The bifunctional active site of s-adenosylmethionine synthetase. Roles of the active site aspartates.

S-Adenosylmethionine (AdoMet) synthetase catalyzes the biosynthesis of AdoMet in a unique enzymatic reaction. Initially the sulfur of methionine displaces the intact tripolyphosphate chain (PPP(i)) from ATP, and subsequently PPP(i) is hydrolyzed to PP(i) and P(i) before product release. The crystal structure of Escherichia coli AdoMet synthetase shows that the active site contains four aspartate residues. Aspartate residues Asp-16* and Asp-271 individually provide the sole protein ligand to one of the two required Mg(2+) ions (* denotes a residue from a second subunit); aspartates Asp-118 and Asp-238* are proposed to interact with methionine. Each aspartate has been changed to an uncharged asparagine, and the metal binding residues were also changed to alanine, to assess the roles of charge and ligation ability on catalytic efficiency. The resultant enzyme variants all structurally resemble the wild type enzyme as indicated by circular dichroism spectra and are tetramers. However, all have k(cat) reductions of approximately 10(3)-fold in AdoMet synthesis, whereas the MgATP and methionine K(m) values change by less than 3- and 8-fold, respectively. In the partial reaction of PPP(i) hydrolysis, mutants of the Mg(2+) binding residues have >700-fold reduced catalytic efficiency (k(cat)/K(m)), whereas the D118N and D238*N mutants are impaired less than 35-fold. The catalytic efficiency for PPP(i) hydrolysis by Mg(2+) site mutants is improved by AdoMet, like the wild type enzyme. In contrast AdoMet reduces the catalytic efficiency for PPP(i) hydrolysis by the D118N and D238*N mutants, indicating that the events involved in AdoMet activation are hindered in these methionyl binding site mutants. Ca(2+) uniquely activates the D271A mutant enzyme to 15% of the level of Mg(2+), in contrast to the approximately 1% Ca(2+) activation of the wild type enzyme. This indicates that the Asp-271 side chain size is a discriminator between the activating ability of Ca(2+) and the smaller Mg(2+).     

Discrimination of cognate and noncognate substrates at the active site of class I lysyl-tRNA synthetase

The aminoacyl-tRNA synthetases are divided into two unrelated structural classes, with lysyl-tRNA synthetase (LysRS) being the only enzyme represented in both classes. On the basis of the structure of l-lysine complexed with Pyrococcus horikoshii class I LysRS (LysRS1) and homology to glutamyl-tRNA synthetase (GluRS), residues implicated in amino acid recognition and noncognate substrate discrimination were systematically replaced in Borrelia burgdorferi LysRS1. The catalytic efficiency of steady-state aminoacylation (k(cat)/K(M)) with lysine by LysRS1 variants fell by 1-4 orders of magnitude compared to that of the wild type. Disruption of putative hydrogen bonding interactions through replacement of G29, T31, and Y269 caused up to 1500-fold reductions in k(cat)/K(M), similar to changes previously observed for comparable variants of class II LysRS (LysRS2). Replacements of W220 and H242, both of which are implicated in hydrophobic interactions with the side chain of lysine, resulted in more dramatic changes with up to 40000-fold reductions in k(cat)/K(M) observed. This indicates that the more compact LysRS1 active site employs both electrostatic and hydrophobic interactions during lysine discrimination, explaining the ability of LysRS1 to discriminate against noncognate substrates accepted by LysRS2. Several of the LysRS1 variants were found to be more specific than the wild type with respect to noncognate amino acid recognition but less efficient in cognate aminoacylation. This indicates that LysRS1 compromises between efficient catalysis and substrate discrimination, in contrast to LysRS2 which is considerably more effective in catalysis but is less specific than its class I counterpart.     

The active site loop of S-adenosylmethionine synthetase modulates catalytic efficiency

Crystallographic studies of Escherichia coli S-adenosylmethionine synthetase (ATP:L-methionine S-adenosyltransferase, MAT) have defined a flexible polypeptide loop that can gate access to the active site without contacting the substrates. The influence of the length and sequence of this active site loop on catalytic efficiency has been characterized in a mutant in which the E. coli MAT sequence (DRADPLEQ) has been replaced with the distinct sequence of the corresponding region of the otherwise highly homologous rat liver enzyme (HDLRNEEDV). Four additional mutants in which the entire DRADPLEQ sequence was replaced by five, six, seven, or eight glycines have been studied to unveil the effects of loop length and the influence of side chains. In all of the mutants, the maximal rate of S-adenosylmethionine formation (k(cat)) is diminished by more than 200-fold whereas the rate of hydrolysis of the tripolyphosphate intermediate is decreased by less than 3-fold. Thus, the function of the loop is localized to the first step in the overall reaction. The K(m) for methionine increases in all of the oligoglycine mutants, whereas the K(m) values for ATP are not substantially different. The k(cat) for the wild-type enzyme is decreased by increases in solution microviscosity with 55% of the maximal dependence. Thus, a diffusional event is coupled to the chemical step of AdoMet formation, which is known to be rate-limiting. The results indicate that a conformational change, possibly loop closure, is associated with AdoMet synthesis. The data integrate a previously discovered conformational change associated with PPP(i) binding to the E x AdoMet complex into the reaction sequence, reflecting a difference in protein conformation in the E x AdoMet x PPP(i) complex whether it is formed from the E x ATP x methionine complex or from binding of exogenous PPP(i). The temperature dependence of the k(cat) for S-adenosylmethionine formation shows that the removal of the side chains in the glycine mutants causes the activation enthalpy of the reaction to approximately double in each case, while the activation entropy changes from negative in the wild-type enzyme to positive in the mutants. The favorable activation entropy in the mutant-catalyzed reactions may reflect release of water during catalysis, while the negative activation entropy in the reaction catalyzed by the wild-type enzyme apparently reflects reorganization of the loop. The observations point to how nature can fine-tune the activity of an enzyme by modifying substrate and product access to the active site rather than by altering the enzyme x substrate contacts or the catalytic machinery itself.     

