Amino acid residues in ribonuclease MC1 from bitter gourd seeds which are essential for uridine specificity

The ribonuclease MC1 (RNase MC1), isolated from seeds of bitter gourd (Momordica charantia), consists of 190 amino acids and is characterized by specific cleavage at the 5'-side of uridine. Site-directed mutagenesis was used to evaluate the contribution of four amino acids, Asn71, Val72, Leu73, and Arg74, at the alpha4-alpha5 loop between alpha4 and alpha5 helices for recognition of uracil base by RNase MC1. Four mutants, N71T, V72L, L73A, and R74S, in which Asn71, Val72, Leu73, and Arg74 in RNase MC1 were substituted for the corresponding amino acids, Thr, Leu, Ala, and Ser, respectively, in a guanylic acid preferential RNase NW from Nicotiana glutinosa, were prepared and characterized with respect to enzymatic activity. Kinetic analysis with a dinucleoside monophosphate, CpU, showed that the mutant N71T exhibited 7.0-fold increased K(m) and 2.3-fold decreased k(cat), while the mutant L73A had 14.4-fold increased K(m), although it did retain the k(cat) value comparable to that of the wild-type. In contrast, replacements of Val72 and Arg74 by the corresponding amino acids Leu and Ser, respectively, had little effect on the enzymatic activity. This observation is consistent with findings in the crystal structure analysis that Asn71 and Leu73 are responsible for a uridine specificity for RNase MC1. The role of Asn71 in enzymatic reaction of RNase MC1 was further investigated by substituting amino acids Ala, Ser, Gln, and Asp. Our observations suggest that Asn71 has at least two roles: one is base recognition by hydrogen bonding, and the other is to stabilize the conformation of the alpha4-alpha5 loop by hydrogen bonding to the peptide backbone, events which possibly result in an appropriate orientation of the alpha-helix (alpha5) containing active site residues. Mutants N71T and N71S showed a remarkable shift from uracil to guanine specificity, as evaluated by cleavage of CpG, although they did exhibit uridine specificity against yeast RNA and homopolynucleotides.     

Mutation of active site residues Asn67 to Ile, Gln92 to Val and Leu204 to Ser in human carbonic anhydrase II: influences on the catalytic activity and affinity for inhibitors

Site-directed mutagenesis has been used to change three amino acid residues involved in the binding of inhibitors (Asn67Ile; Gln92Val and Leu204Ser) within the active site of human carbonic anhydrase (CA, EC 4.2.1.1) II (hCA II). Residues 67, 92 and 204 were changed from hydrophobic to hydrophilic ones, and vice versa. The Asn67Ile and Leu204Ser mutants showed similar k(cat)/K(M) values compared to the wild type (wt) enzyme, whereas the Gln92Val mutant was around 30% less active as a catalyst for CO(2) hydration to bicarbonate compared to the wt protein. Affinity for sulfonamides/sulfamates was decreased in all three mutants compared to wt hCA II. The effect was stronger for the Asn67Ile mutant (the closest residue to the zinc ion), followed by the Gln92Val mutant (residue situated in the middle of the active site) and weakest for the Leu204Ser mutant, an amino acid situated far away from the catalytic metal ion, at the entrance of the cavity. This study shows that small perturbations within the active site architecture have influences on the catalytic efficiency but dramatically change affinity for inhibitors among the CA enzymes, especially when the mutated amino acid residues are nearby the catalytic metal ion.     

Engineered monomeric human histidine triad nucleotide-binding protein 1 hydrolyzes fluorogenic acyl-adenylate and lysyl-tRNA synthetase-generated lysyl-adenylate

