Solvent kinetic isotope effects monitor changes in hydrogen bonding at the active center of yeast pyruvate decarboxylase concomitant with substrate activation: the substituent at position 221 can control the state of activation.

Substrate activation of yeast pyruvate decarboxylase has been studied extensively in the authors' laboratories providing strong evidence that interaction of substrate with residue C221 provides the trigger, and the information is then transmitted along the C221 to H92 to E91 to W412 to G413 pathway to the 4'-amino nitrogen of the thiamin diphosphate cofactor. Earlier, it was found that the C221S substitution reduced the Hill coefficient from 2.0 to 0.8-0.9, the C221A substitution to 1.0, even though C221 is located on the beta domain some 20 A from the active center thiamin diphosphate cofactor, which is at the interface of the alpha and gamma domains. Here are reported experiments on the C221D/C222A and C221E/C222A variants, in which a negative charge is built onto the C221 side chain, to better mimic the effect of a pyruvate molecule covalently bonded to C221 as a thiohemiketal. Both variants were purified to an optimal activity of 70% of the wild-type enzyme, higher activity than that with the earlier uncharged substitutions at this position. The Hill coefficient for both variants is exactly 1.0. The deuterium solvent kinetic isotope effects (SKIE) on k(cat) for these variants were similar to that for the wild-type enzyme and the C221A/C222A variant, suggesting that starting with the first irreversible step (decarboxylation) the rate-limiting transition states are very similar for all of these enzyme forms. In contrast, such SKIE on k(cat)/K(m) are quite different for the C221A/C222A variant (0.62) than for the C221E/C222A or C221D/C222A variants (0.80-0.82), clearly indicating the effect of the C221 substitutions on transition states starting with the binding of the first substrate to the enzyme and terminating with the decarboxylation step. The results provide strong additional evidence for the involvement of residue C221 in the substrate activation process and suggest that the C221D (C221E) substitution shifts the enzyme into a conformation that resembles the activated conformation. A comparison with SKIE for the wild-type enzyme provides insight to changes in hydrogen bonding at the active center as a result of substrate activation.     

Consequences of a modified putative substrate-activation site on catalysis by yeast pyruvate decarboxylase

Earlier, it had been proposed in the laboratories at Halle that a cysteine residue is responsible for the hysteretic substrate activation behavior of yeast pyruvate decarboxylase. More recently, this idea has received support in a series of studies from Rutgers with the identification of residue C221 as the site where substrate is bound to transmit the information to H92, to E91, to W412, and finally to the active center thiamin diphosphate. According to steady-state kinetic assays, the C221A/C222A variant is no longer subject to substrate activation yet is still a well-functioning enzyme. Several further experiments are reported on this variant: (1) The variant exhibits lag phases in the product formation progress curves, which can be attributed to a unimolecular step in the pre-steady-state stage of catalysis. (2) The rate of exchange with solvent deuterium of the thiamin diphosphate C2H atom is slowed by a factor of 2 compared to the wild-type enzyme, suggesting that the reduced activity that results from the substitutions some 20 A from the active center is also seen in the first key step of the reaction. (3) The solvent (deuterium oxide) kinetic isotope effect was found to be inverse on V(max)/K(m) (0.62), and small but normal on V(max) (1.26), virtually ruling out residue C221 as being responsible for the inverse effects reported for the wild-type enzyme at low substrate concentrations. The solvent kinetic isotope effects are compared to those on two related enzymes not subject to substrate activation, Zymomonas mobilis pyruvate decarboxylase and benzoylformate decarboxylase.     

Activity and function of rabbit muscle-specific creatine kinase at low temperature by mutation at gly268 to asn268

Carp muscle-specific creatine kinase M1 isoenzyme (M1-CK) seems to have evolved to adapt to synchronized changes in body temperature and intracellular pH. When gly(268) in rabbit muscle-specific creatine kinase was substituted with asn(268) as found in carp M1-CK, the rabbit muscle-specific CK G286N mutant specific activity at pH 8.0 and 10°C was more than 2-fold higher than that in the wild-type rabbit enzyme. Kinetic studies showed that K(m) values of the rabbit CK G268N mutant were similar to those of the wild-type rabbit enzyme, yet circular dichroism spectra showed that the overall secondary structures of the mutant enzyme, at pH 8.0 and 5°C, were almost identical to the carp M1-CK enzyme. The X-ray diffraction pattern of the mutant enzyme crystal revealed that amino acid residues involved in substrate binding are closer to one another than in the rabbit enzyme, and the cysteine283 active site of the mutant enzyme points away from the ADP binding site. At pH 7.4-8.0 and 35-10°C, with a smaller substrate, dADP, specific activities of the mutant enzyme were consistently higher than the wild-type rabbit enzyme and more similar to the carp M1-CK enzyme. Thus, the smaller active site of the RM-CK G268N mutant may be one of the reasons for its improved activity at low temperature.     