Probing a rate-limiting step by mutational perturbation of AdoMet binding in the HhaI methyltransferase

DNA methylation plays important roles via regulation of numerous cellular mechanisms in diverse organisms, including humans. The paradigm bacterial methyltransferase (MTase) HhaI (M.HhaI) catalyzes the transfer of a methyl group from the cofactor S-adenosyl-L-methionine (AdoMet) onto the target cytosine in DNA, yielding 5-methylcytosine and S-adenosyl-L-homocysteine (AdoHcy). The turnover rate (k cat) of M.HhaI, and the other two cytosine-5 MTases examined, is limited by a step subsequent to methyl transfer; however, no such step has so far been identified. To elucidate the role of cofactor interactions during catalysis, eight mutants of Trp41, which is located in the cofactor binding pocket, were constructed and characterized. The mutants show full proficiency in DNA binding and base-flipping, and little variation is observed in the apparent methyl transfer rate k chem as determined by rapid-quench experiments using immobilized fluorescent-labeled DNA. However, the Trp41 replacements with short side chains substantially perturb cofactor binding (100-fold higher K(AdoMet)D and K(AdoMet)M) leading to a faster turnover of the enzyme (10-fold higher k cat). Our analysis indicates that the rate-limiting breakdown of a long-lived ternary product complex is initiated by the dissociation of AdoHcy or the opening of the catalytic loop in the enzyme.     

Enhancement, relaxation, and reversal of the stereoselectivity for phosphotriesterase by rational evolution of active site residues

The factors that govern the substrate reactivity and stereoselectivity of phosphotriesterase (PTE) toward organophosphotriesters containing various combinations of methyl, ethyl, isopropyl, and phenyl substituents at the phosphorus center were determined by systematic alterations in the dimensions of the active site. The wild type PTE prefers the S(P)-enantiomers over the corresponding R(P)-enantiomers by factors ranging from 10 to 90. Enlargement of the small subsite of PTE with the substitution of glycine and alanine residues for Ile-106, Phe-132, and/or Ser-308 resulted in significant improvements in k(cat)/K(a) for the R(P)-enantiomers of up to 2700-fold but had little effect on k(cat)/K(a) for the corresponding S(P)-enantiomers. The kinetic preferences for the S(P)-enantiomers were thus relaxed without sacrificing the inherent catalytic activity of the wild type enzyme. A reduction in the size of the large subsite with the mutant H257Y resulted in a reduction in k(cat)/K(a) for the S(P)-enantiomers, while the values of k(cat)/K(a) for the R(P)-enantiomers were essentially unchanged. The initial stereoselectivity observed with the wild type enzyme toward the chiral substrate library was significantly reduced with the H257Y mutant. Simultaneous alternations in the sizes of the large and small subsites resulted in the complete reversal of the chiral specificity. With this series of mutants, the R(P)-enantiomers were preferred as substrates over the corresponding S(P)-enantiomers by up to 500-fold. These results have demonstrated that the stereochemical determinants for substrate hydrolysis by PTE can be systematically altered through a rational reconstruction of the dimensions of the active site.     