Hint1 is a homodimeric protein and member of the ubiquitous HIT superfamily. Hint1 catalyzes the hydrolysis of purine phosphoramidates and lysyl-adenylate generated by lysyl-tRNA synthetase (LysRS). To determine the importance of homodimerization on the biological and catalytic activity of Hint1, the dimer interface of human Hint1 (hHint1) was destabilized by replacement of Val(97) of hHint1 with Asp, Glu, or Arg. The mutants were shown to exist as monomers in solution by a combination of size exclusion chromatograph, static light scattering, and chemically induced dimerization studies. Circular dichroism studies revealed little difference between the stability of the V97D, V97E, and wild-type hHint1. Relative to wild-type and the V97E mutant, however, significant perturbation of the V97D mutant structure was observed. hHint1 was shown to prefer 3-indolepropionic acyl-adenylate (AIPA) over tryptamine adenosine phosphoramidate monoester (TpAd). Wild-type hHint1 was found to be 277- and 1000-fold more efficient (k(cat)/K(m) values) than the V97E and V97D mutants, respectively. Adenylation of wild-type, V97D, and V97E hHint1 by human LysRS was shown to correlate with the mutant k(cat)/K(m) values using 3-indolepropionic acyl-adenylate as a substrate, but not tryptamine adenosine phosphoramidate monoester. Significant perturbations of the active site residues were not detected by molecular dynamics simulations of the hHint1s. Taken together, these results demonstrate that for hHint1; 1) the efficiency (k(cat)/K(m)) of acylated AMP hydrolysis, but not maximal catalytic turnover (k(cat)), is dependent on homodimerization and 2) the hydrolysis of lysyl-AMP generated by LysRS is not dependent on homodimerization if the monomer structure is similar to the wild-type structure.     

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

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

Catalytic role for arginine 188 in the C-C hydrolase catalytic mechanism for Escherichia coli MhpC and Burkholderia xenovorans LB400 BphD

The alpha/beta-hydrolase superfamily, comprised mainly of esterase and lipase enzymes, contains a family of bacterial C-C hydrolases, including MhpC and BphD which catalyze the hydrolytic C-C cleavage of meta-ring fission intermediates on the Escherichia coli phenylpropionic acid pathway and Burkholderia xenovorans LB400 biphenyl degradation pathway, respectively. Five active site amino acid residues (Arg-188, Asn-109, Phe-173, Cys-261, and Trp-264) were identified from sequence alignments that are conserved in C-C hydrolases, but not in enzymes of different function. Replacement of Arg-188 in MhpC with Gln and Lys led to 200- and 40-fold decreases, respectively, in k(cat); the same replacements for Arg-190 of BphD led to 400- and 700-fold decreases, respectively, in k(cat). Pre-steady-state kinetic analysis of the R188Q MhpC mutant revealed that the first step of the reaction, keto-enol tautomerization, had become rate-limiting, indicating that Arg-188 has a catalytic role in ketonization of the dienol substrate, which we propose is via substrate destabilization. Mutation of nearby residues Phe-173 and Trp-264 to Gly gave 4-10-fold reductions in k(cat) but 10-20-fold increases in K(m), indicating that these residues are primarily involved in substrate binding. The X-ray structure of a succinate-H263A MhpC complex shows concerted movements in the positions of both Phe-173 and Trp-264 that line the approach to Arg-188. Mutation of Asn-109 to Ala and His yielded 200- and 350-fold reductions, respectively, in k(cat) and pre-steady-state kinetic behavior similar to that of a previous S110A mutant, indicating a role for Asn-109 is positioning the active site loop containing Ser-110. The catalytic role of Arg-188 is rationalized by a hydrogen bond network close to the C-1 carboxylate of the substrate, which positions the substrate and promotes substrate ketonization, probably via destabilization of the bound substrate.     

Engineering the active center of the 6-phospho-beta-galactosidase from Lactococcus lactis

