Engineering E. coli Alkaline Phosphatase Yields Changes of Catalytic Activity, Thermal Stability and Phosphate Inhibition

To investigate the function of aspartic acid residue 101 and arginine residue 166 in the active site of Escherichia coli alkaline phosphatase (EAP), two single mutants D101S (Asp 101 →Ser) and R166K (Arg 166 →Lys) and a double mutant D101S/R166K of EAP were generated through site-directed mutagenesis based on over-lap PCR method. Their enzymatic kinetic properties, thermal stabilities and possible reaction mechanism were explored. In the presence of inorganic phosphate acceptor, 1 M diethanolamine buffer, the k cat for D101S mutant enzyme increased 10-fold compared to that of wild-type EAP. The mutant R166K has a 2-fold decrease of k cat relative to the wild-type EAP, but the double mutant D101S/R166K was in the middle of them, indicative of an additive effect of these two mutations. On the other hand, the catalytic efficiencies of mutant enzymes are all reduced because of a substantial increase of K m values. All three mutants were more resistant to phosphate inhibitor than the wild-type enzyme. The analysis of the kinetic data suggests that (1) the D101S mutant enzyme obtains a higher catalytic activity by allowing a faster release of the product; (2) the R166K mutant enzyme can reduce the binding of the substrate and phosphate competitive inhibitor; (3) the double mutant enzyme has characteristics of both quicker catalytic turnover number and decreased affinity for competitive inhibitor. Additionally, pre-steady-state kinetics of D101S and D101S/R166K mutants revealed a transient burst followed by a linear steady state phase, obviously different from that of wild-type EAP, suggesting that the rate-limiting step has partially change from the release of phosphate from non-covalent E-Pi complex to the hydrolysis of covalent E-Pi complex for these two mutants.     

大肠杆菌碱性磷酸酶的体外定向进化研究

大肠杆菌碱性磷酸酶（E.coli alkaline phosphatase, EAP, EC 3.1.3.1）是一个非特异性二聚体磷酸单酯酶. 采用易错聚合酶链反应(error prone PCR)的方法,在原有高活力突变株的基础上,对EAP远离活性中心催化三联体的区域进行定向进化,经两轮error prone PCR,获得催化活力较亲本D101S突变株提高3倍、较野生型酶提高35倍的进化酶4-186,并对该酶的催化动力学特征进行了分析. 进化酶基因的DNA测序表明4-186含两个有义氨基酸置换：K167R和S374C,二者既不位于底物结合位点,也不位于酶的金属离子结合位点.     

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(+).     

Mutational analysis of residues in two consensus motifs in the active sites of cathepsin E

Cathepsin E, an intracellular aspartic proteinase of the pepsin family, is composed of two homologous domains, each containing the catalytic Asp residue in a consensus DTG motif. Here we examine the significance of residues in the motifs of rat cathepsin E by substitution of Asp98, Asp283, and Thr284 with other residues using site-directed mutagenesis. Each of the mutant proenzymes, as well as the wild-type protein, was found in culture media and cell extracts when heterologously expressed in human embryonic kidney 293T cells. The single mutants D98A, D283A, and D283E, and the double mutants D98A/D283A and D98E/D283E showed neither autocatalytic processing nor enzymatic activities under acidic conditions. However, the D98E and T284S mutants retained the ability to transform into the mature forms, although they exhibited only about 13 and 40% of the activity of the wild-type enzyme, respectively. The K(m) values of these two mutants were similar to those of the wild-type enzyme, but their k(cat) values were greatly decreased. The K(i) values for pepstatin and the Ascaris pepsin inhibitor of the mutants and the wild-type enzyme were almost the same. The circular dichroism spectra of the two mutants were essentially the same as those of the wild-type enzyme at various pH values. These results indicate that (i) Asp98, Asp283, and Thr284 are indeed critical for catalysis, and (ii) the decrease in the catalytic activity of D98E and T284S mutants is brought about by an effect on the kinetic process from the enzyme-substrate complex to the release of the product.     