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.     

Use of random and saturation mutageneses to improve the properties of Thermus aquaticus amylomaltase for efficient production of cycloamyloses

Amylomaltase from Thermus aquaticus catalyzes intramolecular transglycosylation of alpha-1,4 glucans to produce cyclic alpha-1,4 glucans (cycloamyloses) with degrees of polymerization of 22 and higher. Although the amylomaltase mainly catalyzes the transglycosylation reaction, it also has weak hydrolytic activity, which results in a reduction in the yield of the cycloamyloses. In order to obtain amylomaltase with less hydrolytic activity, random mutagenesis was perfromed for the enzyme gene. Tyr54 (Y54) was identified as the amino acid involved in the hydrolytic activity of the enzyme. When Y54 was replaced with all other amino acids by site-directed mutagenesis, the hydrolytic activities of the mutated enzymes were drastically altered. The hydrolytic activities of the Y54G, Y54P, Y54T, and Y54W mutated enzymes were remarkably reduced compared with that of the wild-type enzyme, while those of the Y54F and Y54K mutated enzymes were similar to that of the wild-type enzyme. Introducing an amino acid replacement at Y54 also significantly affected the cyclization activity of the amylomaltase. The Y54A, Y54L, Y54R, and Y54S mutated enzymes exhibited cyclization activity that was approximately twofold higher than that of the wild-type enzyme. When the Y54G mutated enzyme was employed for cycloamylose production, the yield of cycloamyloses was more than 90%, and there was no decrease until the end of the reaction.     

Mutagenesis of the proposed iron-sulfur cluster binding ligands in Escherichia coli biotin synthase

Biotin synthase (BioB) is a member of a family of enzymes that includes anaerobic ribonucleotide reductase and pyruvate formate lyase activating enzyme. These enzymes all use S-adenosylmethionine during turnover and contain three highly conserved cysteine residues that may act as ligands to an iron-sulfur cluster required for activity. Three mutant enzymes of BioB have been made, each with one cysteine residue (C53, 57, 60) mutated to alanine. All three mutant enzymes were inactive, but they still exhibited the characteristic UV-visible spectrum of a [2Fe-2S]2+ cluster similar to that of the wild-type enzyme.     

Kinetic and structural characterization of urease active site variants

Klebsiella aerogenes urease uses a dinuclear nickel active site to catalyze urea hydrolysis at >10(14)-fold the spontaneous rate. To better define the enzyme mechanism, we examined the kinetics and structures for a suite of site-directed variants involving four residues at the active site: His320, His219, Asp221, and Arg336. Compared to wild-type urease, the H320A, H320N, and H320Q variants exhibit similar approximately 10(-)(5)-fold deficiencies in rates, modest K(m) changes, and disorders in the peptide flap covering their active sites. The pH profiles for these mutant enzymes are anomalous with optima near 6 and shoulders that extend to pH 9. H219A urease exhibits 10(3)-fold increased K(m) over that of native enzyme, whereas the increase is less marked ( approximately 10(2)-fold) in the H219N and H219Q variants that retain hydrogen bonding capability. Structures for these variants show clearly resolved active site water molecules covered by well-ordered peptide flaps. Whereas the D221N variant is only moderately affected compared to wild-type enzyme, D221A urease possesses low activity ( approximately 10(-)(3) that of native enzyme), a small increase in K(m), and a pH 5 optimum. The crystal structure for D221A urease is reminiscent of the His320 variants. The R336Q enzyme has a approximately 10(-)(4)-fold decreased catalytic rate with near-normal pH dependence and an unaffected K(m). Phenylglyoxal inactivates the R336Q variant at over half the rate observed for native enzyme, demonstrating that modification of non-active-site arginines can eliminate activity, perhaps by affecting the peptide flap. Our data favor a mechanism in which His219 helps to polarize the substrate carbonyl group, a metal-bound terminal hydroxide or bridging oxo-dianion attacks urea to form a tetrahedral intermediate, and protonation occurs via the general acid His320 with Asp221 and Arg336 orienting and influencing the acidity of this residue. Furthermore, we conclude that the simple bell-shaped pH dependence of k(cat) and k(cat)/K(m) for the native enzyme masks a more complex underlying pH dependence involving at least four pK(a)s.     

