Identification of active site residues by site-directed mutagenesis of delta 5-3-ketosteroid isomerase from Pseudomonas putida biotype B.

In order to assess the roles of specific amino acid residues in the delta 5-3-ketosteroid isomerase from Pseudomonas putida biotype B during catalysis, we replaced aspartic acid 40 with asparagine (D40N) and tyrosine 16 with phenylalanine (Y16F) in the enzyme by site-directed mutagenesis. Both purified mutant enzymes resulted in profound decreases in catalytic activities, 10(3.3)-fold in the Y16F mutant and 10(6.2)-fold in the D40N mutant. Aspartic acid 40 and tyrosine 16 of the enzyme are the corresponding amino acids in the active site of the homologous enzyme from Comamonas testosteroni. Our results indicate that active-site residues of the two homologous enzymes are similar. This is opposite to the previous identification of a cysteine in an active site-directed photoinactivation study of the enzyme.     

Functional analysis of active site residues of Bacillus thuringiensis WB7 chitinase by site-directed mutagenesis

To investigate the roles of the active site residues in the catalysis of Bacillus thuringiensis WB7 chitinase, twelve mutants, F201L, F201Y, G203A, G203D, D205E, D205N, D207E, D207N, W208C, W208R, E209D and E209Q were constructed by site-directed mutagenesis. The results showed that the mutants F201L, G203D, D205N, D207E, D207N, W208C and E209D were devoid of activity, and the loss of the enzymatic activities for F201Y, G203A, D205E, W208R and E209Q were 72, 70, 48, 31 and 29%, respectively. The pH-activity profiles indicated that the optimum pH for the mutants as well as for the wildtype enzyme was 8.0. E209Q exhibited a broader active pH range while D205E, G203A and F201Y resulted in a narrower active pH range. The pH range of activity reduced 1 unit for D205E, and 2 units for G203A and F201Y. The temperature-activity profiles showed that the optimum temperature for other mutants as well as wildtype enzyme was 60°C, but 50°C for G203A, which suggested that G203A resulted in a reduction of thermostability. The study indicated that the six active site residues involving in mutagenesis played an important part in WB7 chitinase. In addition, the catalytic mechanisms of the six active site residues in WB7 chitinase were discussed.     

Production of L-ribose from L-ribulose by a triple-site variant of mannose-6-phosphate isomerase from Geobacillus thermodenitrificans

A triple-site variant (W17Q N90A L129F) of mannose-6-phosphate isomerase from Geobacillus thermodenitrificans was obtained by combining variants with residue substitutions at different positions after random and site-directed mutagenesis. The specific activity and catalytic efficiency (k(cat)/K(m)) for L-ribulose isomerization of this variant were 3.1- and 7.1-fold higher, respectively, than those of the wild-type enzyme at pH 7.0 and 70°C in the presence of 1 mM Co(2+). The triple-site variant produced 213 g/liter l-ribose from 300 g/liter L-ribulose for 60 min, with a volumetric productivity of 213 g liter(-1) h(-1), which was 4.5-fold higher than that of the wild-type enzyme. The k(cat)/K(m) and productivity of the triple-site variant were approximately 2-fold higher than those of the Thermus thermophilus R142N variant of mannose-6-phosphate isomerase, which exhibited the highest values previously reported.     

Mutagenesis of catalytically important residues of cupin type phosphoglucose isomerase from Archaeoglobus fulgidus

