Dihydrooxonate is a substrate of dihydroorotate dehydrogenase (DHOD) providing evidence for involvement of cysteine and serine residues in base catalysis.

The flavoprotein dihydroorotate dehydrogenase (DHOD) catalyzes the oxidation of dihydroorotate to orotate. Dihydrooxonate is an analogue of dihydroorotate in which the C5 carbon is substituted by a nitrogen atom. We have investigated dihydrooxonate as a substrate of three DHODs, each representing a distinct evolutionary class of the enzyme, namely the two family 1 enzymes from Lactococcus lactis, DHODA and DHODB, and the enzyme from Escherichia coli, which, like the human enzyme, belongs to family 2. Dihydrooxonate was accepted as a substrate although much less efficiently than dihydroorotate. The first half-reaction was rate limiting according to pre-steady-state and steady-state kinetics with different electron acceptors. Cysteine and serine have been implicated as active site base residues, which promote substrate oxidation in family 1 and family 2 DHODs, respectively. Mutants of DHODA (C130A) and E. coli DHOD (S175A) have extremely low activity in standard assays with dihydroorotate as substrate, but with dihydrooxonate the mutants display considerable and increasing activity above pH 8.0. Thus, the absence of the active site base residue in the enzymes seems to be compensated for by a lower pK(a) of the 5-position in the substrate. Oxonate, the oxidation product of dihydrooxonate, was a competitive inhibitor versus dihydroorotate, and DHODA was the most sensitive of the three enzymes. DHODA was reinvestigated with respect to product inhibition by orotate. The results suggest a classical one-site ping-pong mechanism with fumarate as electron acceptor, while the kinetics with ferricyanide is highly dependent on the detailed reaction conditions.     

Lys-D48 is required for charge stabilization, rapid flavin reduction, and internal electron transfer in the catalytic cycle of dihydroorotate dehydrogenase B of Lactococcus lactis

Dihydroorotate dehydrogenase B (DHODB) catalyzes the oxidation of dihydroorotate (DHO) to orotate and is found in the pyrimidine biosynthetic pathway. The Lactococcus lactis enzyme is a dimer of heterodimers containing FMN, FAD, and a 2Fe-2S center. Lys-D48 is found in the catalytic subunit and its side-chain adopts different positions, influenced by ligand binding. Based on crystal structures of DHODB in the presence and absence of orotate, we hypothesized that Lys-D48 has a role in facilitating electron transfer in DHODB, specifically in stabilizing negative charge in the reduced FMN isoalloxazine ring. We show that mutagenesis of Lys-D48 to an alanine, arginine, glutamine, or glutamate residue (mutants K38A, K48R, K48Q, and K48E) impairs catalytic turnover substantially (approximately 50-500-fold reduction in turnover number). Stopped-flow studies demonstrate that loss of catalytic activity is attributed to poor rates of FMN reduction by substrate. Mutation also impairs electron transfer from the 2Fe-2S center to FMN. Addition of methylamine leads to partial rescue of flavin reduction activity. Nicotinamide coenzyme oxidation and reduction at the distal FAD site is unaffected by the mutations. Formation of the spin-interacting state between the FMN semiquinone-reduced 2Fe-2S centers observed in wild-type enzyme is retained in the mutant proteins, consistent with there being little perturbation of the superexchange paths that contribute to the efficiency of electron transfer between these cofactors. Our data suggest a key charge-stabilizing role for Lys-D48 during reduction of FMN by dihydroorotate, or by electron transfer from the 2Fe-2S center, and establish a common mechanism of FMN reduction in the single FMN-containing A-type and the complex multicenter B-type DHOD enzymes.     

Structure of dihydroorotate dehydrogenase B: electron transfer between two flavin groups bridged by an iron-sulphur cluster

BACKGROUND: The fourth step and only redox reaction in pyrimidine de novo biosynthesis is catalyzed by the flavoprotein dihydroorotate dehydrogenase (DHOD). Based on their sequences, DHODs are grouped into two major families. Lactococcus lactis is one of the few organisms with two DHODs, A and B, belonging to each of the two subgroups of family 1. The B enzyme (DHODB) is a prototype for DHODs in Gram-positive bacteria that use NAD+ as the second substrate. DHODB is a heterotetramer composed of two different proteins (PyrDB and PyrK) and three different cofactors: FMN, FAD, and a [2Fe-2S] cluster. RESULTS: Crystal structures have been determined for DHODB and its product complex. The DHODB heterotetramer is composed of two closely interacting PyrDB-PyrK dimers with the [2Fe-2S] cluster in their interface centered between the FMN and FAD groups. Conformational changes are observed between the complexed and uncomplexed state of the enzyme for the loop carrying the catalytic cysteine residue and one of the lysines interacting with FMN, which is important for substrate binding. CONCLUSIONS: A dimer of two PyrDB subunits resembling the family 1A enzymes forms the central core of DHODB. PyrK belongs to the NADPH ferredoxin reductase superfamily. The binding site for NAD+ has been deduced from the similarity to these proteins. The orotate binding in DHODB is similar to that in the family 1A enzymes. The close proximity of the three redox centers makes it possible to propose a possible electron transfer pathway involving residues conserved among the family 1B DHODs.     