Several amino acids in the active center of the 6-phospho-beta-galactosidase from Lactococcus lactis were replaced by the corresponding residues in homologous enzymes of glycosidase family 1 with different specificities. Three mutants, W429A, K435V/Y437F and S428D/ K435V/Y437F, were constructed. W429A was found to have an improved specificity for glucosides compared with the wild-type, consistent with the theory that the amino acid at this position is relevant for the distinction between galactosides and glucosides. The k(cat)/K(m) for o-nitrophenyl-beta-D-glucose-6-phosphate is 8-fold higher than for o-nitrophenyl-beta-D-galactose-6-phosphate which is the preferred substrate of the wild-type enzyme. This suggests that new hydrogen bonds are formed in the mutant between the active site residues, presumably Gln19 or Trp421 and the C-4 hydroxyl group. The two other mutants with the exchanges in the phosphate-binding loop were tested for their ability to bind phosphorylated substrates. The triple mutant is inactive. The double mutant has a dramatically decreased ability to bind o-nitrophenyl-beta-D-galactose-6-phosphate whereas the interaction with o-nitrophenyl-beta-D-galactose is barely altered. This result shows that the 6-phospho-beta-galactosidase and the related cyanogenic beta-glucosidase from Trifolium repens have different recognition mechanisms for substrates although the structures of the active sites are highly conserved.     

Human ferrochelatase: characterization of substrate-iron binding and proton-abstracting residues

The terminal step in heme biosynthesis, the insertion of ferrous iron into protoporphyrin IX to form protoheme, is catalyzed by the enzyme ferrochelatase (EC 4.99.1.1). A number of highly conserved residues identified from the crystal structure of human ferrochelatase as being in the active site were examined by site-directed mutagenesis. The mutants Y123F, Y165F, Y191H, and R164L each had an increased K(m) for iron without an altered K(m) for porphyrin. The double mutant R164L/Y165F had a 6-fold increased K(m) for iron and a 10-fold decreased V(max). The double mutant Y123F/Y191F had low activity with an elevated K(m) for iron, and Y123F/Y165F had no measurable activity. The mutants H263A/C/N, D340N, E343Q, E343H, and E343K had no measurable enzyme activity, while E343D, E347Q, and H341C had decreased V(max)s without significant alteration of the K(m)s for either substrate. D340E had near-normal kinetic parameters, while D383A and H231A had increased K(m)s for iron. On the basis of these data and the crystal structure of human ferrochelatase, it is proposed that residues E343, H341, and D340 form a conduit from H263 in the active site to the protein exterior and function in proton extraction from the porphyrin macrocycle. The role of H263 as the porphyrin proton-accepting residue is central to catalysis since metalation only occurs in conjunction with proton abstraction. It is suggested that iron is transported from the exterior of the enzyme at D383/H231 via residues W227 and Y191 to the site of metalation at residues R164 and Y165 which are on the opposite side of the active site pocket from H263. This model should be general for mitochondrial membrane-associated eucaryotic ferrochelatases but may differ for bacterial ferrochelatases since the spatial orientation of the enzyme within prokaryotic cells may differ.     

A continuous anaerobic fluorimetric assay for ferrochelatase by monitoring porphyrin disappearance

A continuous spectrofluorimetric assay for determining ferrochelatase activity has been developed using the physiological substrates ferrous iron and protoporphyrin IX under strictly anaerobic conditions. In contrast to heme, the product of the ferrochelatase-catalyzed reaction, protoporphyrin IX is fluorescent, and therefore the progress of the reaction can be monitored by following the decrease in protoporphyrin fluorescence intensity (with excitation and emission wavelengths at 505 and 635 nm, respectively). This continuous fluorimetric assay detects activities as low as 0.01 nmol porphyrin consumed min(-1), representing an increase in sensitivity of up to two orders of magnitude over the currently used, discontinuous assays. The determination of the steady-state kinetic parameters of ferrochelatase yielded K(m)(PPIX)=1.4+/-0.2 microM, K(m)(Fe(2+))=1.9+/-0.3 microM, and k(cat)=4.0+/-0.3 min(-1). In addition to its applicability for acquisition of kinetic data to characterize ferrochelatase and recombinant variants, this new method should permit detection of low concentrations of ferrochelatase in biological samples.     