Recently, cupin type phosphoglucose isomerases have been described as a novel protein family representing a separate lineage in the evolution of phosphoglucose isomerases. The importance of eight active site residues completely conserved within the cPGI family has been assessed by site-directed mutagenesis using the cPGI from Archaeoglobus fulgidus (AfcPGI) as a model. The mutants T63A, G79A, G79L, H80A, H80D, H82A, E93A, E93D, Y95F, Y95K, H136A, and Y160F were constructed, purified, and the impact of the respective mutation on catalysis and/or metal ion binding as well as thermostability was analyzed. The variants G79A, G79L, and Y95F exhibited a lower thermostability. The catalytic efficiency of the enzyme was reduced by more than 100-fold in the G79A, G79L, H80A, H80D, E93D, Y95F variants and more than 15-fold in the T63A, H82A, Y95K, Y160F variants, but remained about the same in the H136A variant at Ni2+ saturating conditions. Further, the Ni2+ content of the mutants H80A, H80D, H82A, E93A, E93D and their apparent Ni2+ binding ability was reduced, resulting in an almost complete loss of activity and thus underlining the crucial role of the metal ion for catalysis. Evidence is presented that H80, H82 and E93 play an additional role in catalysis besides metal ion binding. E93 appears to be the key catalytic residue of AfcPGI, as the E93A mutant did not show any catalytic activity at all.     

Replacement of tyrosine 181 by phenylalanine in gentisate 1,2-dioxygenase I from Pseudomonas alcaligenes NCIMB 9867 enhances catalytic activities

xlnE, encoding gentisate 1,2-dioxygenase (EC 1.13.11.4), from Pseudomonas alcaligenes (P25X) was mutagenized by site-directed mutagenesis. The mutant enzyme, Y181F, demonstrated 4-, 3-, 6-, and 16-fold increases in relative activity towards gentisate and 3-fluoro-, 4-methyl-, and 3-methylgentisate, respectively. The specific mutation conferred a 13-fold higher catalytic efficiency (k_cat/K_m) on Y181F towards 3-methylgentisate than that of the wild-type enzyme.     

Improved oligosaccharide synthesis by protein engineering of beta-glucosidase CelB from hyperthermophilic Pyrococcus furiosus

Enzymatic transglycosylation of lactose into oligosaccharides was studied using wild-type beta-glucosidase (CelB) and active site mutants thereof (M424K, F426Y, M424K/F426Y) and wild-type beta-mannosidase (BmnA) of the hyperthermophilic Pyrococcus furiosus. The effects of the mutations on kinetics, enzyme activity, and substrate specificity were determined. The oligosaccharide synthesis was carried out in aqueous solution at 95 degrees C at different lactose concentrations and pH values. The results showed enhanced synthetic properties of the CelB mutant enzymes. An exchange of one phenylalanine to tyrosine (F426Y) increased the oligosaccharide yield (45%) compared with the wild-type CelB (40%). Incorporation of a positively charged group in the active site (M424K) increased the pH optimum of transglycosylation reaction of CelB. The double mutant, M424K/F426Y, showed much better transglycosylation properties at low (10-20%) lactose concentrations compared to the wild-type. At a lactose concentration of 10%, the oligosaccharide yield for the mutant was 40% compared to 18% for the wild-type. At optimal reaction conditions, a higher ratio of tetrasaccharides to trisaccharides was obtained with the double mutant (0.42, 10% lactose) compared to the wild-type (0.19, 70% lactose). At a lactose concentration as low as 10%, only trisaccharides were synthesized by CelB wild-type. The beta-mannosidase BmnA from P. furiosus showed both beta-glucosidase and beta-galactosidase activity and in the transglycosylation of lactose the maximal oligosaccharide yield of BmnA was 44%. The oligosaccharide yields obtained in this study are high compared to those reported with other transglycosylating beta-glycosidases in oligosaccharide synthesis from lactose.     

Purification, characterization and thermal inactivation kinetics of a non-regioselective thermostable lipase from a genotypically identified extremophilic Bacillus subtilis NS 8