Key NAD+-binding residues in human 15-hydroxyprostaglandin dehydrogenase

NAD(+)-dependent 15-hydroxyprostaglandin dehydrogenase (15-PGDH), a member of the short-chain dehydrogenase/reductase (SDR) family, catalyzes the first step in the catabolic pathways of prostaglandins and lipoxins, and is believed to be the key enzyme responsible for the biological inactivation of these biologically potent eicosanoids. The enzyme utilizes NAD(+) specifically as a coenzyme. Potential amino acid residues involved in binding NAD(+) and facilitating enzyme catalysis have been partially identified. In this report, we propose that three more residues in 15-PGDH, Ile-17, Asn-91, and Val-186, are also involved in the interaction with NAD(+). Site-directed mutagenesis was used to examine their roles in binding NAD(+). Several mutants (I17A, I17V, I17L, I17E, I17K, N91A, N91D, N91K, V186A, V186I, V186D, and V186K) were prepared, expressed as glutathione S-transferase (GST) fusion enzymes in Escherichia coli, and purified by GSH-agarose affinity chromatography. Mutants I17E, I17K, N91L, N91K, and V186D were found to be inactive. Mutants N91A, N91D, V186A, and V186K exhibited comparable activities to the wild type enzyme. However, mutants I17A, I17V, I17L, and V186I had higher activity than the wild type. Especially, the activities of I17L and V186I were increased nearly 4- and 5-fold, respectively. The k(cat)/K(m) ratios of all active mutants for PGE(2) were similar to that of the wild type enzyme. However, the k(cat)/K(m) ratios of mutants I17A and N91A for NAD(+) were decreased 5- and 10-fold, respectively, whereas the k(cat)/K(m) ratios of mutants I17V, N91D, V186I, and V186K for NAD(+) were comparable to that of the wild type enzyme. The k(cat)/K(m) ratios of mutants I17L and V186A for NAD(+) were increased over nearly 2-fold. These results suggest that Ile-17, Asn-91, and Val-186 are involved in the interaction with NAD(+) and contribute to the full catalytic activity of 15-PGDH.     

Arginine 165/arginine 277 pair in (S)-mandelate dehydrogenase from Pseudomonas putida: role in catalysis and substrate binding

(S)-Mandelate dehydrogenase from Pseudomonas putida belongs to a FMN-dependent enzyme family that oxidizes (S)-alpha-hydroxyacids. Active site structures of three homologous enzymes, including MDH, show the presence of two conserved arginine residues in close juxtaposition (Arg165 and Arg277 in MDH). Arg277 has an important catalytic role; it stabilizes both the ground and transition states through its positive charge as well as a hydrogen bond [Lehoux, I. E., and Mitra, B. (2000) Biochemistry 39, 10055-10065]. In this study, we examined the role of Arg165 and the overall importance of the Arg165/Arg277 pair. Single mutants at Arg165 as well as double mutants at Arg165 and Arg277 were characterized. Our results show that Arg165 has a role similar to, but less critical than, that of Arg277. It stabilizes the transition state through its positive charge and the ground state through a charge-independent interaction, most likely, a hydrogen bond. Though the k(cat)s for the charge-conserved mutants, R165K and R277K, were only 3-5-fold lower than those of wild-type MDH (wtMDH), the k(cat) for R165K/R277K was approximately 350-fold lower. Thus, at least one arginine residue is required for the optimal substrate orientation and catalysis. Stopped-flow studies show that the FMN reduction step is completely rate-limiting for both wtMDH and the arginine mutants, with the possible exception of R165E. Substrate isotope effects indicate that the carbon-hydrogen bond-breaking step is only partially rate-limiting for wtMDH but fully rate-limiting for the mutants. pH profiles of R165M conclusively show that the pK(a) of 9.3 in free wtMDH does not belong to Arg165.     

Residues at the active site of the esterase 2 from Alicyclobacillus acidocaldarius involved in substrate specificity and catalytic activity at high temperature.

The recently solved three-dimensional structure of the thermophilic esterase 2 from Alicyclobacillus acidocaldarius allowed us to have a snapshot of an enzyme-sulfonate complex, which mimics the second stage of the catalytic reaction, namely the covalent acyl-enzyme intermediate. The aim of this work was to design, by structure-aided analysis and to generate by site-directed and saturation mutagenesis, EST2 variants with changed substrate specificity in the direction of preference for monoacylesters whose acyl-chain length is greater than eight carbon atoms. Positions 211 and 215 of the polypeptide chain were chosen to introduce mutations. Among five variants with single and double amino acid substitutions, three were obtained, M211S, R215L, and M211S/R215L, that changed the catalytic efficiency profile in the desired direction. Kinetic characterization of mutants and wild type showed that this change was achieved by an increase in k(cat) and a decrease in K(m) values with respect to the parental enzyme. The M211S/R215L specificity constant for p-nitrophenyl decanoate substrate was 6-fold higher than the wild type. However, variants M211T, M211S, and M211V showed strikingly increased activity as well as maximal activity with monoacylesters with four carbon atoms in the acyl chain, compared with the wild type. In the case of mutant M211T, the k(cat) for p-nitrophenyl butanoate was 2.4-fold higher. Overall, depending on the variant and on the substrate, we observed improved catalytic activity at 70 degrees C with respect to the wild type, which was a somewhat unexpected result for an enzyme with already high k(cat) values at high temperature. In addition, variants with altered specificity toward the acyl-chain length were obtained. The results were interpreted in the context of the EST2 three-dimensional structure and a proposed catalytic mechanism in which k(cat), e.g. the limiting step of the reaction, was dependent on the acyl chain length of the ester substrate.     