Examining thrombin hydrolysis of the factor XIII activation peptide segment leads to a proposal for explaining the cardioprotective effects observed with the factor XIII V34L mutation

In the blood coagulation cascade, thrombin cleaves fibrinopeptides A and B from fibrinogen revealing sites for fibrin polymerization that lead to insoluble clot formation. Factor XIII stabilizes this clot by catalyzing the formation of intermolecular cross-links in the fibrin network. Thrombin activates the Factor XIII a(2) dimer by cleaving the Factor XIII activation peptide segment at the Arg(37)-Gly(38) peptide bond. Using a high performance liquid chromatography assay, the kinetic constants K(m), k(cat), and k(cat)/K(m) were determined for thrombin hydrolysis of fibrinogen Aalpha-(7-20), Factor XIII activation peptide-(28-41), and Factor XIII activation peptide-(28-41) with a Val(34) to Leu substitution. This Val to Leu mutation has been correlated with protection from myocardial infarction. In the absence of fibrin, the Factor XIII activation peptide-(28-41) exhibits a 10-fold lower k(cat)/K(m) value than fibrinogen Aalpha-(7-20). With the Factor XIII V34L mutation, decreases in K(m) and increases in k(cat) produce a 6-fold increase in k(cat)/K(m) relative to the wild-type Factor XIII sequence. A review of the x-ray crystal structures of known substrates and inhibitors of thrombin leads to a hypothesis that the new Leu generates a peptide with more extensive interactions with the surface of thrombin. As a result, the Factor XIII V34L is proposed to be susceptible to wasteful conversion of zymogen to activated enzyme. Premature depletion may provide cardioprotective effects.     

Tyr115, gln165 and trp209 contribute to the 1, 2-epoxy-3-(p-nitrophenoxy)propane-conjugating activity of glutathione S-transferase cGSTM1-1

We investigated the epoxidase activity of a class mu glutathione S-transferase (cGSTM1-1), using 1,2-epoxy-3-(p-nitrophenoxy)propane (EPNP) as substrate. Trp209 on the C-terminal tail, Arg107 on the alpha4 helix, Asp161 and Gln165 on the alpha6 helix of cGSTM1-1 were selected for mutagenesis and kinetic studies. A hydrophobic side-chain at residue 209 is needed for the epoxidase activity of cGSTM1-1. Replacing Trp209 with histidine, isoleucine or proline resulted in a fivefold to 28-fold decrease in the k(cat)(app) of the enzyme, while a modest 25 % decrease in the k(cat)(app) was observed for the W209F mutant. The rGSTM1-1 enzyme has serine at the correponding position. The k(cat)(app) of the S209W mutant is 2. 5-fold higher than that of the wild-type rGSTM1-1. A charged residue is needed at position 107 of cGSTM1-1. The K(m)(app)(GSH) of the R107L mutant is 38-fold lower than that of the wild-type enzyme. On the contrary, the R107E mutant has a K(m)(app)(GSH) and a k(cat)(app) that are 11-fold and 35 % lower than those of the wild-type cGSTM1-1. The substitutions of Gln165 with Glu or Leu have minimal effect on the affinity of the mutants towards GSH or EPNP. However, a discernible reduction in k(cat)(app) was observed. Asp161 is involved in maintaining the structural integrity of the enzyme. The K(m)(app)(GSH) of the D161L mutant is 616-fold higher than that of the wild-type enzyme. In the hydrogen/deuterium exchange experiments, this mutant has the highest level of deuteration among all the proteins tested.We also elucidated the structure of cGSTM1-1 co-crystallized with the glutathionyl-conjugated 1, 2-epoxy-3-(p-nitrophenoxy)propane (EPNP) at 2.8 A resolution. The product found in the active site was 1-hydroxy-2-(S-glutathionyl)-3-(p-nitrophenoxy)propane, instead of the conventional 2-hydroxy isomer. The EPNP moiety orients towards Arg107 and Gln165 in dimer AB, and protrudes into a hydrophobic region formed by the loop connecting beta1 and alpha1 and part of the C-terminal tail in dimer CD. The phenoxyl ring forms strong ring stacking with the Trp209 side-chain in dimer CD. We hypothesize that these two conformations represent the EPNP moiety close to the initial and final stages of the reaction mechanism, respectively.     