Thermostable lipase produced by a genotypically identified extremophilic Bacillus subtilis NS 8 was purified 500-fold to homogeneity with a recovery of 16% by ultrafiltration, DEAE-Toyopearl 650M and Sephadex G-75 column. The purified enzyme showed a prominent single band with a molecular weight of 45 kDa. The optimum pH and temperature for activity of lipase were 7.0 and 60°C, respectively. The enzyme was stable in the pH range between 7.0 and 9.0 and temperature range between 40 and 70°C. It showed high stability with half-lives of 273.38 min at 60°C, 51.04 min at 70°C and 41.58 min at 80°C. The D-values at 60, 70 and 80°C were 788.70, 169.59 and 138.15 min, respectively. The enzyme's enthalpy, entropy and Gibb's free energy were in the range of 70.07-70.40 kJ mol(-1), -83.58 to -77.32 kJ mol(-1)K(-1) and 95.60-98.96 kJ mol(-1), respectively. Lipase activity was slightly enhanced when treated with Mg(2+) but there was no significant enhancement or inhibition of the activity with Ca(2+). However, other metal ions markedly inhibited its activity. Of all the natural vegetable oils tested, it had slightly higher hydrolytic activity on soybean oil compared to other oils. On TLC plate, the enzyme showed non-regioselective activity for triolein hydrolysis.     

How can a catalytic lesion be offset? The energetics of two pseudorevertant triosephosphate isomerases

The reaction energetics of four triosephosphate isomerase mutants are compared with those of the wild-type enzyme. The two primary mutants, E165D and H95N, contain site-specific alterations of active site residues. In one case the active site base has been altered (E165D), and in the other, an active site electrophile has been removed (H95N), yet the major effect in each case is the relative destabilization of the transition states for the two chemical (enolization) steps that constitute the catalytic reaction. When the genes encoding each of these sluggish mutant isomerases were subjected to random mutagenesis using chemical reagents and a selection for isomerases of increased catalytic potency was performed, pseudorevertant enzymes with dramatic increases in activity were found. Remarkably, the same second-site suppressor locus partially corrects each lesion. The E165D,S96P pseudorevertant is a 20-fold better catalyst than the E165D mutant from which it is derived, and the H95N,S96P pseudorevertant is about 60 times more active than its H95N parent. The S96P substitution thus increases the catalytic activity in each of two different contexts, H95N and E165D. The energetic consequences of the S96P change are suprisingly similar in each pseudorevertant. The H95N,S96P enzyme is more effective than H95N at stabilizing the intermediate enediol(ate) phosphate and its flanking transition states. The E165D,S96P enzyme likewise stabilizes the transition states for enolization better than E165D, and this pseudorevertant also forms a tighter enzyme-dihydroxyacetone phosphate complex than its parent. These data show how, in these two cases, the catalytic potency of sluggish mutant enzymes can be improved by second-site changes. The results thus provide the beginnings of a detailed understanding of the kinetic refinement of enzyme catalysts.     

An active site homology model of phenylalanine ammonia-lyase from Petroselinum crispum.

The plant enzyme phenylalanine ammonia-lyase (PAL, EC 4.3.1.5) shows homology to histidine ammonia-lyase (HAL) whose structure has been solved by X-ray crystallography. Based on amino-acid sequence alignment of the two enzymes, mutagenesis was performed on amino-acid residues that were identical or similar to the active site residues in HAL to gain insight into the importance of this residues in PAL for substrate binding or catalysis. We mutated the following amino-acid residues: S203, R354, Y110, Y351, N260, Q348, F400, Q488 and L138. Determination of the kinetic constants of the overexpressed and purified enzymes revealed that mutagenesis led in each case to diminished activity. Mutants S203A, R354A and Y351F showed a decrease in kcat by factors of 435, 130 and 235, respectively. Mutants F400A, Q488A and L138H showed a 345-, 615- and 14-fold lower kcat, respectively. The greatest loss of activity occurred in the PAL mutants N260A, Q348A and Y110F, which were 2700, 2370 and 75 000 times less active than wild-type PAL. To elucidate the possible function of the mutated amino-acid residues in PAL we built a homology model of PAL based on structural data of HAL and mutagenesis experiments with PAL. The homology model of PAL showed that the active site of PAL resembles the active site of HAL. This allowed us to propose possible roles for the corresponding residues in PAL catalysis.     

