Probing the essential catalytic residues and substrate affinity in the thermoactive Bacillus stearothermophilus US100 L-arabinose isomerase by site-directed mutagenesis

The L-arabinose isomerase (L-AI) from Bacillus stearothermophilus US100 is characterized by its high thermoactivity and catalytic efficiency. Furthermore, as opposed to the majority of l-arabinose isomerases, this enzyme requires metallic ions for its thermostability rather than for its activity. These features make US100 L-AI attractive as a template for industrial use. Based on previously solved crystal structures and sequence alignments, we identified amino acids that are putatively important for the US100 L-AI isomerization reaction. Among these, E306, E331, H348, and H447, which correspond to the suggested essential catalytic amino acids of the L-fucose isomerase and the L-arabinose isomerase from Escherichia coli, are presumed to be the active-site residues of US100 L-AI. Site-directed mutagenesis confirmed that the mutation of these residues resulted in totally inactive proteins, thus demonstrating their critical role in the enzyme activity. A homology model of US100 L-AI was constructed, and its analysis highlighted another set of residues which may be crucial for the recognition and processing of substrates; hence, these residues were subjected to mutagenesis studies. The replacement of the D308, F329, E351, and H446 amino acids with alanine seriously affected the enzyme activities, and suggestions about the roles of these residues in the catalytic mechanism are given. The mutation F279Q strongly increased the enzyme's affinity for L-fucose and decreased the affinity for L-arabinose compared to that of the wild-type enzyme, showing the implication of this amino acid in substrate recognition.     

Studies on the allosteric nature of acetate kinase from Bacillus stearothermophilus.

Fructose 1,6-bisphosphate (FBP) stimulates the reaction of Bacillus stearothermophilus acetate kinase (AK). FBP changes the reaction curve for ATP from a sigmoidal type to a Michaelis-Menten one. The binding of FBP to AK was studied by an equilibrium dialysis method and by measuring changes in fluorescence. The extent of binding of FBP to the enzyme paralleled its activation. In addition, the binding constant for FBP increased in the presence of substrate, ATP. These results suggest that FBP is an allosteric activator of B. stearothermophilus AK. Only two moles of FBP bound to this tetrameric enzyme. No cooperativity was found for the binding of FBP. These observations support the previous conclusion, that a set of two subunits in the tetramer is a unit of the enzymatic function. A model is presented to interpret the sigmoidal kinetics for ATP, the absence of cooperativity for FBP binding, and the allosteric activation by FBP of this enzyme. The kinetic properties of the enzyme can be explained quantitatively by this model.     

Purification and properties of pyruvate kinase from Bacillus stearothermophilus

Pyruvate kinase was purified to homogeneity from a moderate thermophile, Bacillus stearothermophilus. The molecular weight of the enzyme was found to be 250,000 on gel filtration and 242,000 on sedimentation analysis. The enzyme consisted of four identical subunits of a molecular weight of 62,000-64,000. There were no remarkable differences between the thermophilic enzyme and mesophilic enzymes in amino acid composition, secondary structure, mono- and di-valent cation requirements for activity or specificity for nucleoside diphosphates. But the thermophilic enzyme was stable at high temperature and for a longer period of storage at lower temperature. Its specific activity was relatively high even at a low temperature (30 degrees C). The enzyme exhibited homotropic positive cooperativity for phosphoenol-pyruvate, but not for ADP. It was allosterically activated by AMP, ribose 5-phosphate and nucleoside monophosphates, but not by fructose 1,6-bisphosphate. Activation by AMP and ribose 5-phosphate, and inhibition by inorganic phosphate were also observed even at the physiological temperature (60 degrees C) for the thermophile.     

The putative effector-binding site of Leishmania mexicana pyruvate kinase studied by site-directed mutagenesis

The activity of pyruvate kinase of Leishmania mexicana is allosterically regulated by fructose 2,6-bisphosphate (F-2,6-P(2)), contrary to the pyruvate kinases from other eukaryotes that are usually stimulated by fructose 1,6-bisphosphate (F-1,6-P(2)). Based on the comparison of the three-dimensional structure of Saccharomyces cerevisiae pyruvate kinase crystallized with F-1,6-P(2) present at the effector site (R-state) and the L. mexicana enzyme crystallized in the T-state, two residues (Lys453 and His480) were proposed to bind the 2-phospho group of the effector. This hypothesis was tested by site-directed mutagenesis. The allosteric activation by F-2,6-P(2) appeared to be entirely abrogated in the mutated enzymes confirming our predictions.     