The effect of valine substitution for glycine in the dimer interface of citrate synthase from Thermoplasma acidophilum on stability and activity

To determine the role of hydrophobic interactions in the dimer interface of citrate synthase (CS) from Thermoplasma (Tp) acidophilum in thermostabilization, we have used site-directed mutagenesis to replace Gly 196 by Val on the helix L of the subunit interface. Recombinant wild-type and Gly 196 mutant TpCS enzymes were largely identical in terms of substrate specificities (K(m) for oxaloacetate and acetyl CoA). However, the mutation not only reduced catalytic activity (about 10-fold) (i.e., V(max), k(cat) and specific activity) of the TpCS, but also decreased its thermal and chemical stability. Archaeal citrate synthase is active as a dimer, since residues from both monomers participate in the active site. Our results suggest that Gly196 --> Val mutation interferes with dimerization, so that improper dimerization or dissociation of the dimer would have a profound affect on the activity as well as the conformational stability of TpCS.     

Contribution of Gln9 and Phe80 to substrate binding in ribonuclease MC1 from bitter gourd seeds.

Ribonuclease MC1 (RNase MC1) isolated from bitter gourd (Momordica charantia) seeds specifically cleaves phosphodiester bonds on the 5'-side of uridine. The crystal structures of RNase MC1 in complex with 2'-UMP or 3'-UMP reveal that Gln9, Asn71, Leu73, and Phe80 are involved in uridine binding by hydrogen bonding and hydrophobic interactions [Suzuki et al. (2000) Biochem. Biophys. Res. Commun. 275, 572-576]. To evaluate the contribution of Gln9 and Phe80 to uridine binding, Gln9 was replaced with Ala, Phe, Glu, or His, and Phe80 with Ala by site-directed mutagenesis. The kinetic properties of the resulting mutant enzymes were characterized using cytidylyl-3',5'-uridine (CpU) as a substrate. The mutant Q9A exhibited a 3.7-fold increased K(m) and 27.6-fold decreased k(cat), while three other mutations, Q9F, Q9E, and Q9H, predominantly affected the k(cat) value. Replacing Phe80 with Ala drastically reduced the catalytic efficiency (k(cat)/K(m)) with a minimum K(m) value equal to 8 mM. It was further found that the hydrolytic activities of the mutants toward cytidine-2',3'-cyclic monophosphate (cCMP) were reduced. These results demonstrate that Gln9 and Phe80 play essential roles not only in uridine binding but also in hydrolytic activity. Moreover, we produced double Ala substituted mutants at Gln9, Asn71, Leu73, and Phe80, and compared their kinetic properties with those of the corresponding single mutants. The results suggest that these four residues may contribute to uridine binding in a mutually independent manner.     

Valine 10 may act as a driver for product release from the active site of human glutathione transferase P1-1

We have probed the electrophilic binding site (H-site) of human glutathione transferase P1-1 through mutagenesis of two valines, Val 10 and Val 35, into glycine and alanine, respectively. These two residues were previously shown to be the only conformationally variable residues in the H-site and hence may play important roles in cosubstrate recognition and/or product dissociation. Both of these mutant enzymes have been expressed in Escherichia coli and purified and their kinetic properties characterized. The results demonstrate that Val35Ala behaves similarly to wild-type, whereas Val10Gly exhibits a strong decrease of k(cat) and k(cat)/K(m) (cosub) toward two selected cosubstrates: ethacrynic acid and 1-chloro-2,4-dinitrobenzene. Pre-steady-state kinetic analysis of the GSH conjugation with ethacrynic acid shows that both wild-type and Val10Gly mutant enzymes exhibit the same rate-limiting step: the dissociation of product. However, in the Val10Gly mutant there is an increased energetic barrier which renders the dissociation of product more difficult. Similar results are found for the Val10Gly mutant with 1-chloro-2,4-dinitrobenzene as cosubstrate. With this latter cosubstrate, Val 10 also exerts a positive role in the conformational transitions of the ternary complex before the chemical event. Crystallographic analysis of the Val10Gly mutant in complex with the inhibitor S-hexyl-GSH suggests that Val 10 optimally orientates products, thus promoting their exit from the active site.     