Creatine kinase: a role for arginine-95 in creatine binding and active site organization

Sequence homology analysis reveals that arginine-95 is fully conserved in 29 creatine kinases sequenced to date, but fully conserved as a tyrosine residue in 16 arginine kinases. Site-directed mutants of rabbit muscle creatine kinase (rmCK) were prepared in which R95 was replaced by a tyrosine (R95Y), alanine (R95A), or lysine (R95K). Kinetic analysis of phosphocreatine formation for each purified mutant showed that recombinant native rmCK and all R95 mutants follow a random-order, rapid-equilibrium mechanism. However, we observed no evidence for synergism of substrate binding by the recombinant native enzyme, as reported previously [Maggio et al., (1977) J. Biol. Chem. 252, 1202-1207] for creatine kinase isolated directly from rabbit muscle. The catalytic efficiencies of R95Y and R95A are reduced approximately 3000- and 2000-fold, respectively, compared to native enzyme, but that of R95K is reduced only 30-fold. The major contribution to the reduction of the catalytic efficiency of R95K is a 5-fold reduction in the affinity for creatine. This suggests that while a basic residue is required at position 95 for optimal activity, R95 is not absolutely essential for binding or catalysis in CK. R95Y has a significantly lower affinity for creatine than the native enzyme, but it also displays a somewhat lower affinity for MgATP and 100-fold reduction in k(cat). Interestingly, R95A appears to bind either creatine or MgATP first with affinities similar to those for the native enzyme, but it has a 10-fold lower affinity for the second substrate, suggesting that replacement of R95 by an alanine disrupts the active site organization and reduces the efficiency of formation of the catalytically competent ternary complex.     

Adaptation of a thermophilic enzyme, 3-isopropylmalate dehydrogenase, to low temperatures

Random mutagenesis coupled with screening of the active enzyme at a low temperature was applied to isolate cold-adapted mutants of a thermophilic enzyme. Four mutant enzymes with enhanced specific activities (up to 4.1-fold at 40 degrees C) at a moderate temperature were isolated from randomly mutated Thermus thermophilus 3-isopropylmalate dehydrogenase. Kinetic analysis revealed two types of cold-adapted mutants, i.e. k(cat)-improved and K(m)-improved types. The k(cat)-improved mutants showed less temperature-dependent catalytic properties, resulting in improvement of k(cat) (up to 7.5-fold at 40 degrees C) at lower temperatures with increased K(m) values mainly for NAD. The K(m)-improved enzyme showed higher affinities toward the substrate and the coenzyme without significant change in k(cat) at the temperatures investigated (30-70 degrees C). In k(cat)-improved mutants, replacement of a residue was found near the binding pocket for the adenine portion of NAD. Two of the mutants retained thermal stability indistinguishable from the wild-type enzyme. Extreme thermal stability of the thermophilic enzyme is not necessarily decreased to improve the catalytic function at lower temperatures. The present strategy provides a powerful tool for obtaining active mutant enzymes at lower temperatures. The results also indicate that it is possible to obtain cold-adapted mutant enzymes with high thermal stability.     

Enhancement of thermostability of fungal deglycating enzymes by directed evolution

Fructosyl peptide oxidases are valuable for the determination of glycoproteins such as hemoglobin A1c. For practical use in clinical diagnosis, we applied directed evolution to improve the thermostability of these enzymes. After two rounds of random mutagenesis and high-throughput screening, six thermostabilizing amino acid substitutions were identified. Therefore, site-directed and cassette mutageneses were applied to combine these six stabilizing mutations. The simultaneous mutants showed that the stabilizing effect of the amino acid replacement was cumulative. The sextuple mutant enzyme, R94K/G184D/F265L/N272D/H302R/H388Y, had a half-life of thermal inactivation at 50°C that was 79.8-fold longer than that of the parental fructosyl peptide oxidase. The thermostable variants also showed increased tolerance to digestion by a protease. The sextuple mutant enzyme did not lose its activity on incubation with neutral protease, while the wild-type enzyme almost completely lost its activity. Furthermore, three amino acid substitutions were introduced into another fructosyl peptide oxidase with a different substrate specificity. The half-life of inactivation at 50°C was 3.61-fold longer than that of the parent enzyme. These engineered fructosyl peptide oxidases will be useful for industrial application to clinical diagnosis.     