The conserved R166 residue of ALDH5A (succinic semialdehyde dehydrogenase) has multiple functional roles

ALDH5 (aka succinic semialdehyde dehydrogenase) is a NAD(+)-dependent aldehyde dehydrogenase crucial for the proper removal of the GABA metabolite succinic semialdehyde (SSA). All known ALDH5 family members contain the conserved amino acid sequence "MITRK". Our studies of rat ALDH5A indicate that residue R166 in this sequence may play a role in the substrate specificity of ALDH5A for the gamma-carboxylated succinic semialdehyde versus other aliphatic and aromatic aldehydes including acetaldehyde and benzaldehyde. We tested the hypothesis that the R166 residue regulates aldehyde specificity by utilizing rat ALDH5A wild-type (R166wt) and R166K, R166H, R166A, and R166E mutants. The V(MAX) using SSA fell whereas the K(M) for SSA increased for all mutants analyzed yielding k(cat)/K(M) (s(-1)/microM) ratios of 52.3 (R166wt), 5.5 (R166K), 0.01 (R166H), 0.008 (R166E), and 0.004 (R166A). Utilization of acetaldehyde by the R166H mutant was similar to R166wt with k(cat)/K(M)'s of 0.003 and 0.002, respectively. Almost no activity towards acetaldehyde was noted for the R166E and R166A mutants. Unexpectedly, the K(M) for NAD(+) changed: 21 microM (R166wt), 81 microM (R166K), 63 microM (R166H), 35 microM (R166E) and 44 microM (R166A). As release of NADH can be a rate-limiting step for ALDH activity, NADH binding was evaluated for R166wt and R166H enzymes. The K(D) of NADH for R166H (0.9 microM) was 11-fold less than that of ALDH5A wt (10.3 microM) and possibly explains the increase in the K(M) for NAD(+). Furthermore, data using R166K and R166H mutants demonstrate that inhibition of enzyme activity by low pH is regulated in part by the R166 residue. Our data indicate that the R166 residue of ALDH5A regulates multiple enzymatic functions.     

Active-site mutants of beta-lactamase: use of an inactive double mutant to study requirements for catalysis

We have studied the catalytic activity and some other properties of mutants of Escherichia coli plasmid-encoded RTEM beta-lactamase (EC 3.5.2.6) with all combinations of serine and threonine residues at the active-site positions 70 and 71. (All natural beta-lactamases have conserved serine-70 and threonine-71.) From the inactive double mutant Ser-70----Thr, Thr-71----Ser [Dalbadie-McFarland, G., Cohen, L. W., Riggs, A. D., Morin, C., Itakura, K., & Richards, J. H. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 6409-6413], an active revertant, Thr-71----Ser (i.e., residue 70 in the double mutant had changed from threonine to the serine conserved at position 70 in the wild-type enzyme), was isolated by an approach that allows identification of active revertants in the absence of a background of wild-type enzyme. This mutant (Thr-71----Ser) has about 15% of the catalytic activity of wild-type beta-lactamase. The other possible mutant involving serine and threonine residues at positions 70 and 71 (Ser-70----Thr) shows no catalytic activity. The primary nucleophiles of a serine or a cysteine residue [Sigal, I. S., Harwood, B. G., & Arentzen, R. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 7157-7160] at position 70 thus seem essential for enzymatic activity. Compared to wild-type enzyme, all three mutants show significantly reduced resistance to proteolysis; for the active revertant (Thr-71----Ser), we have also observed reduced thermal stability and reduced resistance to denaturation by urea.     

Site-directed mutagenesis of beta-lactamase I. Single and double mutants of Glu-166 and Lys-73.

Two single mutants and the corresponding double mutant of beta-lactamase I from Bacillus cereus 569/H were constructed and their kinetics investigated. The mutants have Lys-73 replaced by arginine (K73R), or Glu-166 replaced by aspartic acid (E166D), or both (K73R + E166D). All four rate constants in the acyl-enzyme mechanism were determined for the E166D mutant by the methods described by Christensen, Martin & Waley [(1990) Biochem. J. 266, 853-861]. Both the rate constants for acylation and deacylation for the hydrolysis of benzylpenicillin were decreased about 2000-fold in this mutant. In the K73R mutant, and in the double mutant, the rate constants for acylation were decreased about 100-fold and 10,000-fold respectively. All three mutants also had lowered values for the rate constants for the formation and dissociation of the non-covalent enzyme-substrate complex. The specificities of the mutants did not differ greatly from those of wild-type beta-lactamase, but the hydrolysis of cephalosporin C by the K73R mutant gave 'burst' kinetics.     