Effects of site-directed mutagenesis of the surface residues Gln128 and Gln225 of thermolysin on its catalytic activity

Thermolysin is remarkably activated and stabilized by neutral salts with varying degrees depending on salt species, and particular surface residues are thought to be especially important in its activity and stability [Inouye, K. (1992) J. Biochem. 112, 335-340; Inouye, K. et al. (1998) Biochim. Biophys. Acta 1388, 209-214]. In this study, we examined the mutational effects of the surface residues of thermolysin. Gln128 and Gln225 were selected as the residues to be mutated because they are located on the surface loop and close to but not in the active site (23.5 and 15.8 A far from the active site zinc ion, respectively) and fully solvent accessible. Nine single mutants [Q128K (Gln128 is replaced with Lys), Q128E, Q128A, Q225K, Q225R, Q225E, Q225D, Q225A and Q225V] were constructed by site-directed mutagenesis. Mutational changes in catalytic activity were found only in the mutant thermolysins having a hydrophobic residue at the position 225 (Q225A and Q225V). In the hydrolysis of a neutral substrate N-[3-(2-furyl)acryloyl]-glycyl-l-leucine amide (FAGLA), the alkaline pK(a) value of Q225A is 8.48 +/- 0.04, being higher by 0.42 +/- 0.07 units than that of the wild-type thermolysin. The k(cat)/K(m) value of the wild-type enzyme is enhanced 14 times with 4 M NaCl, and those of Q225A and Q225V are enhanced 10 and 19 times, respectively. In the hydrolysis of a negatively charged substrate N-carbobenzoxy-l-aspartyl-l-phenylalanine methyl ester (ZDFM), unlike FAGLA, the initial velocities of Q225A and Q225V decreased to 30 and 50% of that of the wild-type enzyme, respectively. Their thermal stability is similar to that of the wild-type enzyme. These findings indicate that even a single mutation at the thermolysin surface induces changes in the electrostatic environment in the active site and affects the activity. Thus, site-directed mutagenesis of surface residues of thermolysin, including apparently thermodynamically unfavorable introduction of hydrophobic residues, should be explored to improve its activity and stability.     

Distinct conformation-mediated functions of an active site loop in the catalytic reactions of NAD-dependent D-lactate dehydrogenase and formate dehydrogenase

The three-dimensional structures of NAD-dependent D-lactate dehydrogenase (D-LDH) and formate dehydrogenase (FDH), which resemble each other, imply that the two enzymes commonly employ certain main chain atoms, which are located on corresponding loop structures in the active sites of the two enzymes, for their respective catalytic functions. These active site loops adopt different conformations in the two enzymes, a difference likely attributable to hydrogen bonds with Asn97 and Glu141, which are also located at equivalent positions in D-LDH and FDH, respectively. X-ray crystallography at 2.4-A resolution revealed that replacement of Asn97 with Asp did not markedly change the overall protein structure but markedly perturbed the conformation of the active site loop in Lactobacillus pentosus D-LDH. The Asn97-->Asp mutant D-LDH exhibited virtually the same k(cat), but about 70-fold higher K(M) value for pyruvate than the wild-type enzyme. For Paracoccus sp. 12-A FDH, in contrast, replacement of Glu141 with Gln and Asn induced only 5.5- and 4.3-fold increases in the K(M) value, but 110 and 590-fold decreases in the k(cat) values for formate, respectively. Furthermore, these mutant FDHs, particularly the Glu141-->Asn enzyme, exhibited markedly enhanced catalytic activity for glyoxylate reduction, indicating that FDH is converted to a 2-hydroxy-acid dehydrogenase on the replacement of Glu141. These results indicate that the active site loops play different roles in the catalytic reactions of D-LDH and FDH, stabilization of substrate binding and promotion of hydrogen transfer, respectively, and that Asn97 and Glu141, which stabilize suitable loop conformations, are essential elements for proper loop functioning.     