Identification of critical residues of choline kinase A2 from Caenorhabditis elegans

Choline kinase catalyzes the phosphorylation of choline by ATP, the first committed step in the CDP-choline pathway for phosphatidylcholine biosynthesis. To begin to elucidate the mechanism of catalysis by this enzyme, choline kinase A-2 from Caenorhabditis elegans was analyzed by systematic mutagenesis of highly conserved residues followed by analysis of kinetic and structural parameters. Specifically, mutants were analyzed with respect to K(m) and k(cat) values for each substrate and Mg(2+), inhibitory constants for Mg(2+) and Ca(2+), secondary structure as monitored by circular dichroism, and sensitivity to unfolding in guanidinium hydrochloride. The most severe impairment of catalysis occurred with the modification of Asp-255 and Asn-260, which are located in the conserved Brenner's phosphotransferase motif, and Asp-301 and Glu-303, in the signature choline kinase motif. For example, mutation of Asp-255 or Asp-301 to Ala eliminated detectable catalytic activity, and mutation of Asn-260 and Glu-303 to Ala decreased k(cat) by 300- and 10-fold, respectively. Additionally, the K(m) for Mg(2+) for mutants N260A and E303A was approximately 30-fold higher than that of wild type. Several other residues (Ser-86, Arg-111, Glu-125, and Trp-387) were identified as being important: Catalytic efficiencies (k(cat)/K(m)) for the enzymes in which these residues were mutated to Ala were reduced to 2-25% of wild type. The high degree of structural similarity among choline kinase A-2, aminoglycoside phosphotransferases, and protein kinases, together with the results from this mutational analysis, indicates it is likely that these conserved residues are located at the catalytic core of choline kinase.     

Reaction mechanism of glutathione synthetase from Arabidopsis thaliana: site-directed mutagenesis of active site residues

Glutathione is essential for maintaining the intracellular redox environment and is synthesized from gamma-glutamylcysteine, glycine, and ATP by glutathione synthetase (GS). To examine the reaction mechanism of a eukaryotic GS, 24 Arabidopsis thaliana GS (AtGS) mutants were kinetically characterized. Within the gamma-glutamylcysteine/glutathione-binding site, the S153A and S155A mutants displayed less than 4-fold changes in kinetic parameters with mutations of Glu-220 (E220A/E220Q), Gln-226 (Q226A/Q226N), and Arg-274 (R274A/R274K) at the distal end of the binding site resulting in 24-180-fold increases in the K(m) values for gamma-glutamylcysteine. Substitution of multiple residues interacting with ATP (K313M, K367M, and E429A/E429Q) or coordinating magnesium ions to ATP (E148A/E148Q, N150A/N150D, and E371A) yielded inactive protein because of compromised nucleotide binding, as determined by fluorescence titration. Other mutations in the ATP-binding site (E371Q, N376A, and K456M) resulted in greater than 30-fold decreases in affinity for ATP and up to 80-fold reductions in turnover rate. Mutation of Arg-132 and Arg-454, which are positioned at the interface of the two substrate-binding sites, affected the enzymatic activity differently. The R132A mutant was inactive, and the R132K mutant decreased k(cat) by 200-fold; however, both mutants bound ATP with K(d) values similar to wild-type enzyme. Minimal changes in kinetic parameters were observed with the R454K mutant, but the R454A mutant displayed a 160-fold decrease in k(cat). In addition, the R132K, R454A, and R454K mutations elevated the K(m) value for glycine up to 11-fold. Comparison of the pH profiles and the solvent deuterium isotope effects of A. thaliana GS and the Arg-132 and Arg-454 mutants also suggest distinct mechanistic roles for these residues. Based on these results, a catalytic mechanism for the eukaryotic GS is proposed.     

Probing functional perfection in substructures of ribonuclease T1: double combinatorial random mutagenesis involving Asn43, Asn44, and Glu46 in the guanine binding loop

Combinatorial random mutageneses involving either Asn43 with Asn44 (set 1) or Glu46 with an adjacent insertion (set 2) were undertaken to explore the functional perfection of the guanine recognition loop of ribonuclease T(1) (RNase T(1)). Four hundred unique recombinants were screened in each set for their ability to enhance enzyme catalysis of RNA cleavage. After a thorough selection procedure, only six variants were found that were either as active or more active than wild type which included substitutions of Asn43 by Gly, His, Leu, or Thr, an unplanned Tyr45Ser substitution and Glu46Pro with an adjacent Glu47 insertion. Asn43His-RNase T(1) has the same loop sequence as that for RNases Pb(1) and Fl(2). None of the most active mutants were single substitutions at Asn44 or double substitutions at Asn43 and Asn44. A total of 13 variants were purified, and these were subjected to kinetic analysis using RNA, GpC, and ApC as substrates. Modestly enhanced activities with GpC and RNA involved both k(cat) and K(M) effects. Mutants having low activity with GpC had proportionately even lower relative activity with RNA. Asn43Gly-RNase T(1) and all five of the purified mutants in set 2 exhibited similar values of k(cat)/K(M) for ApC which were the highest observed and about 10-fold that for wild type. The specificity ratio [(k(cat)/K(M))(GpC)/(k(cat)/K(M))(ApC)] varied over 30 000-fold including a 10-fold increase [Asn43His variant; mainly due to a low (k(cat)/K(M))(ApC)] and a 3000-fold decrease (Glu46Ser/(insert)Gly47 variant; mainly due to a low (k(cat)/K(M))(GpC)) as compared with wild type. It is interesting that k(cat) (GpC) for the Tyr45Ser variant was almost 4-fold greater than for wild type and that Pro46/(insert)Glu47 RNase T(1) is 70-fold more active than the permuted variant (insert)Pro47-RNase T(1) which has a conserved Glu46. In any event, the observation that only 6 out of 800 variants surveyed had wild-type activity supports the view that functional perfection of the guanine recognition loop of RNase T(1) has been achieved.     