A catalytic triad is responsible for acid-base chemistry in the Ascaris suum NAD-malic enzyme

The pH dependence of kinetic parameters of several active site mutants of the Ascaris suum NAD-malic enzyme was investigated to determine the role of amino acid residues likely involved in catalysis on the basis of three-dimensional structures of malic enzyme. Lysine 199 is positioned to act as the general base that accepts a proton from the 2-hydroxyl of malate during the hydride transfer step. The pH dependence of V/K(malate) for the K199R mutant enzyme reveals a pK of 5.3 for an enzymatic group required to be unprotonated for activity and a second pK of 6.3 that leads to a 10-fold loss in activity above the pK of 6.3 to a new constant value up to pH 10. The V profile for K199R is pH independent from pH 5.5 to pH 10 and decreases below a pK of 4.9. Tyrosine 126 is positioned to act as the general acid that donates a proton to the enolpyruvate intermediate to form pyruvate. The pH dependence of V/K(malate) for the Y126F mutant is qualitatively similar to K199R, with a requirement for a group to be unprotonated for activity with a pK of 5.6 and a partial activity loss of about 3-fold above a pK of 6.7 to a new constant value. The Y126F mutant enzyme is about 60000-fold less active than the wild-type enzyme. In contrast to K199R, the V rate profile for Y126F also shows a partial activity loss above pH 6.6. The wild-type pH profiles were reinvestigated in light of the discovery of the partial activity change for the mutant enzymes. The wild-type V/K(malate) pH-rate profile exhibits the requirement for a group to be unprotonated for catalysis with a pK of 5.6 and also shows the partial activity loss above a pK of 6.4. The wild-type V pH-rate profile decreases below a pK of 5.2 and is pH independent from pH 5.5 to pH 10. Aspartate 294 is within hydrogen-bonding distance to K199 in the open and closed forms of malic enzyme. D294A is about 13000-fold less active than the wild-type enzyme, and the pH-rate profile for V/K(malate) indicates the mutant is only active above pH 9. The data suggest that the pK present at about pH 5.6 in all of the pH profiles represents D294, and during catalysis D294 accepts a proton from K199 to allow K199 to act as a general base in the reaction. The pK for the general acid in the reaction is not observed, consistent with rapid tautomerization of enolpyruvate. No other ionizable group in the active site is likely responsible for the partial activity change observed in the pH profiles, and thus the group responsible is probably remote from the active site and the effect on activity is transmitted through the protein by a conformational change.     

Use of Random and Saturation Mutageneses To Improve the Properties of Thermus aquaticus Amylomaltase for Efficient Production of Cycloamyloses

Amylomaltase from Thermus aquaticus catalyzes intramolecular transglycosylation of α-1,4 glucans to produce cyclic α-1,4 glucans (cycloamyloses) with degrees of polymerization of 22 and higher. Although the amylomaltase mainly catalyzes the transglycosylation reaction, it also has weak hydrolytic activity, which results in a reduction in the yield of the cycloamyloses. In order to obtain amylomaltase with less hydrolytic activity, random mutagenesis was perfromed for the enzyme gene. Tyr54 (Y54) was identified as the amino acid involved in the hydrolytic activity of the enzyme. When Y54 was replaced with all other amino acids by site-directed mutagenesis, the hydrolytic activities of the mutated enzymes were drastically altered. The hydrolytic activities of the Y54G, Y54P, Y54T, and Y54W mutated enzymes were remarkably reduced compared with that of the wild-type enzyme, while those of the Y54F and Y54K mutated enzymes were similar to that of the wild-type enzyme. Introducing an amino acid replacement at Y54 also significantly affected the cyclization activity of the amylomaltase. The Y54A, Y54L, Y54R, and Y54S mutated enzymes exhibited cyclization activity that was approximately twofold higher than that of the wild-type enzyme. When the Y54G mutated enzyme was employed for cycloamylose production, the yield of cycloamyloses was more than 90%, and there was no decrease until the end of the reaction.     