Directed Evolution of E. coli Alkaline Phosphatase Towards Higher Catalytic Activity

Directed evolution was used to enhance the catalytic activity of E. coli alkaline phosphatase (EAP). Through two rounds of error-prone PCR and one round of DNA shuffling followed by a rapid, sensitive screening procedure, several improved variants were obtained. Their enzymatic kinetic properties, thermal stabilities and possible mechanism for the improvement were investigated. In 1.0 M Tris buffer, the specific activity of the most active EAP variant S2163 was 1500 units/mg protein, showing it to be 3.6 times more active than the D101S parent enzyme and ∼40 times more active than the wild-type EAP. At the same time, the K_m value of the S2163 variant decreased to 1491 μM from the 2384 μM of the D101S. As a result, the k_cat/K_m ratio of this variant showed a 5.8-fold enhancement over that of D101S parent enzyme. Three activating amino acid substitutions, K167R, G180S and S374C, which were located far away from the center of the catalytic pocket, were identified by sequencing the genes encoding evolved enzymes. Possible explanations for the improvement of activity were analyzed.     

Cold adaptation of xylose isomerase from Thermus thermophilus through random PCR mutagenesis. Gene cloning and protein characterization.

Random PCR mutagenesis was applied to the Thermus thermophilus xylA gene encoding xylose isomerase. Three cold-adapted mutants were isolated with the following amino-acid substitutions: E372G, V379A (M-1021), E372G, F163L (M-1024) and E372G (M-1026). The wild-type and mutated xylA genes were cloned and expressed in Escherichia coli HB101 using the vector pGEM-T Easy, and their physicochemical and catalytic properties were determined. The optimum pH for xylose isomerization activity for the mutants was approximately 7.0, which is similar to the wild-type enzyme. Compared with the wild-type, the mutants were active over a broader pH range. The mutants exhibited up to nine times higher catalytic rate constants (k(cat)) for d-xylose compared with the wild-type enzyme at 60 degrees C, but they did not show any increase in catalytic efficiency (k(cat)/K(m)). For d-glucose, both the k(cat) and the k(cat)/K(m) values for the mutants were increased compared with the wild-type enzyme. Furthermore, the mutant enzymes exhibited up to 255 times higher inhibition constants (K(i)) for xylitol than the wild-type, indicating that they are less inhibited by xylitol. The thermal stability of the mutated enzymes was poorer than that of the wild-type enzyme. The results are discussed in terms of increased molecular flexibility of the mutant enzymes at low temperatures.     

Improving the activity and stability of GL-7-ACA acylase CA130 by site-directed mutagenesis

In the present study, glutaryl-7-amino cephalosporanic acid acylase from Pseudomonas sp. strain 130 (CA130) was mutated to improve its enzymatic activity and stability. Based on the crystal structure of CA130, two series of amino acid residues, one from those directly involved in catalytic function and another from those putatively involved in surface charge, were selected as targets for site-directed mutagenesis. In the first series of experiments, several key residues in the substrate-binding pocket were substituted, and the genes were expressed in Escherichia coli for activity screening. Two of the mutants constructed, Y151alphaF and Q50betaN, showed two- to threefold-increased catalytic efficiency (k(cat)/K(m)) compared to wild-type CA130. Their K(m) values were decreased by ca. 50%, and the k(cat) values increased to 14.4 and 16.9 s(-1), respectively. The ability of these mutants to hydrolyze adipoyl 6-amino penicillinic acid was also improved. In the second series of mutagenesis, several mutants with enhanced stabilities were identified. Among them, R121betaA and K198betaA had a 30 to 58% longer half-life than wild-type CA130, and K198betaA and D286betaA showed an alkaline shift of optimal pH by about 1.0 to 2.0 pH units. To construct an engineered enzyme with the properties of both increased activity and stability, the double mutant Q50betaN/K198betaA was expressed. This enzyme was purified and immobilized for catalytic analysis. The immobilized mutant enzyme showed a 34.2% increase in specific activity compared to the immobilized wild-type CA130.     