Residue 259 in protein-tyrosine phosphatase PTP1B and PTPalpha determines the flexibility of glutamine 262

To study the flexibility of the substrate-binding site and in particular of Gln262, we have performed adiabatic conformational search and molecular dynamics simulations on the crystal structure of the catalytic domain of wild-type protein-tyrosine phosphatase (PTP) 1B, a mutant PTP1B(R47V,D48N,M258C,G259Q), and a model of the catalytically active form of PTPalpha. For each molecule two cases were modeled: the Michaelis-Menten complex with the substrate analogue p-nitrophenyl phosphate (p-PNPP) bound to the active site and the cysteine-phosphor complex, each corresponding to the first and second step of the phosphate hydrolysis. Analyses of the trajectories revealed that in the cysteine-phosphor complex of PTP1B, Gln262 oscillates freely between the bound phosphate group and Gly259 frequently forming, as observed in the crystal structure, a hydrogen bond with the backbone oxygen of Gly259. In contrast, the movement of Gln262 is restricted in PTPalpha and the mutant due to interactions with Gln259 reducing the frequency of the oscillation of Gln262 and thereby delaying the positioning of this residue for the second step in the catalysis, as reflected experimentally by a reduction in k(cat). Additionally, in the simulation with the Michaelis-Menten complexes, we found that a glutamine in position 259 induces steric hindrance by pushing the Gln262 side chain further toward the substrate and thereby negatively affecting K(m) as indicated by kinetic studies. Detailed analysis of the water structure around Gln262 and the active site Cys215 reveals that the probability of finding a water molecule correctly positioned for catalysis is much larger in PTP1B than in PTP1B(R47V,D48N,M258C,G259Q) and PTPalpha, in accordance with experiments.     

Nonfixed relationship of the Michaelis constant and maximum velocity with their corresponding rate constants

The Michaelis constant (K(m)) and V(mas) (E0k(cat)) values for two mutant sets of enzymes were studied from the viewpoint of their definition in a rapid equilibrium reaction model and in a steady state reaction model. The "AMP set enzyme" had a mutation at the AMP-binding site (Y95F, V67I, and V67I/L76V), and the "ATP set enzyme" had a mutation at a possible ATP-binding region (Y32F, Y34F, and Y32A/Y34A). Reaction rate constants obtained using steady state model analysis explained discrepancies found by the rapid equilibrium model analysis. (i) The unchanged number of bound AMPs for Y95F and the wild type despite the markedly increased K(m) values for AMP of the AMP set of enzymes was explained by alteration of the rate constants of the AMP step (k(+2), k(-2)) to retain the ratio k(+2)/k(-2). (ii) A 100 times weakened selectivity of ATP for Y34F in contrast to no marked changes in K(m) values for both ATP and AMP for the ATP set of enzymes was explained by the alteration of the rate constants of the ATP steps. A similar alteration of the K(m) and k(cat) values of these enzymes resulted from distinctive alterations of their rate constants. The pattern of alteration was highly suggestive. The most interesting finding was that the rate constants that decided the K(m) and k(cat) values were replaced by the mutation, and the simple relationships between K(m), k(cat), and the rate constants of K(m)1 = k(+1)/k(-1) and k(cat) = k(f) were not valid. The nature of the K(m) and k(cat) alterations was discussed.     

Improving the catalytic efficiency of a meta-cleavage product hydrolase (CumD) from Pseudomonas fluorescens IP01

The meta-cleavage product hydrolase from Pseudomonas fluorescens IP01 (CumD) hydrolyzes 2-hydroxy-6-oxo-7-methylocta-2,4-dienoate (6-isopropyl HODA) in the cumene (isopropylbenzene) degradation pathway. To modulate the substrate specificity and catalytic efficiency of CumD toward substrates derived from monocyclic aromatic compounds, we constructed the CumD mutants, A129V, I199V, and V227I, as well as four types of double and triple mutants. Toward substrates with smaller side chains (e.g. 2-hydroxy-6-oxohepta-2,4-dienoate; 6-ethyl-HODA), the k(cat)/K(m) values of the single mutants were 4.2-11 fold higher than that of the wild type enzyme and 1.8-4.7 fold higher than that of the meta-cleavage product hydrolase from Pseudomonas putida F1 (TodF). The A129V mutant showed the highest k(cat)/K(m) value for 2-hydroxy-6-oxohepta-2,4-dienoate (6-ethyl-HODA). The crystal structure of the A129V mutant was determined at 1.65 A resolution, enabling location of the Ogamma atom of the Ser103 side chain. A chloride ion was bound to the oxyanion hole of the active site, and mutant enzymes at the residues forming this site were also examined. The k(cat) values of Ser34 mutants were decreased 2.9-65 fold, suggesting that the side chain of Ser34 supports catalysis by stabilizing the anionic oxygen of the proposed intermediate state (gem-diolate). This is the first crystal structure determination of CumD in an active form, with the Ser103 residue, one of the catalytically essential "triad", being intact.     