Conserved tyrosine-369 in the active site of Escherichia coli copper amine oxidase is not essential.

Copper amine oxidases are homodimeric enzymes that catalyze two reactions: first, a self-processing reaction to generate the 2,4,5-trihydroxyphenylalanine (TPQ) cofactor from an active site tyrosine by a single turnover mechanism; second, the oxidative deamination of primary amine substrates with the production of aldehyde, hydrogen peroxide, and ammonia catalyzed by the mature enzyme. The importance of active site residues in both of these processes has been investigated by structural studies and site-directed mutagenesis in enzymes from various organisms. One conserved residue is a tyrosine, Tyr369 in the Escherichia coli enzyme, whose hydroxyl is hydrogen bonded to the O4 of TPQ. To explore the importance of this site, we have studied a mutant enzyme in which Tyr369 has been mutated to a phenylalanine. We have determined the X-ray crystal structure of this variant enzyme to 2.1 A resolution, which reveals that TPQ adopts a predominant nonproductive conformation in the resting enzyme. Reaction of the enzyme with the irreversible inhibitor 2-hydrazinopyridine (2-HP) reveals differences in the reactivity of Y369F compared with wild type with more efficient formation of an adduct (lambda(max) = 525 nm) perhaps reflecting increased mobility of the TPQ adduct within the active site of Y369F. Titration with 2-HP also reveals that both wild type and Y369F contain one TPQ per monomer, indicating that Tyr369 is not essential for TPQ formation, although we have not measured the rate of TPQ biogenesis. The UV-vis spectrum of the Y369F protein shows a broader peak and red-shifted lambda(max) at 496 nm compared with wild type (480 nm), consistent with an altered electronic structure of TPQ. Steady-state kinetic measurements reveal that Y369F has decreased catalytic activity particularly below pH 6.5 while the K(M) for substrate beta-phenethylamine increases significantly, apparently due to an elevated pK(a) (5.75-6.5) for the catalytic base, Asp383, that should be deprotonated for efficient binding of protonated substrate. At pH 7.0, the K(M) for wild type and Y369F are similar at 1.2 and 1.5 microM, respectively, while k(cat) is decreased from 15 s(-1) in wild type to 0.38 s(-1), resulting in a 50-fold decrease in k(cat)/K(M) for Y369F. Transient kinetics experiments indicate that while the initial stages of enzyme reduction are slower in the variant, these do not represent the rate-limiting step. Previous structural and solution studies have implicated Tyr369 as a component of a proton shuttle from TPQ to dioxygen. The moderate changes in kinetic parameters observed for the Y369F variant indicate that if this is the case, then the absence of the Tyr369 hydroxyl can be compensated for efficiently within the active site.     

Tyrosine residue 300 is important for activity and stability of branching enzyme from Escherichia coli

Branching enzyme belongs to the alpha-amylase family, which includes enzymes that catalyze hydrolysis or transglycosylation at alpha-(1,4)- or alpha-(1,6)-glucosidic linkages. In the alpha-amylase family, four highly conserved regions are proposed to make up the active site. From amino acid sequence analysis a tyrosine residue is completely conserved in the alpha-amylase family. In Escherichia coli branching enzyme, this residue (Y300) is located prior to the conserved region 1. Site-directed mutagenesis of the Y300 residue in E. coli branching enzyme was used in order to study its possible function in branching enzymes. Replacement of Y300 with Ala, Asp, Leu, Ser, and Trp resulted in mutant enzymes with less than 1% of wild-type activity. A Y300F substitution retained 25% of wild-type activity. Kinetic analysis of Y300F showed no effect on the Km value. The heat stability of Y300F was analyzed, and this was lowered significantly compared to that of the wild-type enzyme. Y300F also showed lower relative activity at elevated temperatures compared to wild-type. Thus, these results show that Tyr residue 300 in E. coli branching enzyme is important for activity and thermostability of the enzyme.     