Mutagenesis of Trp(54) and Trp(203) residues on Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase significantly affects catalytic activities of the enzyme

The possible structural and catalytic functions of the nine tryptophan amino acid residues, including Trp(54), Trp(105), Trp(112), Trp(141), Trp(148), Trp(165), Trp(186), Trp(198), and Trp(203) in Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase (Fs beta-glucanase), were characterized using site-directed mutagenesis, initial rate kinetics, fluorescence spectrometry, and structural modeling analysis. Kinetic studies showed that a 5-7-fold increase in K(m) value for lichenan was observed for W141F, W141H, and W203R mutant Fs beta-glucanases, and approximately 72-, 56-, 30-, 29.5-, 4.9-, and 4.3-fold decreases in k(cat) relative to that for the wild-type enzyme were observed for the W54F, W54Y, W141H, W203R, W141F, and W148F mutants, respectively. In contrast, W186F and W203F, unlike the other 12 mutants, exhibited a 1.4- and 4.2-fold increase in k(cat), respectively. W165F and W203R were the only two mutants that exhibited a 4-7-fold higher activity relative to the wild-type enzyme after they were incubated at pH 3.0 for 1 h. Fluorescence spectrometry indicated that all of the mutations on the nine tryptophan amino acid residues retained a folding similar to that of the wild-type enzyme. Structural modeling and kinetic studies suggest that Trp(54), Trp(141), Trp(148), and Trp(203) play important roles in maintaining structural integrity in the substrate-binding cleft and the catalytic efficiency of the enzyme.     

Analysis of the catalytic and binding residues of the diadenosine tetraphosphate pyrophosphohydrolase from Caenorhabditis elegans by site-directed mutagenesis

The contributions to substrate binding and catalysis of 13 amino acid residues of the Caenorhabditis elegans diadenosine tetraphosphate pyrophosphohydrolase (Ap(4)A hydrolase) predicted from the crystal structure of an enzyme-inhibitor complex have been investigated by site-directed mutagenesis. Sixteen glutathione S-transferase-Ap(4)A hydrolase fusion proteins were expressed and their k(cat) and K(m) values determined after removal of the glutathione S-transferase domain. As expected for a Nudix hydrolase, the wild type k(cat) of 23 s(-1) was reduced by 10(5)-, 10(3)-, and 30-fold, respectively, by replacement of the conserved P(4)-phosphate-binding catalytic residues Glu(56), Glu(52), and Glu(103) by Gln. K(m) values were not affected, indicating a lack of importance for substrate binding. In contrast, mutating His(31) to Val or Ala and Lys(83) to Met produced 10- and 16-fold increases in K(m) compared with the wild type value of 8.8 microm. These residues stabilize the P(1)-phosphate. H31V and H31A had a normal k(cat) but K83M showed a 37-fold reduction in k(cat). Lys(36) also stabilizes the P(1)-phosphate and a K36M mutant had a 10-fold reduced k(cat) but a relatively normal K(m). Thus both Lys(36) and Lys(83) may play a role in catalysis. The previously suggested roles of Tyr(27), His(38), Lys(79), and Lys(81) in stabilizing the P(2) and P(3)-phosphates were not confirmed by mutagenesis, indicating the absence of phosphate-specific binding contacts in this region. Also, mutating both Tyr(76) and Tyr(121), which clamp one substrate adenosine moiety between them in the crystal structure, to Ala only increased K(m) 4-fold. It is concluded that interactions with the P(1)- and P(4)-phosphates are minimum and sufficient requirements for substrate binding by this class of enzyme, indicating that it may have a much wider substrate range then previously believed.     

Chemical and mutagenic investigations of fatty acid amide hydrolase: evidence for a family of serine hydrolases with distinct catalytic properties.

Fatty acid amide hydrolase (FAAH) is a membrane-bound enzyme responsible for the catabolism of neuromodulatory fatty acid amides, including anandamide and oleamide. FAAH's primary structure identifies this enzyme as a member of a diverse group of alkyl amidases, known collectively as the "amidase signature family". At present, this enzyme family's catalytic mechanism remains poorly understood. In this study, we investigated the catalytic features of FAAH through mutagenesis, affinity labeling, and steady-state kinetic methods. In particular, we focused on the respective roles of three serine residues that are conserved in all amidase signature enzymes (S217, S218, and S241 in FAAH). Mutation of each of these serines to alanine resulted in a FAAH enzyme bearing significant catalytic defects, with the S217A and S218A mutants showing 2300- and 95-fold reductions in k(cat), respectively, and the S241A mutant exhibiting no detectable catalytic activity. The double S217A:S218A FAAH mutant displayed a 230 000-fold decrease in k(cat), supporting independent catalytic functions for these serine residues. Affinity labeling of FAAH with a specific nucleophile reactive inhibitor, ethoxy oleoyl fluorophosphonate, identified S241 as the enzyme's catalytic nucleophile. The pH dependence of FAAH's k(cat) and k(cat)/K(m) implicated a base involved in catalysis with a pK(a) of 7.9. Interestingly, mutation of each of FAAH's conserved histidines (H184, H358, and H449) generated active enzymes, indicating that FAAH does not contain a Ser-His-Asp catalytic triad commonly found in other mammalian serine hydrolytic enzymes. The unusual properties of FAAH identified here suggest that this enzyme, and possibly the amidase signature family as a whole, may hydrolyze amides by a novel catalytic mechanism.     