Elucidation of active site residues of Arabidopsis thaliana flavonol synthase provides a molecular platform for engineering flavonols

Arabidopsis thaliana flavonol synthase (aFLS) catalyzes the production of quercetin, which is known to possess multiple medicinal properties. aFLS is classified as a 2-oxoglutarate dependent dioxygenase as it requires ferrous iron and 2-oxoglutarate for catalysis. In this study, the putative residues for binding ferrous iron (H221, D223 and H277), 2-oxoglutarate (R287 and S289) and dihydroquercetin (H132, F134, K202, F293 and E295) were identified via computational analyses. To verify the proposed roles of the identified residues, 15 aFLS mutants were constructed and their activities were examined via a spectroscopic assay designed in this study. Mutations at H221, D223, H277 and R287 completely abolished enzymes activities, supporting their importance in binding ferrous iron and 2-oxoglutarate. However, mutations at the proposed substrate binding residues affected the enzyme catalysis differently such that the activities of K202 and F293 mutants drastically decreased to approximately 10% of the wild-type whereas the H132F mutant exhibited approximately 20% higher activity than the wild-type. Kinetic analyses established an improved substrate binding affinity in H132F mutant (Km: 0.027+/-0.0028 mM) compared to wild-type (Km: 0.059+/-0.0063 mM). These observations support the notion that aFLS can be selectively mutated to improve the catalytic activity of the enzyme for quercetin production.     

A catalytic mechanism that explains a low catalytic activity of serine dehydratase like-1 from human cancer cells: crystal structure and site-directed mutagenesis studies

SDH (l-serine dehydratase, EC 4.3.1.17) is a pyridoxal-5'-phosphate (PLP)-dependent enzyme that catalyzes dehydration of l-Ser/Thr to yield pyruvate/ketobutyrate and ammonia. A SDH isoform (cSDH) found in human cancer cell lines has relatively low catalytic activity in comparison with the liver enzyme (hSDH). The crystal structure of cSDH has been determined at 2.8 angstroms resolution. A PLP is covalently attached to K48 by Schiff-base linkage in the active site. The ring nitrogen of PLP is involved in a H-bonding with C309, but is apparently not protonated. Twenty-three amino residues that compose the active site surfaces were identified. The human and rat liver enzymes (hSDH and rSDH) have the same residues, while residues G72, A172, and S228 in cSDH are replaced with A66, S166, and A222, respectively, in hSDH. These residues in hSDH and cSDH were mutated to make complementary pairs of mutated enzymes, and their kinetic parameters were determined. C303 of hSDH and C309 of cSDH which are H-bonding partner of the ring nitrogen of PLP were mutated to alanine and their kinetic parameters were also determined. The crystal structures and the mutation data suggest that having a glycine at residue 72 of cSDH is the major reason for the reduction of catalytic activity of cSDH. Changing alanine to glycine at residue 72 increases the flexibility of the substrate binding-loop (71S(G/A)GN74), so that the bound substrate and PLP are not pushed deep into the active cleft. Consequently, the proton transfer rate from S(G) of C309 to N1 of the bound PLP is decreased, which determines the rate of catalytic reaction.     

Three subunits contribute amino acids to the active site of tetrameric adenylosuccinate lyase: Lys268 and Glu275 are required

Tetrameric adenylosuccinate lyase (ASL) of Bacillus subtilis catalyzes the cleavage of adenylosuccinate to form AMP and fumarate. We previously reported that two distinct subunits contribute residues to each active site, including the His68 and His89 from one and His141 from a second subunit [Brosius, J. L., and Colman, R. F. (2000) Biochemistry 39, 13336-13343]. Glu(275) is 2.8 A from His141 in the ASL crystal structure, and Lys268 is also in the active site region; Glu275 and Lys268 come from a third, distinct subunit. Using site-directed mutagenesis, we have replaced Lys268 by Arg, Gln, Glu, and Ala, with specific activities of the purified mutant enzymes being 0.055, 0.00069, 0.00028, and 0.0, respectively, compared to 1.56 units/mg for wild-type (WT) enzyme. Glu275 was substituted by Gln, Asp, Ala, and Arg; none of these homogeneous mutant enzymes has detectable activity. Circular dichroism and light scattering reveal that neither the secondary structure nor the oligomeric state of the Lys268 mutant enzymes has been perturbed. Native gel electrophoresis and circular dichroism indicate that the Glu275 mutant enzymes are tetramers, but their conformation is altered slightly. For K268R, the K(m)s for all substrates are similar to WT enzyme. Binding studies using [2-3H]-adenylosuccinate reveal that none of the Glu275 mutant enzymes, nor inactive K268A, can bind substrate. We propose that Lys268 participates in binding substrate and that Glu275 is essential for catalysis because of its interaction with His141. Incubation of H89Q with K268Q or E275Q leads to restoration of up to 16% WT activity, while incubation of H141Q with K268Q or E275Q results in 6% WT activity. These complementation studies provide the first functional evidence that a third subunit contributes residues to each intersubunit active site of ASL. Thus, adenylosuccinate lyase has four active sites per enzyme tetramer, each of which is formed from regions of three subunits.     