Alteration of specific activity and stability of thermostable neutral protease by site-directed mutagenesis.

On the basis of three-dimensional information, many amino acid substitutions were introduced in the thermostable neutral protease (NprM) of Bacillus stearothermophilus MK232 by site-directed mutagenesis. When Glu at position 143 (Glu-143), which is one of the proposed active sites, was substituted for by Gln and Asp, the proteolytic activity disappeared. F114A (Phe-114 to Ala), Y110W (Tyr-110 to Trp), and Y211W (Tyr-211 to Trp) mutant enzymes had higher activity (1.3- to 1.6-fold) than the wild-type enzyme. When an autolysis site, Tyr-93, was replaced by Gly and Ser, the remaining activities of those mutant enzymes were higher than that of the wild-type enzyme.     

Xylanase XYL1p from Scytalidium acidophilum: Site-directed mutagenesis and acidophilic adaptation

The role of residues Asp60, Tyr35 and Glu141 in the pH-dependent activity of xylanase XYL1p from Scytalidium acidophilum was investigated by site-directed mutagenesis. These amino acids are highly conserved among the acidophilic family 11 xylanases and located near the catalytic site. XYL1p and its single mutants D60N, Y35W and E141A and three combined mutants DN/YW, DN/EA and YW/EA were over-expressed in Pichia pastoris and purified. Xylanase activities at different pH’s and temperatures were determined. All mutations increased the pH optimum by 0.5–1.5 pH units. All mutants have lower specific activities except the E141A mutant that exhibited a 50% increase in specific activity at pH 4.0 and had an overall catalytic efficiency higher than the wild-type enzyme. Thermal unfolding experiments show that both the wild-type and E141A mutant proteins have a T_m maximum at pH 3.5, the E141A mutant being slightly less stable than the wild-type enzyme. These mutations confirm the importance of these amino acids in the pH adaptation. Mutant E141A with its enhanced specific activity at pH 4.0 and improved overall catalytic efficiency is of possible interest for biotechnological applications.     

Alteration of specific activity and stability of thermostable neutral protease by site-directed mutagenesis.

On the basis of three-dimensional information, many amino acid substitutions were introduced in the thermostable neutral protease (NprM) of Bacillus stearothermophilus MK232 by site-directed mutagenesis. When Glu at position 143 (Glu-143), which is one of the proposed active sites, was substituted for by Gln and Asp, the proteolytic activity disappeared. F114A (Phe-114 to Ala), Y110W (Tyr-110 to Trp), and Y211W (Tyr-211 to Trp) mutant enzymes had higher activity (1.3- to 1.6-fold) than the wild-type enzyme. When an autolysis site, Tyr-93, was replaced by Gly and Ser, the remaining activities of those mutant enzymes were higher than that of the wild-type enzyme.     

The evolution of catalytic efficiency and substrate promiscuity in human theta class 1-1 glutathione transferase

Theta class glutathione transferases (GST) from various species exhibit markedly different catalytic activities in conjugating the tripeptide glutathione (GSH) to a variety of electrophilic substrates. For example, the human theta 1-1 enzyme (hGSTT1-1) is 440-fold less efficient than the rat theta 2-2 enzyme (rGSTT2-2) with the fluorogenic substrate 7-amino-4-chloromethyl coumarin (CMAC). Large libraries of hGSTT1-1 constructed by error-prone PCR, DNA shuffling, or saturation mutagenesis were screened for improved catalytic activity towards CMAC in a quantitative fashion using flow cytometry. An iterative directed evolution approach employing random mutagenesis in conjunction with homologous recombination gave rise to enzymes exhibiting up to a 20,000-fold increase in k(cat)/K(M) compared to hGSTT1-1. All highly active clones encoded one or more mutations at residues 32, 176, or 234. Combinatorial saturation mutagenesis was used to evaluate the full complement of natural amino acids at these positions, and resulted in the isolation of enzymes with catalytic rates comparable to those exhibited by the fastest mutants obtained via directed evolution. The substrate selectivities of enzymes resulting from random mutagenesis, DNA shuffling, and combinatorial saturation mutagenesis were evaluated using a series of distinct electrophiles. The results revealed that promiscuous substrate activities arose in a stochastic manner, as they did not correlate with catalytic efficiency towards the CMAC selection substrate. In contrast, chimeric enzymes previously constructed by homology-independent recombination of hGSTT-1 and rGSTT2-2 exhibited very different substrate promiscuity profiles, and showed a more defined relationship between evolved and promiscuous activities.     

