of Asp residues (169 and 348) for XCP were elucidated to be their catalytic residues, respectively. The Glu(222) residue in PCP or Asp(79) residue in XCP was excluded from the candidates as catalytic residues, since the corresponding mutant retained its original activity.     

Identification of a catalytic residue of Clostridium paraputrificum N-acetyl-beta-D-glucosaminidase Nag3A by site-directed mutagenesis

Clostridium paraputrificum M-21 beta-N-acetylglucosaminidase 3A (Nag3A) is an enzyme classified in family 3 of the glycoside hydrolases. To identify catalytic residues of this enzyme, mutations were introduced into highly conserved Glu and Asp residues. Replacement of Asp175 with Ala abolished the catalytic activity without change in the circular dichroism spectrum, strongly suggesting that this residue is a catalytic residue, a nucleophile/base or a proton donor. Since the K(m) values of mutant enzymes D119N, D229N, D229A and D274N increased 17 to 41 times as compared with that of wild-type enzyme, Asp119, Asp229, and Asp274 appear to be involved in substrate recognition and binding. Taking previous studies into consideration, we presume that Asp303 is the catalytic nucleophile and Asp175 is the proton donor of C. paraputrificum Nag3A.     

Enzymatic properties of mutant Escherichia coli tryptophan synthase alpha-subunits

Thirty-nine mutant tryptophan synthase alpha subunits have been purified and analyzed (in the presence of the beta 2-subunit) for their enzymatic (kcat, Km) behavior in the reactions catalyzed by the alpha 2.beta 2 complex, the fully constituted form of this enzyme. The mutant alpha subunits, obtained by in vitro random, saturation mutagenesis of the encoding trpA gene, contain single amino acid substitutions at sites within the first 121 residues of the alpha polypeptide. Four categories of altered residues have been tentatively assigned roles in the catalytic functions of this enzyme: 1) catalytic residues (Glu49 and Asp60); 2) residues involved in substrate binding or orientation (Phe22, Thr63, Gln65, Tyr102, and Leu105); 3) residues involved in alpha.beta subunit interactions (Gly51, Pro53, Asp56, Asp60, Pro62, Ala67, Phe72, Thr77, Pro78, Tyr102, Asn104, Leu105, and Asn108); and 4) residues with no apparent catalytic roles. Catalytic residue alterations result in no detectable activity in the alpha-subunit specific reactions. Substrate binding/orientation roles are detected enzymatically primarily as rate defects; alterations only at Tyr102 result in apparent Km effects. alpha.beta interaction roles are detected as rate defects in all tryptophan synthase reactions plus Km increases for the alpha-subunit substrate, indole-3-glycerol phosphate, only when L-serine is present at the beta 2-subunit active site. A substitution at only one site, Asn104, appears to be unique in its potential effect on intersubunit channeling of indole, the product of the alpha-subunit specific reaction, to the beta 2-subunit active site.