Identification of critical residues of the mycobacterial dephosphocoenzyme a kinase by site-directed mutagenesis

Dephosphocoenzyme A kinase performs the transfer of the γ-phosphate of ATP to dephosphocoenzyme A, catalyzing the last step of coenzyme A biosynthesis. This enzyme belongs to the P-loop-containing NTP hydrolase superfamily, all members of which posses a three domain topology consisting of a CoA domain that binds the acceptor substrate, the nucleotide binding domain and the lid domain. Differences in the enzymatic organization and regulation between the human and mycobacterial counterparts, have pointed out the tubercular CoaE as a high confidence drug target (HAMAP database). Unfortunately the absence of a three-dimensional crystal structure of the enzyme, either alone or complexed with either of its substrates/regulators, leaves both the reaction mechanism unidentified and the chief players involved in substrate binding, stabilization and catalysis unknown. Based on homology modeling and sequence analysis, we chose residues in the three functional domains of the enzyme to assess their contributions to ligand binding and catalysis using site-directed mutagenesis. Systematically mutating the residues from the P-loop and the nucleotide-binding site identified Lys14 and Arg140 in ATP binding and the stabilization of the phosphoryl intermediate during the phosphotransfer reaction. Mutagenesis of Asp32 and Arg140 showed catalytic efficiencies less than 5-10% of the wild type, indicating the pivotal roles played by these residues in catalysis. Non-conservative substitution of the Leu114 residue identifies this leucine as the critical residue from the hydrophobic cleft involved in leading substrate, DCoA binding. We show that the mycobacterial enzyme requires the Mg(2+) for its catalytic activity. The binding energetics of the interactions of the mutant enzymes with the substrates were characterized in terms of their enthalpic and entropic contributions by ITC, providing a complete picture of the effects of the mutations on activity. The properties of mutants defective in substrate recognition were consistent with the ordered sequential mechanism of substrate addition for CoaE.     

The use of site-directed mutagenesis and time-resolved fluorescence spectroscopy to assign the fluorescence contributions of individual tryptophan residues in Bacillus stearothermophilus lactate dehydrogenase

Site-directed mutagenesis has been used to generate two mutant Bacillus stearothermophilus lactate dehydrogenases: in one, Trp-150 has been replaced with a tyrosine residue and, in the other, both Trp-150 and -80 are replaced with tyrosines. Both enzymes are fully catalytically active and their affinities for substrates and coenzymes, and thermal stabilities are very similar to those of the native enzyme. Time-resolved fluorescence measurements using a synchrotron source have shown that all three tryptophans in the native enzyme fluoresce. By comparing the mutant and native enzymes it was possible, for the first time, to assign, unambiguously, lifetimes to the individual tryptophans: Trp-203 (7.4 ns), Trp-80 (2.35 ns) and Trp-150 (less than 0.3 ns). Trp-203 is responsible for 75-80% of the steady-state fluorescence emission, Trp-80 for 20%, and Trp-150 for less than 2%.     

Improvement of the catalytic performance of glycerol kinase from Bacillus subtilis by chromosomal site-directed mutagenesis

Biotechnology Letters - Glycerol kinase is the key enzyme in glycerol metabolism, and its catalytic efficiency has an important effect on glycerol utilization. Based on an analysis of the glycerol...     

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.     

Mutagenesis of the active site lysine 221 of the pyruvate kinase from Bacillus stearothermophilus

Lysine 221 of the pyruvate kinase from Bacillus stearothermophilus was mutated to arginine, leucine, asparatic acid and cysteine. All the mutated enzymes were 10(4) to 10(5) times less active than the wild-type enzyme. The cysteine-free enzyme C9S/C268S, and the enzyme C9S/C268S/K221C, which possessed a unique sulfhydryl group at position 221, were prepared. The former had comparable activity to the wild-type enzyme and the latter was 10(4) times less active. These enzymes were denatured and renatured after aminoethylation. The C9S/C268S/K221C enzyme failed to regain its activity when renatured without aminoethylation; but when it was renatured after aminoethylation, it regained 4.5% of the activity of the C9S/C268S enzyme. This evidence suggests the importance of the Lys221 for the pyruvate kinase activity. The kinetic parameters of the S-aminoethylated C9S/C268S/K221C enzyme suggest that it has decreased affinity for phosphoenolpyruvate.     