Catalytic properties of dihydroorotate dehydrogenase from Saccharomyces cerevisiae: studies on pH, alternate substrates, and inhibitors

Yeast dihydroorotate dehydrogenase (DHOD) was purified 2800-fold to homogeneity from its natural source. Its sequence is 70% identical to that of the Lactococcus lactis DHOD (family IA) and the two active sites are nearly the same. Incubations of the yeast DHOD with dideuterodihydroorotate (deuterated in the positions eliminated in the dehydrogenation) as the donor and [14C]orotate as the acceptor revealed that the C5 deuteron exchanged with H2O solvent at a rate equal to the 14C exchange rate, whereas the C6 deuteron was infrequently exchanged with H2O solvent, thus indicating that the C6 deuteron of the dihydroorotate is sticky on the flavin cofactor. The pH dependencies of the steady-state parameters (k(cat) and k(cat)/Km) are similar, indicating that k(cat)/Km reports the productive binding of substrate, and the parameters are dependent on the donor-acceptor pair. The lower pKa values for k(cat) and k(cat)/Km observed for substrate dihydroorotate (around 6) in comparison to the values determined for dihydrooxonate (around 8) suggest that the C5 pro S hydrogen atom of dihydroorotate (but not the analogous hydrogen of dihydrooxonate), which is removed in the dehydrogenation, assists in lowering the pKa of the active site base (Cys133). The pH dependencies of the kinetic isotope effects on steady-state parameters observed for the dideuterated dihydroorotate are consistent with the dehydrogenation of substrate being rate limiting at low pH values, with a pKa value approximating that assigned to Cys133. Electron acceptors with dihydroorotate as donor were preferred in the following order: ferricyanide (1), DCPIP (0.54), Qo (0.28), fumarate (0.15), and O2 (0.035). Orotate inhibition profiles versus varied concentrations of dihydroorotate with ferricyanide or O2 as acceptors suggest that both orotate and dihydroorotate have significant affinities for the reduced and oxidized forms of the enzyme.     

New properties of Bacillus subtilis succinate dehydrogenase altered at the active site. The apparent active site thiol of succinate oxidoreductases is dispensable for succinate oxidation.

Mammalian and Escherichia coli succinate dehydrogenase (SDH) and E. coli fumarate reductase apparently contain an essential cysteine residue at the active site, as shown by substrate-protectable inactivation with thiol-specific reagents. Bacillus subtilis SDH was found to be resistant to this type of reagent and contains an alanine residue at the amino acid position equivalent to the only invariant cysteine in the flavoprotein subunit of E. coli succinate oxidoreductases. Substitution of this alanine, at position 252 in the flavoprotein subunit of B. subtilis SDH, by cysteine resulted in an enzyme sensitive to thiol-specific reagents and protectable by substrate. Other biochemical properties of the redesigned SDH were similar to those of the wild-type enzyme. It is concluded that the invariant cysteine in the flavoprotein of E. coli succinate oxidoreductases corresponds to the active site thiol. However, this cysteine is most likely not essential for succinate oxidation and seemingly lacks an assignable specific function. An invariant arginine in juxtaposition to Ala-252 in the flavoprotein of B. subtilis SDH, and to the invariant cysteine in the E. coli homologous enzymes, is probably essential for substrate binding.     

Genetic reconstruction and characterization of the recombinant transacylase (E2b) component of bovine branched-chain alpha-keto acid dehydrogenase complex. Implication of histidine 391 as an active site residue

Genetically altered transacylase (E2b) proteins of the bovine branched-chain alpha-keto acid dehydrogenase complex were overexpressed in Escherichia coli and characterized. Deletion by PstI or Bal31 digestion of the amino-terminal region of the inner-core domain (residues 175-421) beyond residue 209 resulted in a complete loss of transacylase activity. The enzyme assay was carried out using [1-14C]isovaleryl-CoA and exogenous dihydrolipoamide as substrates. The removal of 4 residues (Thr-Ile-Pro-Ile) (residues 175-178) from the amino terminus of the inner-core domain significantly reduced the level of transacylase activity. The results establish that the segment between residues 175 and 209 is an integral part of the active site of E2b. The residue His-391 in the recombinant inner-core domain (E2b delta 167) was changed to Asn or Gln by site-directed mutagenesis. The wild-type and the two mutant inner-core domains were assembled into 24-mers as determined by gel filtration. However, both Asn and Gln mutations were accompanied by a complete loss of the enzymatic activity. Titration of the natural branched-chain alpha-keto dehydrogenase complex from pH 8 to 6 sharply reduced transacylase activity. The above data support the hypothesis that a conserved histidine residue in E2 acts as a general base for the transacylation reaction by analogy with E. coli chloramphenicol acetyltransferases.     