Artificial evolution of an enzyme active site: structural studies of three highly active mutants of Escherichia coli alkaline phosphatase

The crystal structure of three mutants of Escherichia coli alkaline phosphatase with catalytic activity (k(cat)) enhancement as compare to the wild-type enzyme is described in different states. The biological aspects of this study have been reported elsewhere. The structure of the first mutant, D330N, which is threefold more active than the wild-type enzyme, was determined with phosphate in the active site, or with aluminium fluoride, which mimics the transition state. These structures reveal, in particular, that this first mutation does not alter the active site. The second mutant, D153H-D330N, is 17-fold more active than the wild-type enzyme and activated by magnesium, but its activity drops after few days. The structure of this mutant was solved under four different conditions. The phosphate-free enzyme was studied in an inactivated form with zinc at site M3, or after activation by magnesium. The comparison of these two forms free of phosphate illustrates the mechanism of the magnesium activation of the catalytic serine residue. In the presence of magnesium, the structure was determined with phosphate, or aluminium fluoride. The drop in activity of the mutant D153H-D330N could be explained by the instability of the metal ion at M3. The analysis of this mutant helped in the design of the third mutant, D153G-D330N. This mutant is up to 40-fold more active than the wild-type enzyme, with a restored robustness of the enzyme stability. The structure is presented here with covalently bound phosphate in the active site, representing the first phosphoseryl intermediate of a highly active alkaline phosphatase. This study shows how structural analysis may help to progress in the improvement of an enzyme catalytic activity (k(cat)), and explains the structural events associated with this artificial evolution.     

Reduced activity of bamhi variants c54i, c64w, and c54d/c64r is consistent with the substrate-assisted catalysis model

Three specific mutants, C54I, C54W, and a double-mutant C54D:C64R of restriction endonuclease BamHI, were generated and studied to investigate the role, if any, of the 54th and 64th cysteine residues in the catalysis of BamHI. The mutation was achieved using the megaprimer approach for PCR. The mutant genes were cloned and characterized by sequencing. The mutant and the wild-type proteins were expressed and purified and their kinetic parameters were determined using short synthetic oligonucleotides as substrates. All mutants had higher K(m) values than that of the wild-type enzyme suggesting a decrease in the affinity of the enzyme for its substrate. The mutant protein C54W showed significant changes in the CD spectra vis-a-vis wild-type enzyme and had the lowest K(m)/K(cat) value among the mutants indicative of changes in the secondary structure of the protein. The melting curves of the mutant proteins overlapped that of the wild-type enzyme. Analysis of the K(cat) values in the context of cocrystal structure suggests that the effect of Cys54 mutation is probably through the perturbation of the local structure whereas reduced activity of the double mutant is consistent with the substrate-assisted catalysis mechanism.     

Alteration of substrate specificity of cholesterol oxidase from Streptomyces sp. by site-directed mutagenesis

Despite the structural similarities between cholesterol oxidase from Streptomyces and that from Brevibacterium, both enzymes exhibit different characteristics, such as catalytic activity, optimum pH and temperature. In attempts to define the molecular basis of differences in catalytic activity or stability, substitutions at six amino acid residues were introduced into cholesterol oxidase using site-directed mutagenesis of its gene. The amino acid substitutions chosen were based on structural comparisons of cholesterol oxidases from Streptomyces and BREVIBACTERIUM: Seven mutant enzymes were constructed with the following amino acid substitutions: L117P, L119A, L119F, V145Q, Q286R, P357N and S379T. All the mutant enzymes exhibited activity with the exception of that with the L117P mutation. The resulting V145Q mutant enzyme has low activities for all substrates examined and the S379T mutant enzyme showed markedly altered substrate specificity compared with the wild-type enzyme. To evaluate the role of V145 and S379 residues in the reaction, mutants with two additional substitutions in V145 and four in S379 were constructed. The mutant enzymes created by the replacement of V145 by Asp and Glu had much lower catalytic efficiency for cholesterol and pregnenolone as substrates than the wild-type enzyme. From previous studies and this study, the V145 residue seems to be important for the stability and substrate binding of the cholesterol oxidase. In contrast, the catalytic efficiencies (k(cat)/K(m)) of the S379T mutant enzyme for cholesterol and pregnenolone were 1.8- and 6.0-fold higher, respectively, than those of the wild-type enzyme. The enhanced catalytic efficiency of the S379T mutant enzyme for pregnenolone was due to a slightly high k(cat) value and a low K(m) value. These findings will provide several ideas for the design of more powerful enzymes that can be applied to clinical determination of serum cholesterol levels and as sterol probes.     