Site-directed mutagenesis in Bacillus stearothermophilus fructose-6-phosphate 1-kinase. Mutation at the substrate-binding site affects allosteric behavior

Arg252 of fructose-6-phosphate 1-kinase (PFK) from Bacillus stearothermophilus has been proposed to be involved in the binding of the substrate Fru-6-P. We demonstrate here that mutation of this residue to alanine converts the enzyme to a form with characteristics similar to those of its allosterically tight form. The mutant enzyme exhibits a high affinity for its inhibitor phosphoenolpyruvate (a 68-fold difference compared to wild type) and a dramatically decreased Fru-6-P affinity (1500-fold increase in Km). It is more sensitive to inhibition by high ATP concentrations than the wild type, and this inhibition is relieved by ADP, GDP, or higher Fru-6-P concentrations. In contrast, mutation of Arg252 to lysine increases the affinity of the enzyme for P-enolpyruvate by only 2-fold and increases its Km for Fru-6-P by only 50-fold. Sigmoidal kinetics with respect to Fru-6-P in the presence of P-enolpyruvate were observed with Hill numbers of 2.2, 2.4, and 1.7 for wild-type B. stearothermophilus PFK and the Arg252 to lysine and to alanine mutations, respectively. Unlike fructose-6-phosphate 1-kinase from Escherichia coli, in the absence of P-enolpyruvate, B. stearothermophilus PFK exhibits a hyperbolic profile with respect to Fru-6-P concentration. B. stearothermophilus PFK is sensitive to inhibition by high ATP concentrations and competitively inhibited by GDP or ADP. Our data indicate that Arg252 of B. stearothermophilus PFK plays a major role in both Fru-6-P binding and allosteric interaction between the subunits. However, this residue does not seem to participate directly in the catalytic process.     

Identification of residues involved in v-Src substrate recognition by site-directed mutagenesis.

To study the role of the catalytic domain in v-Src substrate specificity, we engineered three site-directed mutants (Leu-472 to Tyr or Trp and Thr-429 to Met). The mutant forms of Src were expressed in Sf9 cells and purified. We analyzed the substrate specificities of wild-type v-Src and the mutants using two series of peptides that varied at residues C-terminal to tyrosine. The peptides contained either the YMTM motif found in insulin receptor substrate-1 (IRS-1) or the YGEF motif identified from peptide library experiments to be the optimal sequence for Src. Mutations at positions Leu-472 or Thr-429 caused changes in substrate specificity at positions P+1 and P+3 (i.e. one or three residues C-terminal to tyrosine). This was particularly evident in the case of the L-472W mutant, which had pronounced alterations in its preferences at the P+1 position. The results suggest that residue Leu-472 plays a role in P+1 substrate recognition by Src. We discuss the results in the light of recent work on the roles of the SH2, SH3 and catalytic domains of Src in substrate specificity.     

Mechanism of allosteric modulation of Escherichia coli carbamoyl phosphate synthetase probed by site-directed mutagenesis of ornithine site residues

The role of residues of the ornithine activator site is probed by mutagenesis in Escherichia coli carbamoyl phosphate synthetase (CPS). Mutations E783A, E783L, E892A and E892L abolish ornithine binding, E783D and T1042V decrease 2-3 orders of magnitude and E892D decreased 10-fold apparent affinity for ornithine. None of the mutations inactivates CPS. E783 mutations hamper carbamate phosphorylation and increase K(+) and MgATP requirements, possibly by perturbing the K(+)-loop near the carbamate phosphorylation site. Mutation E892A activates the enzyme similarly to ornithine, possibly by altering the position of K891 at the opening of the tunnel that delivers the carbamate to its phosphorylation site. T1042V also influences modulation by IMP and UMP, supporting signal transmission from the nucleotide effector to the ornithine site mediated by a hydrogen bond network involving T1042. Ornithine activation of CPS may be mediated by K(+)-loop and tunnel gating changes.     

Energetics of allosteric regulation in muscle pyruvate kinase.