Modulation of inhibition of ferrochelatase by N-methylprotoporphyrin

Protoporhyrin IX ferrochelatase catalyses the terminal step of the haem-biosynthetic pathway by inserting ferrous iron into protoporphyrin IX. NMPP (N-methylprotoporphyrin), a transition-state analogue and potent inhibitor of ferrochelatase, is commonly used to induce haem deficiency in mammalian cell cultures. To create ferrochelatase variants with different extents of tolerance towards NMPP and to understand further the mechanism of ferrochelatase inhibition by NMPP, we isolated variants with increased NMPP resistance, bearing mutations in an active-site loop (murine ferrochelatase residues 248-257), which was previously shown to mediate a protein conformational change triggered by porphyrin binding. The kinetic mechanisms of inhibition of two variants, in which Pro255 was replaced with either arginine (P255R) or glycine (P255G), were investigated and compared with that of wild-type ferrochelatase. While the binding affinity of the P255X variants for NMPP decreased by one order of magnitude in relation to that of wild-type enzyme, the inhibition constant increased by approximately two orders of magnitude (K(i)(app) values of 1 microM and 2.3 microM for P255R and P255G respectively, as against 3 nM for wild-type ferrochelatase). Nonetheless, the drastically reduced inhibition of the variants by NMPP was not paralleled with a decrease in specificity constant (kcat/K(m, protoporhyrin IX)) and/or catalytic activity (kcat). Further, although NMPP binding to either wild-type ferrochelatase or P255R occurred via a similar two-step kinetic mechanism, the forward and reverse rate constants associated with the second and rate-limiting step were comparable for the two enzymes. Collectively, these results suggest that Pro255 has a crucial role in maintaining an appropriate protein conformation and modulating the selectivity and/or regiospecificity of ferrochelatase.     

Site-directed mutagenesis of dimethyl sulfoxide reductase from Rhodobacter capsulatus: characterization of a Y114 --> F mutant

A system for expressing site-directed mutants of the molybdenum enzyme dimethyl sulfoxide reductase from Rhodobacter capsulatus in the natural host was constructed. This system was used to generate and express dimethyl sulfoxide reductase with a Y114F mutation. The Y114F mutant had an increased k(cat) and increased K(m) toward both dimethyl sulfoxide and trimethylamine N-oxide compared to the native enzyme, and the value of k(cat)/K(m) was lower for both substrates in the mutant enzyme. The Y114F mutant, as isolated, was able to oxidize dimethyl sulfide with phenazine ethosulfate as the electron acceptor but with a lower k(cat) than that of the native enzyme. The pH optimum of dimethyl sulfide:acceptor oxidoreductase activity in the Y114F mutant was shown to be shifted by +1 pH unit compared to the native enzyme. The Y114F mutant did not form a pink complex with dimethyl sulfide, which is characteristic of the native enzyme. The mutant enzyme showed a large increase in the K(d) for DMS. Direct electrochemistry showed that the Mo(V)/Mo(IV) couple was unaffected by the Y114F mutant, but the midpoint potential of the Mo(VI)/Mo(V) couple was raised by about 50 mV. These data confirm that the Y114 residue plays a critical role in oxidation-reduction processes at the molybdenum active site and in oxygen atom transfer associated with sulfoxide reduction.