Directed Evolution of E. coli Alkaline Phosphatase Towards Higher Catalytic Activity

Directed evolution was used to enhance the catalytic activity of E. coli alkaline phosphatase (EAP). Through two rounds of error-prone PCR and one round of DNA shuffling followed by a rapid, sensitive screening procedure, several improved variants were obtained. Their enzymatic kinetic properties, thermal stabilities and possible mechanism for the improvement were investigated. In 1.0 M Tris buffer, the specific activity of the most active EAP variant S2163 was 1500 units/mg protein, showing it to be 3.6 times more active than the D101S parent enzyme and ～40 times more active than the wild-type EAP. At the same time, the K_m value of the S2163 variant decreased to 1491 μM from the 2384 μM of the D101S. As a result, the k_cat/K_m ratio of this variant showed a 5.8-fold enhancement over that of D101S parent enzyme. Three activating amino acid substitutions, K167R, G180S and S374C, which were located far away from the center of the catalytic pocket, were identified by sequencing the genes encoding evolved enzymes. Possible explanations for the improvement of activity were analyzed.     

Investigation of the role of Arg301 identified in the X-ray structure of phosphite dehydrogenase

Phosphite dehydrogenase (PTDH) from Pseudomonas stutzeri catalyzes the nicotinamide adenine dinucleotide-dependent oxidation of phosphite to phosphate. The enzyme belongs to the family of D-hydroxy acid dehydrogenases (DHDHs). A search of the protein databases uncovered many additional putative phosphite dehydrogenases. The genes encoding four diverse candidates were cloned and expressed, and the enzymes were purified and characterized. All oxidized phosphite to phosphate and had similar kinetic parameters despite a low level of pairwise sequence identity (39-72%). A recent crystal structure identified Arg301 as a residue in the active site that has not been investigated previously. Arg301 is fully conserved in the enzymes shown here to be PTDHs, but the residue is not conserved in other DHDHs. Kinetic analysis of site-directed mutants of this residue shows that it is important for efficient catalysis, with an ~100-fold decrease in k(cat) and an almost 700-fold increase in K(m,phosphite) for the R301A mutant. Interestingly, the R301K mutant displayed a slightly higher k(cat) than the parent PTDH, and a more modest increase in K(m) for phosphite (nearly 40-fold). Given these results, Arg301 may be involved in the binding and orientation of the phosphite substrate and/or play a catalytic role via electrostatic interactions. Three other residues in the active site region that are conserved in the PTDH orthologs but not DHDHs were identified (Trp134, Tyr139, and Ser295). The importance of these residues was also investigated by site-directed mutagenesis. All of the mutants had k(cat) values similar to that of the wild-type enzyme, indicating these residues are not important for catalysis.     

3-D structure of a mutant (Asp101-->Ser) of E.coli alkaline phosphatase with higher catalytic activity.

Mutagenesis of the absolutely conserved residue Asp101 of the non-specific monoesterase alkaline phosphatase (E.C. 3.1.3.1) from E. coli has produced an enzyme with increased kcat. The carboxyl group of the Asp101 residue has been proposed to be involved in the positioning of Arg166 and the formation of the helix that contains the active site Ser102. The crystal structure of the Asp101-->Ser mutant has been refined at 2.5 A to a final crystallographic R-factor of 0.173. The altered active site structure of the mutant is compared with that of the wild-type as well as with the structures of the mutant enzyme soaked in two known alkaline phosphatase inhibitors (inorganic phosphate and arsenate). The changes affect primarily the side chain of Arg166 which, by losing the hydrogen bond interaction with the carboxyl side chain of Asp101, becomes more flexible. This analysis, in conjunction with product inhibition studies of the mutant enzyme, suggests that at high pH (> 7) the enzyme achieves a quicker catalytic turnover by allowing a faster release of the product.     