The anaerobic (class III) ribonucleotide reductase from Lactococcus lactis. Catalytic properties and allosteric regulation of the pure enzyme system

Lactococcus lactis contains an operon with the genes (nrdD and nrdG) for a class III ribonucleotide reductase. Strict anaerobic growth depends on the activity of these genes. Both were sequenced, cloned, and overproduced in Escherichia coli. The corresponding proteins, NrdD and NrdG, were purified close to homogeneity. The amino acid sequences of NrdD (747 residues, 84.1 kDa) and NrdG (199 residues, 23.3 kDa) are 53 and 42% identical with the respective E. coli proteins. Together, they catalyze the reduction of ribonucleoside triphosphates to the corresponding deoxyribonucleotides in the presence of S-adenosylmethionine, reduced flavodoxin or reduced deazaflavin, potassium ions, dithiothreitol, and formate. EPR experiments demonstrated a [4Fe-4S](+) cluster in reduced NrdG and a glycyl radical in activated NrdD, similar to the E. coli NrdD and NrdG proteins. Different from E. coli, the two polypeptides of NrdD and the proteins in the NrdD-NrdG complex were only loosely associated. Also the FeS cluster was easily lost from NrdG. The substrate specificity and overall activity of the L. lactis enzyme was regulated according to the general rules for ribonucleotide reductases. Allosteric effectors bound to two separate sites on NrdD, one binding dATP, dGTP, and dTTP and the other binding dATP and ATP. The two sites showed an unusually high degree of cooperativity with complex interactions between effectors and a fine-tuning of their physiological effects. The results with the L. lactis class III reductase further support the concept of a common origin for all present day ribonucleotide reductases.     

The dimeric dihydroorotate dehydrogenase A from Lactococcus lactis dissociates reversibly into inactive monomers

The flavoenzyme dihydroorotate dehydrogenase A from Lactococcus lactis is a homodimeric protein of 311 residues/subunit, and the two active sites are positioned at a distance from the dimer interface. To promote formation of the monomeric form of the enzyme, we changed the residues involved in formation of two salt bridges formed between the residues Glu206 of the one polypeptide and Lys296 of the other polypeptide. The mutant enzymes formed inactive precipitates when cells were grown at 37 degrees C, but remained soluble and active when cells were grown at 25 degrees C. The salt bridges were not needed for activity, because the mutant enzymes in which one of the residues was converted to an alanine (E206A or K296A) retained almost full activity. The mutant enzymes in which the charge of one of the residues of the salt bridge was inverted (i.e., E206K or K296E) were severely impaired. The double mutant E206K-K296E, which has the possibility of forming salt bridges in the opposite orientation of the wild type, was fully active in concentrated solutions, but dissociated into inactive monomers upon dilution. The K(D) for the dimer to monomer dissociation reaction was 12 microM, and dimer formation was favored by the product, orotate, or by high ionic strength, indicating that the hydrophobic interactions are important for the subunit contacts. Wild-type dihydroorotate dehydrogenase A was similarly found to dissociate into inactive monomers, but with a K(D) for dissociation equal to 0.12 microM. These results imply that the dimeric state is necessary for activity of the enzyme.     

Glucosamine synthetase from Escherichia coli: purification, properties, and glutamine-utilizing site location

L-Glutamine:D-fructose-6-phosphate amidotransferase (glucosamine synthetase) has been purified to homogeneity from Escherichia coli. A subunit molecular weight of 70,800 was estimated by gel electrophoresis in sodium dodecyl sulfate. Pure glucosamine synthetase did not exhibit detectable NH3-dependent activity and did not catalyze the reverse reaction, as reported for more impure preparations [Gosh, S., Blumenthal, H. J., Davidson, E., & Roseman, S. (1960) J. Biol. Chem. 235, 1265]. The enzyme has a Km of 2 mM for fructose 6-phosphate, a Km of 0.4 mM for glutamine, and a turnover number of 1140 min-1. The amino-terminal sequence confirmed the identification of residues 2-26 of the translated E. coli glmS sequence [Walker, J. E., Gay, J., Saraste, M., & Eberle, N. (1984) Biochem. J. 224, 799]. Methionine-1 is therefore removed by processing in vivo, leaving cysteine as the NH2-terminal residue. The enzyme was inactivated by the glutamine analogue 6-diazo-5-oxo-L-norleucine (DON) and by iodoacetamide. Glucosamine synthetase exhibited half-of-the-sites reactivity when incubated with DON in the absence of fructose 6-phosphate. In its presence, inactivation with [6-14C]DON was accompanied by incorporation of 1 equiv of inhibitor per enzyme subunit. From this behavior, a dimeric structure was tentatively assigned to the native enzyme. The site of reaction with DON was the NH2-terminal cysteine residue as shown by Edman degradation.     