The regulatory mechanism of rabbit muscle pyruvate kinase has been studied as a function of temperature in conjunction with phenylalanine, the allosteric inhibitor. The inhibitory effect of phenylalanine is modulated by temperature. At low temperatures, the presence of phenylalanine is almost inconsequential, but as the temperature increases so does the phenylalanine-dependent inhibition of the kinetic activity. In addition, the presence of phenylalanine induces cooperativity in the relation between velocity and substrate concentration. This effect is especially pronounced at elevated temperature. The kinetic data were analyzed using an equation that describes the steady-state kinetic velocity data as a function of five equilibrium constants and two rate constants. Van't Hoff analysis of the temperature dependence of the equilibrium constants determined by nonlinear curve fitting revealed that the interaction of pyruvate kinase with its substrate, phosphoenolpyruvate, is an enthalpy-driven process. This is consistent with an interaction that involves electrostatic forces, and indeed, phosphoenolpyruvate is a negatively charged substrate. In contrast, the interaction of pyruvate kinase with phenylalanine is strongly entropy driven. These results imply that the binding of phenylalanine involves hydrophobic interaction and are consistent with the basic concepts of strengthening of the hydrophobic effect with an increase in temperature. The effect of phenylalanine at high temperatures is the net consequence of weakening of substrate-enzyme interaction and significant strengthening of inhibitor binding to the inactive state of pyruvate kinase. The effects of salts were also studies. The results show that salts also exert a differential effect on the binding of substrate and inhibitor to the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Roles of cysteinyl residues of phosphoribulokinase as examined by site-directed mutagenesis.

The Calvin Cycle enzyme phosphoribulokinase is activated in higher plants by the reversible reduction of a disulfide bond, which is located at the active site. To determine the possible contribution of the two regulatory residues (Cys16 and Cys55) to catalysis, site-directed mutagenesis has been used to replace each of them in the spinach enzyme with serine or alanine. The only other cysteinyl residues of the kinase, Cys244 and Cys250, were also replaced individually by serine or alanine. A comparison of specific activities of native and mutant enzymes reveals that substitutions at positions 244 or 250 are inconsequential. The position 16 mutants retain 45-90% of the wild-type activity and display normal Km values for both ATP and ribulose 5-phosphate. In contrast, substitution at position 55 results in 85-95% loss of wild-type activity, with less than a 2-fold increase in the Km for ATP and a 4-8-fold increase in the Km for ribulose 5-phosphate. These results are consistent with moderate facilitation of catalysis by Cys55 and demonstrate that the other three cysteinyl residues do not contribute significantly either to structure or catalysis. The enhanced stability, relative to wild-type enzyme, of the Ser16 mutant protein to a sulfhydryl reagent supports earlier suggestions that Cys16 is the initial target of the oxidative deactivation process.     

Identification of catalytically essential residues in Escherichia coli esterase by site-directed mutagenesis.

Escherichia coli esterase (EcE) is a member of the hormone-sensitive lipase family. We have analyzed the roles of the conserved residues in this enzyme (His103, Glu128, Gly163, Asp164, Ser165, Gly167, Asp262, Asp266 and His292) by site-directed mutagenesis. Among them, Gly163, Asp164, Ser165, and Gly167 are the components of a G-D/E-S-A-G motif. We showed that Ser165, Asp262, and His292 are the active-site residues of the enzyme. We also showed that none of the other residues, except for Asp164, is critical for the enzymatic activity. The mutation of Asp164 to Ala dramatically reduced the catalytic efficiency of the enzyme by the factor of 10(4) without seriously affecting the substrate binding. This residue is probably structurally important to make the conformation of the active-site functional.     

Site-directed mutagenesis of a thermostable alpha-amylase from Bacillus stearothermophilus: putative role of three conserved residues.

The relationship between structure, activity, and stability of the thermostable Bacillus stearothermophilus alpha-amylase was studied by site-directed mutagenesis of the three most conserved residues. Mutation of His-238 to Asp involved in Ca2+ and substrate binding reduced the specific activity and thermal stability, but did not affect the pH and temperature optima. Replacement of Asp-331 by Glu in the active site caused almost total inactivation. Interestingly, in prolonged incubation this mutant enzyme showed an altered end-product profile by liberating only maltose and maltotriose. Conservative mutation of the conserved Arg-232 by Lys, for which no function has yet been proposed, resulted in lowered specific activity: around 12% of the parental enzyme. This mutant enzyme had a wider pH range but about the same temperature optimum and thermal stability as the wild-type enzyme. Results obtained with different mutants were interpreted by computer aided molecular modeling.     