Function of arginine-166 in the active site of Escherichia coli alkaline phosphatase

The function of arginine residue 166 in the active site of Escherichia coli alkaline phosphatase was investigated by site-directed mutagenesis. Two mutant versions of alkaline phosphatase, with either serine or alanine in the place of arginine at position 166, were generated by using a specially constructed M13 phage carrying the wild-type phoA gene. The mutant enzymes with serine and alanine at position 166 have very similar kinetic properties. Under conditions of no external phosphate acceptor, the kcat for the mutant enzymes decreases by approximately 30-fold while the Km increases by less than 2-fold. When kinetic measurements are carried out in the presence of a phosphate acceptor, 1.0 M Tris, the kcat for the mutant enzymes is reduced by less than 3-fold, while the Km increases by more than 50-fold. For both mutant enzymes, in either the absence or the presence of a phosphate acceptor, the catalytic efficiency as measured by the kcat/Km ratio decreases by approximately 50-fold as compared to the wild type. Measurements of the Ki for inorganic phosphate show an increase of approximately 50-fold for both mutants. Phenylglyoxal, which inactivates the wild-type enzyme, does not inactivate the Arg-166----Ala enzyme. This result indicates that Arg-166 is the same arginine residue that when chemically modified causes loss of activity [Daemen, F.J.M., & Riordan, J.F. (1974) Biochemistry 13, 2865-2871]. The data reported here suggest that although Arg-166 is important for activity is not essential. The analysis of the kinetic data also suggests that the loss of arginine-166 at the active site of alkaline phosphatase has two different effects on the enzyme. First, the binding of the substrate, and phosphate as a competitive inhibitor, is reduced; second, the rate of hydrolysis of the covalent phosphoenzyme may be diminished.     

The conserved methionine residue of the metzincins: a site-directed mutagenesis study.

The metalloprotease clan of the metzincins derive their name from the presence of a conserved methionine residue that is located on the C-terminal side of the zinc-binding consensus sequence HEXXHXXGXXH. This methionine residue is located in a rather divergent part of the primary sequence but is structurally very well conserved. It is located under the pyramidal base of the three histidine residues that coordinate the catalytic zinc ion and is not involved in any direct contact with the metal nor the substrate. In order to clarify its role, this methionine residue (M226) of the protease C from Erwinia chrysanthemi has been mutated to various other amino acids. The mutants M226L, M226A, M226I were sufficiently stable to be isolated, while the mutants M226H, M226S and M226N could not be purified. The kinetic properties of these mutants were analysed. All mutants showed decreased activity, whereby increases in K(M) as well as decreases in k(cat) were observed. The M226L mutant and M226C-E189 K double mutant, which has the catalytic glutamic acid substituted as well, could be crystallised. The structure of the M226L mutant was determined to a resolution of 2.0 A and refined to R(free) of 0.20. The structure is isomorphous to the wild-type and does not show large differences, with the exception of a very small movement of the zinc-liganding histidine residues. The M226C-E189 K double mutant crystal structure has been refined to an R(free) of 0.20 at 2.1 A resolution. A small rearrangement of the zinc-liganding histidine residues can be detected, which leads to a slightly different zinc coordination and could explain the decrease in activity.     

Probing enzyme–substrate interactions at the catalytic subsite of Leuconostoc mesenteroides sucrose phosphorylase with site-directed mutagenesis: the roles of Asp49 and Arg395

Abstract

Sucrose phosphorylase is a bacterial α-transglucosidase that catalyses glucosyl transfer from sucrose to phosphate, releasing d-fructose and α-d-glucose 1-phosphate as the product of the first (enzyme glucosylation) and second (enzyme deglucosylation) step of the enzymatic reaction, respectively. The transferred glucosyl moiety of sucrose is accommodated at the catalytic subsite of the phosphorylase through a network of charged hydrogen bonds whereby a highly conserved residue pair of Asp and Arg points towards the equatorial hydroxyl at C₄. To examine the role of this ‘hyperpolar’ binding site for the substrate 4-OH, we have mutated Asp⁴⁹ and Arg³⁹⁵ of Leuconostoc mesenteroides sucrose phosphorylase individually to Ala (D49A) and Leu (R395L), respectively, and also prepared an ‘uncharged’ double mutant harbouring both site-directed substitutions. The efficiency for enzyme glucosylation from sucrose was massively decreased in purified preparations of D49A (10⁷-fold) and R395L (10⁵-fold) as compared to wild-type enzyme. The double mutant was not active above the detection limit. Enzyme deglucosylation to phosphate proceeded relatively efficient in D49A as well as R395L, about 500-fold less than in the wild-type phosphorylase. Substrate inhibition by phosphate and a loss in selectivity for reaction with phosphate as compared to water were new features in the two mutants. Asp⁴⁹ and Arg³⁹⁵ are both essential in the catalytic reaction of L. mesenteroides sucrose phosphorylase.     

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.