Activity and androgenic control of glycolytic enzymes in the epididymis and epididymal spermatozoa of the rat.

1. Procedures were developed for the extraction and assay of glycolytic enzymes from the epididymis and epididymal spermatozoa of the rat. 2. The epididymis was separated into four segments for analysis. When rendered free of spermatozoa by efferent duct ligation, regional differences in enzyme activity were apparent. Phosphofructokinase, glycerol phosphate dehydrogenase and glucose 6-phosphate dehydrogenase were more active in the proximal regions of the epididymis, whereas hexokinase, lactate dehydrogenase and phosphorylase were more active in the distal segment. These enzymes were less active in the epididymis of castrated animals and less difference was apparent between the proximal and distal segments. However, the corpus epididymidis from castrated rats had lower activities of almost all enzymes compared with other epididymal segments. 3. Spermatozoa required sonication to obtain satisfactory enzyme release. Glycolytic enzymes were more active in spermatozoa than in epididymal tissue, being more than 10 times as active in the case of hexokinase, phosphoglycerate kinase and phosphoglycerate mutase. 4. The specific activities of a number of enzymes in the epididymis were dependent on the androgen status of the animal. These included hexokinase, phosphofructokinase, aldolase, glyceraldehyde phosphate dehydrogenase, phosphoglycerate kinase, pyruvate kinase, glycerol phosphate dehydrogenase, glucose 6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase and phosphorylase. 5. The caput and cauda epididymidis differed in the extent to which enzyme activities changed in response to an altered androgen status. The most notable examples were hexokinase, phosphofructokinase, aldolase, phosphoglycerate kinase, 6-phosphogluconate dehydrogenase and phosphorylase.     

A structural role of histidine 15 in human glutathione transferase M1-1, an amino acid residue conserved in class Mu enzymes.

His15 is a conserved amino acid residue in all known class Mu glutathione transferases. This His residue in human glutathione transferase M1-1 has been mutated into 17 different amino acid residues by means of site-directed random mutagenesis to determine if any substitutions are compatible with catalytic activity. The majority of the mutant proteins appeared unstable and could not be isolated in reasonable quantities by heterologous expression in Escherichia coli. Five mutant enzymes, H15C, H15K, H15N, H15Q and H15S were purified and more extensively characterized. The mutant proteins shared the same size as that of the wild-type enzyme but could be separated from the parental enzyme by reverse phase HPLC. For all the mutant forms except H15N, the sp. act. with 1-chloro-2,4-dinitrobenzene was less than 3% of the wild-type value--the H15N mutant enzyme displayed 29% of the wild-type activity. None of the catalytically active mutant enzymes showed any major alteration of the binding affinity for the substrate analog S-hexylglutathione, suggesting that His15 is not part of the active site of the enzyme. The high activity of the mutant H15N, also reflected in the kcat/Km, V and S0.5 values, rules out the possibility that His15 in the native enzyme contributes to catalysis by serving as a base. The role of His15, largely replaceable by Asn in the same position, appears to be structural, probably involving hydrogen bonds that maintain the protein in a stable and catalytically active conformation. A critical structural role of His15 in a buried position may explain the evolutionary conservation of this residue in the class Mu glutathione transferases.     