Complete reversal of coenzyme specificity of xylitol dehydrogenase and increase of thermostability by the introduction of structural zinc

Pichia stipitis NAD(+)-dependent xylitol dehydrogenase (XDH), a medium-chain dehydrogenase/reductase, is one of the key enzymes in ethanol fermentation from xylose. For the construction of an efficient biomass-ethanol conversion system, we focused on the two areas of XDH, 1) change of coenzyme specificity from NAD(+) to NADP(+) and 2) thermostabilization by introducing an additional zinc atom. Site-directed mutagenesis was used to examine the roles of Asp(207), Ile(208), Phe(209), and Asn(211) in the discrimination between NAD(+) and NADP(+). Single mutants (D207A, I208R, F209S, and N211R) improved 5 approximately 48-fold in catalytic efficiency (k(cat)/K(m)) with NADP(+) compared with the wild type but retained substantial activity with NAD(+). The double mutants (D207A/I208R and D207A/F209S) improved by 3 orders of magnitude in k(cat)/K(m) with NADP(+), but they still preferred NAD(+) to NADP(+). The triple mutant (D207A/I208R/F209S) and quadruple mutant (D207A/I208R/F209S/N211R) showed more than 4500-fold higher values in k(cat)/K(m) with NADP(+) than the wild-type enzyme, reaching values comparable with k(cat)/K(m) with NAD(+) of the wild-type enzyme. Because most NADP(+)-dependent XDH mutants constructed in this study decreased the thermostability compared with the wild-type enzyme, we attempted to improve the thermostability of XDH mutants by the introduction of an additional zinc atom. The introduction of three cysteine residues in wild-type XDH gave an additional zinc-binding site and improved the thermostability. The introduction of this mutation in D207A/I208R/F209S and D207A/I208R/F209S/N211R mutants increased the thermostability and further increased the catalytic activity with NADP(+).     

Identification of the general acid/base catalyst of a family 3 beta-glucosidase from Flavobacterium meningosepticum

beta-Glucosidase from Flavobacterium meningosepticum (Fbgl) (also known as Chryseobacterium meningosepticum) has been classified as a member of the family 3 glycohydrolases. It is a retaining enzyme involving a two-step, double-displacement mechanism. D247 was shown to function as the nucleophile of the enzymatic reaction [Li, Y.-K., Chir, J., and Chen, F.-Y. (2001) Biochem. J. 355, 835-840]. However, the general acid/base catalyst of this enzyme and of all other family 3 glycohydrolases has not yet been identified. On the basis of amino acid sequence alignment of 15 family 3 enzymes, 11 residues (D71, R129, E132, E136, D137, K168, H169, E177, D247, D458, and E473) are highly conserved. All of these residues are studied by site-directed mutagenesis and kinetic investigation. Analyzing the catalytic power of all mutants reveals E473 residue is the best candidate of the acid/base catalyst. Detailed studies supporting this suggestion are summarized as follows. (1) The k(cat) and K(m) values for the hydrolysis of 2,4-dinitrophenyl beta-D-glucopyranoside (2,4-DNPG) by E473G are reduced 3300- and 900-fold, respectively, compared with those of the wild type (WT). (2) The k(cat) values of E473G-catalyzed hydrolysis are virtually invariant with pH over the range of 5.0-9.0. (3) The activity of E473G with 2,4-DNPG is enhanced by the addition of azide, and beta-glucosyl azide is formed. (4) The k(cat) of the reaction of 2-carboxyphenyl beta-glucoside catalyzed by E473G is comparable to that for hydrolysis by wild-type Fbgl and is 100- and 320-fold better than the k(cat) values for the E473G-catalyzed hydrolysis of 4-carboxyphenyl beta-glucoside and the corresponding methyl ester, respectively. (5) The accumulated glucosyl-enzyme intermediate was directly observed by mass analysis in the reaction of 2,4-DNPG with E473G. All of these results confirm that E473 is the general acid/base catalyst of Fbgl.     