The allosteric regulation of pyruvate kinase

Pyruvate kinase (PK) is critical for the regulation of the glycolytic pathway. The regulatory properties of Escherichia coli were investigated by mutating six charged residues involved in interdomain salt bridges (Arg(271), Arg(292), Asp(297), and Lys(413)) and in the binding of the allosteric activator (Lys(382) and Arg(431)). Arg(271) and Lys(413) are located at the interface between A and C domains within one subunit. The R271L and K413Q mutant enzymes exhibit altered kinetic properties. In K413Q, there is partial enzyme activation, whereas R271L is characterized by a bias toward the T-state in the allosteric equilibrium. In the T-state, Arg(292) and Asp(297) form an intersubunit salt bridge. The mutants R292D and D297R are totally inactive. The crystal structure of R292D reveals that the mutant enzyme retains the T-state quaternary structure. However, the mutation induces a reorganization of the interface with the creation of a network of interactions similar to that observed in the crystal structures of R-state yeast and M1 PK proteins. Furthermore, in the R292D structure, two loops that are part of the active site are disordered. The K382Q and R431E mutations were designed to probe the binding site for fructose 1, 6-bisphosphate, the allosteric activator. R431E exhibits only slight changes in the regulatory properties. Conversely, K382Q displays a highly altered responsiveness to the activator, suggesting that Lys(382) is involved in both activator binding and allosteric transition mechanism. Taken together, these results support the notion that domain interfaces are critical for the allosteric transition. They couple changes in the tertiary and quaternary structures to alterations in the geometry of the fructose 1, 6-bisphosphate and substrate binding sites. These site-directed mutagenesis data are discussed in the light of the molecular basis for the hereditary nonspherocytic hemolytic anemia, which is caused by mutations in human erythrocyte PK gene.     

Possible structure and function of the extra C-terminal sequence of pyruvate kinase from Bacillus stearothermophilus

The pyruvate kinases from Genus Bacillus and a few other bacteria have an extra C-terminal sequence with a phosphoenolpyruvate binding motif composed of about 110 amino acids. To elucidate the possible structure and function of this sequence, the enzyme lacking the sequence was prepared and characterized. The N-terminal sequences of the peptides, which were found only in the lysylendopeptidase digest of the wild enzyme and not in that of the truncated enzyme, were determined. All the determined sequences were found in the extra C-terminal sequence deduced from the DNA sequence. The truncated enzyme showed decreased affinity for phosphoenolpyruvate and the allosteric effector ribose 5-phosphate, and had a reduced thermostability. Other properties, such as tetrameric structure, specific activity, and allosteric characteristics were unchanged. A comparison of the CD spectra of the truncated enzyme and the recombinant enzyme indicated that the structure of the C-terminal sequence should be rich in beta-sheet. These findings suggest that the sequence actually exists and that it may form a steady domain interacting with the A-domain and C-domain, which are the catalytic domain and allosteric effector binding domain, respectively.     

Improving the catalytic efficiency of Bacillus pumilus CotA-laccase by site-directed mutagenesis

Bacterial laccases are potential enzymes for biotechnological applications because of their remarkable advantages, such as broad substrate spectrum, various reactions, high thermostability, wide pH range, and resistance to strongly alkaline environments. However, the use of bacterial laccases for industrialized applications is limited because of their low expression level and catalytic efficiency. In this study, CotA, a bacterial laccase from Bacillus pumilus, was engineered through presumptive reasoning and rational design approaches to overcome low catalytic efficiency and thermostability. L386W/G417L, a CotA double-mutant, was constructed through site-directed mutagenesis. The catalytic efficiency of L386W/G417L was 4.3 fold higher than that of wild-type CotA-laccase, but the thermostability of the former was decreased than that of the latter and other mutants. The half-life (t _1/2) of wild-type and G417L were 1.14 and 1.47 h, but the half-life of L386W/G417L was only 0.37 h when incubating the enzyme at 80 °C. Considering the high catalytic efficiency of L386W/G417L, we constructed L386W/G417L/G57F, another mutant, to improve thermostability. Results showed that the half-life of L386W/G417L/G57F was 0.54 h when incubating the enzyme at 90 °C for 2 h with about 34% residual activity, but the residual activity of L386W/G417L was less than 40% when incubating the enzyme at 90 °C for 5 min. L386W/G417L was more efficient in decolorizing various industrial dyes at pH 10 than other mutants. L386W/G417L/G57F also exhibited an efficient decolorization ability. L386W/G417L/G57F is appropriate for biotechnological applications because of its high activity and thermostability in decolorizing industrial dyes. CotA-laccase may be further subjected to molecular modification and be used as an enhancer to improve decolorization efficiency for the physical and chemical treatment of dye wastewater.