Enhancement of the activity and alkaline pH stability of <Emphasis Type="Italic">Thermobifida fusca</Emphasis> xylanase A by directed evolution

Directed evolution has been used to enhance the catalytic activity and alkaline pH stability of Thermobifida fusca xylanase A, which is one of the most thermostable xylanases. Under triple screened traits of activity, alkaline pH stability and thermostability, through two rounds of random mutagenesis using DNA shuffling, a mutant 2TfxA98 with approximately 12-fold increased k _cat/K _m and 4.5-fold decreased K _m compared with its parent was obtained. Moreover, the alkaline pH stability of 2TfxA98 is increased significantly, with a thermostability slightly lower than that of its parent. Five amino acid substitutions (T21A, G25P, V87P, I91T, and G217L), three of them are near the catalytic active site, were identified by sequencing the genes encoding this evolved enzyme. The activity and stabilizing effects of each amino acid mutation in the evolved enzyme were evaluated by site-directed mutagenesis. This study shows a useful approach to improve the catalytic activity and alkaline pH stability of T. fusca xylanase A toward the hydrolysis of xylan.     

The influence of conserved aromatic residues in 3-hydroxy-3-methylglutaryl-CoA synthase

In order to evaluate the potential contribution of conserved aromatic residues to the hydrophobic active site of 3-hydroxy-3-methylglutaryl-CoA synthase, site-directed mutagenesis was employed to produce Y130L, Y163L, F204L, Y225L, Y346L, and Y376L proteins. Each mutant protein was expressed at levels comparable with wild-type enzyme and was isolated in highly purified form. Initial kinetic characterization indicated that F204L exhibits a substantial (>300-fold) decrease in catalytic rate (kcat). Upon modification with the mechanism-based inhibitor, 3-chloropropionyl-CoA, or in formation of a stable binary complex with acetoacetyl-CoA, F204L exhibits binding stoichiometries comparable with wild-type enzyme, suggesting substantial retention of active site integrity. Y130L and Y376L exhibit inflated values (80- and 40-fold, respectively) for the Km for acetyl-CoA in the acetyl-CoA hydrolysis partial reaction; these mutants also exhibit an order of magnitude decrease in kcat. Formation of the acetyl-S-enzyme reaction intermediate by Y130L, F204L, and Y376L proceeds slowly in comparison with wild-type enzyme. However, solvent exchange into the thioester carbonyl oxygen of these acetyl-S-enzyme intermediates is not slow in comparison with previous observations for D159A and D203A mutants, which also exhibit slow acetyl-S-enzyme formation. The magnitude of the differential isotope shift upon exchange of H218O into [13C]acetyl-S-enzyme suggests a polarization of the thioester carbonyl and a reduction in bond order. Such an effect may substantially contribute to the upfield 13C NMR shift observed for [13C]acetyl-S-enzyme. The influence on acetyl-S-enzyme formation, as well as observed kcat (F204L) and Km (Y130L; Y376L) effects, implicate these invariant residues as part of the catalytic site. Substitution of phenylalanine (Y130F, Y376F) instead of leucine at residues 130 and 376 diminishes the effects on catalytic rate and substrate affinity observed for Y130L and Y376L, underscoring the influence of aromatic side chains near the active site.