Mutational, kinetic, and NMR studies of the roles of conserved glutamate residues and of lysine-39 in the mechanism of the MutT pyrophosphohydrolase

The MutT enzyme catalyzes the hydrolysis of nucleoside triphosphates (NTP) to NMP and PP(i) by nucleophilic substitution at the rarely attacked beta-phosphorus. The solution structure of the quaternary E-M(2+)-AMPCPP-M(2+) complex indicated that conserved residues Glu-53, -56, -57, and -98 are at the active site near the bound divalent cation possibly serving as metal ligands, Lys-39 is positioned to promote departure of the NMP leaving group, and Glu-44 precedes helix I (residues 47-59) possibly stabilizing this helix which contributes four catalytic residues to the active site [Lin, J. , Abeygunawardana, C., Frick, D. N., Bessman, M. J., and Mildvan, A. S. (1997) Biochemistry 36, 1199-1211]. To test these proposed roles, the effects of mutations of each of these residues on the kinetic parameters and on the Mn(2+), Mg(2+), and substrate binding properties were examined. The largest decreases in k(cat) for the Mg(2+)-activated enzyme of 10(4.7)- and 10(2.6)-fold were observed for the E53Q and E53D mutants, respectively, while 97-, 48-, 25-, and 14-fold decreases were observed for the E44D, E56D, E56Q, and E44Q mutations, respectively. Smaller effects on k(cat) were observed for mutations of Glu-98 and Lys-39. For wild type MutT and its E53D and E44D mutants, plots of log(k(cat)) versus pH exhibited a limiting slope of 1 on the ascending limb and then a hump, i.e., a sharply defined maximum near pH 8 followed by a plateau, yielding apparent pK(a) values of 7.6 +/- 0.3 and 8.4 +/- 0.4 for an essential base and a nonessential acid catalyst, respectively, in the active quaternary MutT-Mg(2+)-dGTP-Mg(2+) complex. The pK(a) of 7.6 is assigned to Glu-53, functioning as a base catalyst in the active quaternary complex, on the basis of the disappearance of the ascending limb of the pH-rate profile of the E53Q mutant, and its restoration in the E53D mutant with a 10(1.9)-fold increase in (k(cat))(max). The pK(a) of 8.4 is assigned to Lys-39 on the basis of the disappearance of the descending limb of the pH-rate profile of the K39Q mutant, and the observation that removal of the positive charge of Lys-39, by either deprotonation or mutation, results in the same 8.7-fold decrease in k(cat). Values of k(cat) of both wild type MutT and the E53Q mutant were independent of solvent viscosity, indicating that a chemical step is likely to be rate-limiting with both. A liganding role for Glu-53 and Glu-56, but not Glu-98, in the binary E-M(2+) complex is indicated by the observation that the E53Q, E53D, E56Q, and E56D mutants bound Mn(2+) at the active site 36-, 27-, 4.7-, and 1.9-fold weaker, and exhibited 2.10-, 1.50-, 1.12-, and 1.24-fold lower enhanced paramagnetic effects of Mn(2+), respectively, than the wild type enzyme as detected by 1/T(1) values of water protons, consistent with the loss of a metal ligand. However, the K(m) values of Mg(2+) and Mn(2+) indicate that Glu-56, and to a lesser degree Glu-98, contribute to metal binding in the active quaternary complex. Mutations of the more distant but conserved residue Glu-44 had little effect on metal binding or enhancement factors in the binary E-M(2+) complexes. Two-dimensional (1)H-(15)N HSQC and three-dimensional (1)H-(15)N NOESY-HSQC spectra of the kinetically damaged E53Q and E56Q mutants showed largely intact proteins with structural changes near the mutated residues. Structural changes in the kinetically more damaged E44D mutant detected in (1)H-(15)N HSQC spectra were largely limited to the loop I-helix I motif, suggesting that Glu-44 stabilizes the active site region. (1)H-(15)N HSQC titrations of the E53Q, E56Q, and E44D mutants with dGTP showed changes in chemical shifts of residues lining the active site cleft, and revealed tighter nucleotide binding by these mutants, indicating an intact substrate binding site. (ABSTRACT TRUNCATED)     

Identification of essential histidine residues in 3-deoxy-D-manno-octulosonic acid 8-phosphate synthase: analysis by chemical modification with diethyl pyrocarbonate and site-directed mutagenesis