Why is creatine kinase a dimer? Evidence for cooperativity between the two subunits

The dimeric chicken brain type isoenzyme of creatine kinase (BB-CK) was mutated by a C283S amino acid exchange in the catalytic site to produce a basically inactive dimer (B*B*-CK). The mutated enzyme showed a residual activity of about 4% compared to the wild-type, whereas substrate binding parameters were not altered. The inactivated dimer was hybridized with native dimeric muscle enzyme (MM-CK) to produce a partially inactivated MB*-CK heterodimeric hybrid and also to a his-tagged BB-CK (hBhB-CK) resulting in a partially inactive hBB*-CK homodimer. The generated hybrids were purified by chromatography. The V(max) and substrate binding parameters K(m) and K(d) were determined for both directions of the CK reaction and compared to the parameters of the wild-type enzymes (MM-, BB-, hBhB-, MB-CK). In the direction of ATP synthesis (reverse reaction), the MB*- and hBB*-CK hybrids showed a decrease of V(max) to 34% and 32%, respectively, compared to the unmodified wild-type isoform. The inactivation of a single subunit in MB*-CK led to an increase in the K(d) value resulting in an significant substrate synergism, not seen with the MB-CK wild-type enzyme. In the direction of phosphocreatine synthesis (forward reaction), the modified hybrids showed a decrease of V(max) to 50% of the wild-type enzymes and no significant alterations of the K(m) and K(d) parameters. These results strongly suggest an enzymatic cooperativity of the two subunits in the reverse reaction but independent catalytic function in the forward reaction.     

A key role in catalysis for His89 of adenylosuccinate lyase of Bacillus subtilis

Adenylosuccinate lyase of Bacillus subtilis is a tetrameric enzyme which catalyzes the cleavage of adenylosuccinate to AMP and fumarate. We have mutated His(89), one of three conserved histidines, to Gln, Ala, Glu, and Arg. The enzymes were expressed in Escherichia coli and purified to homogeneity. As compared to a specific activity of 1. 56 micromol of adenylosuccinate converted/min/mg protein for wild-type enzyme, the mutant enzymes exhibit specific activities of 0.0225, 0.0036, 0.0036, and 0.0009 for H89Q, H89A, H89E, and H89R, respectively. Circular dichroism and FPLC gel filtration reveal that mutant enzymes have a similar conformation and oligomeric state to that of wild-type enzyme. In H89Q, the K(M) for adenylosuccinate increases slightly to 2.5-fold that of wild-type, the K(M) for fumarate is elevated 3.3-fold, and the K(M) for AMP is 13 times higher than that observed in wild-type enzyme. The catalytic efficiency of the H89Q enzyme is compromised, with k(cat)/K(M) reduced 174-fold in the direction of AMP formation. These data suggest that His(89) plays a role in both the binding of the AMP portion of the substrate and in correctly orienting the substrate for catalysis. Incubation of H89Q with inactive H141Q enzyme [Lee, T. T., Worby, C., Bao, Z.-Q., Dixon, J. E., and Colman, R. F. (1999) Biochemistry 38, 22-32] leads to a 30-fold increase in activity. This intersubunit complementation indicates that His(89) and His(141) from different subunits participate in the active site and that both are required for catalysis.     

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.     

Magnetic resonance studies of the interaction of Co2+ and phosphoenolpyruvate with pyruvate kinase.

Co2+, which activates rabbit muscle pyruvate kinase, competes with Mn2+ for the active site of the enzyme with a KD of 46 muM. Co2+ binds to phosphoenolpyruvate with a KD of 4.1 mM. The structures of the binary Co2+/P-enolpyruvate, and quaternary pyruvate kinase/Co2+/K+/P-enolpyruvate complexes were studied using EPR and the effects of Co2+ on the longitudinal (T1) and transverse (T2) relaxation times of the protons of water and P-enolpyruvate and the phosphorus of P-enolpyruvate. The EPR spectra of all complexes at 6 K, disappear above 40 K and reveal principal g values between 2 and 7 indicating high spin Co2+. For free Co2+ and for the binary Co2+/P-enolpyruvate complex, the T1 of water protons was independent of frequency in the range 8, 15, 24.3, 100, and 220 MHz. Assuming coordination numbers (q) of 6 and 5 for free Co2+ and Co2+/P-enolpyruvate, respectively, correlation times (tauc) of 1.3 times 10(-13) and 1.7 times 10(-13) s, were calculated. The distances from Co2+ and phosphorus and to the cis and trans protons in the binary Co2+/P-enolpyruvate complex calculated from their T1 values were 2.7 A, 4.1 A, AND 5.3 A, respectively, indicating an inner sphere phosphoryl complex. Consistent with direct phosphoryl coordination, a large Co2+ to phosphorus hyperfine contact coupling constant (A/h) of 5 times 10(5) Hz was determined by the frequency dependence of the T2 of phosphorus at 25.1, 40.5, and 101.5 MHz. For both enzyme complexes, the dipolar correlation time tauc was 2 times 10(-12) s and the number of rapidly exchanging water ligands (q) was 0.6 as determined from the frequency dependence of the T1 of water protons. In the quaternary enzyme/Co2+/K+/P-enolyruvate complex this tauc value was consistent with the frequency dependence of the T1 of the phosphorus of enzyme-bound P-enolpyruvate at 25.1 and 40.5 MHz. Distances from enzyme-bound C02+ to the phosphorus and protons of P-enolpyruvate, from their T1 values, were 5.0 A and 8 to 10 A, respectively, indicating a predominantly (greater than or equal to 98%) second spere complex and less than 2% inner sphere complex. Consistent with a second sphere complex on the enzyme, an A/h value of less than 10(3) Hz was determined from the frequency dependence of the T2 of phosphorus. In all complexes the exchange reates were found to be faster than the paramagnetic relaxation rates and the hyperfine contact interaction was found to be small compared to the dipolar interaction. The results thus indicate that the interaction of C02+ with P-enolpyruvate is greatly decreased upon binding to the active site of pyruvate kinase.     

Improving the activity and stability of thermolysin by site-directed mutagenesis

In previous site-directed mutagenesis study on thermolysin, mutations which increase the catalytic activity or the thermal stability have been identified. In this study, we attempted to generate highly active and stable thermolysin by combining the mutations so far revealed to be effective. Three mutant enzymes, L144S (Leu144 in the central alpha-helix located at the bottom of the active site cleft is replaced with Ser), G8C/N60C/S65P (Gly8, Asn60, and Ser65 in the N-terminal region are replaced with Cys, Cys, and Pro, respectively, to introduce a disulfide bridge between the positions 8 and 60), and G8C/N60C/S65P/L144S, were constructed by site-directed mutagenesis. In the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide (FAGLA) and N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester (ZDFM), the k(cat)/K(m) values of L144S and G8C/N60C/S65P/L144S were 5- to 10-fold higher than that of the wild-type enzyme. The rate constants for thermal inactivation at 70 degrees C and 80 degrees C of G8C/N60C/S65P and G8C/N60C/S65P/L144S decreased to 50% of that of the wild-type enzyme. These results indicate that G8C/N60C/S65P/L144S is more active and stable than the wild-type thermolysin. Thermodynamic analysis suggests that the single mutation of Leu144-->Ser and the triple mutation of Gly8-->Cys, Asn60-->Cys, and Ser65-->Pro are independent.     

Aminoethylcysteine can replace the function of the essential active site lysine of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl coenzyme A reductase.

The biodegradative 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase of Pseudomonas mevalonii catalyzes the NAD(+)-dependent conversion of (S)-HMG-CoA to (R)-mevalonate. Crystallographic analysis of abortive ternary complexes of this enzyme revealed lysine 267 located at a position in the active site, suggesting that it might serve as the general acid/base for catalysis. Site-directed mutagenesis and subsequent chemical derivatization were therefore employed to investigate this active site lysine. Replacement of lysine 267 by alanine, histidine, or arginine resulted in mutant enzymes that lacked detectable activity. Lysine 267 was next replaced by the lysine analogues aminoethylcysteine and carboxyamidomethylcysteine. Using instead of the wild-type enzyme the fully active, cysteine-free mutant enzyme C156A/C296A, lysine 267 was first replaced by cysteine. Cysteine 267 of mutant enzyme C156A/C296A/K267C was then treated with bromoethylamine or iodoacetamide to insert aminoethylcysteine (AEC) or carboxyamidomethylcysteine at position 267. The carboxyamidomethylcysteine derivative was inactive, whereas mutant enzyme C156A/C296A/K267AEC exhibited high catalytic activity. That aminoethylcysteine, but not other basic amino acids, can replace the function of lysine 267 documents both the importance of this residue and the requirement for a precisely positioned positive charge at the active site of the enzyme.