The enzyme 3-deoxy-D-manno-octulosonic acid 8-phosphate (KDO 8-P) synthase from Escherichia coli that catalyzes the aldol-type condensation of D-arabinose 5-phosphate (A 5-P) and phosphoenolpyruvate (PEP) to give KDO 8-P and inorganic phosphate (P(i)) is inactivated by diethyl pyrocarbonate (DEPC). The inactivation is first-order in enzyme and DEPC. A second-order rate constant of 340 M(-1) min(-1) is obtained at pH 7.6 and 4 degrees C. The rate of inactivation is dependent on pH and the pH-inactivation rate data imply the involvement of an amino acid residue with a pK(a) value of 7.3. KDO 8-P synthase activity is not restored to the DEPC-inactivated enzyme following treatment with hydroxylamine. Complete loss of KDO 8-P synthase activity correlates with the ethoxyformylation of three histidine residues by DEPC. KDO 8-P synthase is protected against DEPC inactivation by PEP and partially protected against inactivation by A 5-P. To provide further evidence for the involvement or role of the histidine residues in the aldol-type condensation catalyzed by KDO 8-P synthase, all six histidines were individually mutated to either glycine or alanine. The kinetic constants for the three mutants H40A, H67G, and H246G were unaffected as compared to the wild type enzyme. In contrast, H241G demonstrates a >10-fold increase in K(M) for both PEP and A 5-P and a 4-fold reduction in k(cat), while H97G demonstrates an increase in K(M) for only A 5-P and a 2-fold reduction in k(cat). The activity of the H202G mutant was too low to be measured accurately but the data obtained indicated an approximate 400-fold reduction in k(cat). Circular dichroism measurements of the wild-type and mutant enzymes indicate modest structural changes in only the fully active H67G and H246G mutants. The H241G mutant is protected against DEPC inactivation by PEP and A 5-P to the same extent as the wild-type enzyme, suggesting that the functionally important H241 may not be located in the vicinity of the substrate binding sites. The H97G mutant is protected by PEP against DEPC inactivation to the same degree as the wild-type enzyme but is no longer protected by A 5-P. In the case of the H202G mutant, both A 5-P and PEP protect the mutant against DEPC inactivation but to different extents from those observed for the wild-type enzyme. The catalytic activity of the H97G mutant is partially restored (20% --> 60% of wild-type activity) in the presence of imidazole, while a minor amount of activity is restored to the H202G mutant (<1% --> 4% of wild-type activity) in the presence of imidazole.     

Conserved cysteine 126 in triosephosphate isomerase is required not for enzymatic activity but for proper folding and stability

In triosephosphate isomerase, Cys126 is a conserved residue located close to the catalytic glutamate, Glu165. Although it has been mentioned that Cys126 and other nearby residues are required to maintain the active site geometry optimal for catalysis, no evidence supporting this idea has been reported to date. In this work, we studied the catalytic and stability properties of mutants C126A and C126S of Saccharomyces cerevisiae TIM (wtTIM). None of these amino acid replacements induced significant changes in the folding of wtTIM, as indicated by spectroscopic studies. C126S and C126A have K(M) and k(cat) values that are concomitantly reduced by only 4-fold and 1.5-fold, respectively, compared to those of wtTIM; in either case, however, the catalytic efficiency (k(cat)/K(M)) of the enzyme is barely affected. The affinity of mutated TIMs for the competitive inhibitor 2-phosphoglycolate augmented also slightly. In contrast, greater susceptibility to thermal denaturation resulted from mutation of Cys126, especially when it was changed to Ser. By using values of the rate constants for unfolding and refolding, we estimated that, at 25 degrees C, C126A and C126S are less stable than wtTIM by about 5.0 and 9.0 kcal mol(-)(1), respectively. Moreover, either of these mutations slows down the folding rate by a factor of 10 and decreases the recovery of the active enzyme after thermal unfolding. Thus, Cys126 is required for proper stability and efficient folding of TIM rather than for enzymatic catalysis.     

Mechanism of the family 1 beta-glucosidase from Streptomyces sp: catalytic residues and kinetic studies

The Streptomyces sp. beta-glucosidase (Bgl3) is a retaining glycosidase that belongs to family 1 glycosyl hydrolases. Steady-state kinetics with p-nitrophenyl beta-D-glycosides revealed that the highest k(cat)/K(M) values are obtained with glucoside (with strong substrate inhibition) and fucoside (with no substrate inhibition) substrates and that Bgl3 has 10-fold glucosidase over galactosidase activity. Reactivity studies by means of a Hammett analysis using a series of substituted aryl beta-glucosides gave a biphasic plot log k(cat) vs pK(a) of the phenol aglycon: a linear region with a slope of beta(lg) = -0.8 for the less reactive substrates (pK(a) > 8) and no significant dependence for activated substrates (pK(a) < 8). Thus, according to the two-step mechanism of retaining glycosidases, formation of the glycosyl-enzyme intermediate is rate limiting for the former substrates, while hydrolysis of the intermediate is for the latter. To identify key catalytic residues and on the basis of sequence similarity to other family 1 beta-glucosidases, glutamic acids 178 and 383 were changed to glutamine and alanine by site-directed mutagenesis. Mutation of Glu178 to Gln and Ala yielded enzymes with 250- and 3500-fold reduction in their catalytic efficiencies, whereas larger reduction (10(5)-10(6)-fold) were obtained for mutants at Glu383. The functional role of both residues was probed by a chemical rescue methodology based on activation of the inactive Ala mutants by azide as exogenous nucleophile. The E178A mutant yielded the beta-glucosyl azide adduct (by (1)H NMR) with a 200-fold increase on k(cat) for the 2,4-dinitrophenyl glucoside but constant k(cat)/K(M) on azide concentration. On the other hand, the E383A mutant with the same substrate gave the alpha-glucosyl azide product and a 100-fold increase in k(cat) at 1 M azide. In conclusion, Glu178 is the general acid/base catalyst and Glu383 the catalytic nucleophile. The results presented here indicate that Bgl3 beta-glucosidase displays kinetic and mechanistic properties similar to other family 1 enzymes analyzed so far. Subtle differences in behavior would lie in the fine and specific architecture of their respective active sites.