The role of cysteine 206 in allosteric inhibition of Escherichia coli citrate synthase. Studies by chemical modification, site-directed mutagenesis, and 19F NMR

Escherichia coli citrate synthase is strongly and specifically inhibited by NADH, but this inhibition can be prevented by reacting the enzyme with Ellman's reagent. We have now labeled the single reactive cysteine covalently with monobromobimane and isolated and sequenced the bimane-containing cyanogen bromide peptide and identified the cysteine as Cys-206. Modeling studies suggest that this residue is on the subunit surface, 25-30 A from the active site. Mutation of Cys-206 to serine (C206S), or of Gly-207 to alanine (E207A), weakened NADH binding and inhibition; when these mutations were present together, NADH binding was weaker by 18-fold and inhibition by 250-fold. The mutations also had small effects on substrate binding at the active site. Cys-206 of wild type enzyme and of the mutant E207A was alkylated with 1,1,1-trifluorobromoacetone and the environment of the fluorine nuclei studied by 19F NMR. With wild type enzyme, the NMR spectrum consisted of two peaks of about equal intensity but different line widths, at -8.65 ppm (line width 11.2 +/- 0.5 Hz) and -7.6 ppm (line width 57 +/- 4 Hz). As the labeled wild type citrate synthase was titrated with KCl, the narrow peak converted to the broad one. The same range of KCl concentrations was needed for this conversion as for the allosteric activation of E. coli citrate synthase. The E207A mutant gave the broader NMR peak almost exclusively. We propose that the fluorine label in wild type citrate synthase exists in two conformational states with different mobilities, exchanging slowly on the NMR time scale, and that treatment with KCl, or truncation of the Glu-207 side chain by mutagenesis, stabilizes one of these states. Consistent with this explanation is the finding that Cys-206 reacts more quickly with Ellman's reagent in the presence of KCl, and that this rate is faster yet in the E207A mutant.     

Evidence for a histidine and a cysteine residue in the substrate-binding site of yeast alcohol dehydrogenase.

1. Yeast alcohol dehydrogenase (EC 1.1.1.1) is inhibited by stoicheiometric concentrations of diethyl pyrocarbonate. The inhibition is due to the acylation of a single histidine residue/monomer (mol.wt. 36000). 2. Alcohol dehydrogenase is also inhibited by stoicheiometric amounts of 5,5'-dithiobis-(2-nitrobenzoate), owing to the modification of a single cysteine residue/monomer. 3. Native alcohol dehydrogenase binds two molecules of reduced coenzyme/molecule of enzyme (mol.wt. 144000). 4. Modification of a single histidine residue/monomer by treatment with diethyl pyrocarbonate prevents the binding of acetamide in the ternary complex, enzyme-NADH-acetamede, but does not prevent the binding of NADH to the enzyme. 5. Modification of a single cysteine residue/monomer does not prevent the binding of acetamide to the ternary complex. After the modification of two thiol groups/monomer by treatment with 5,5'-dithiobis-(2-nitrobenzoate), the capacity of enzyme to bind coenzyme in the ternary complex was virtually abolished. 6. From the results presented in this paper we conclude that at least one histidine and one cysteine residue are closely associated in the substrate-binding site of alcohol dehydrogenase.     

Facilitated interaction between the pyruvate dehydrogenase kinase isoform 2 and the dihydrolipoyl acetyltransferase

The dihydrolipoyl acetyltransferase (E2) has an enormous impact on pyruvate dehydrogenase kinase (PDK) phosphorylation of the pyruvate dehydrogenase (E1) component by acting as a mobile binding framework and in facilitating and mediating regulation of PDK activity. Analytical ultracentrifugation (AUC) studies established that the soluble PDK2 isoform is a stable dimer. The interaction of PDK2 with the lipoyl domains of E2 (L1, L2) and the E3-binding protein (L3) were characterized by AUC. PDK2 interacted very weakly with L2 (Kd approximately 175 microM for 2 L2/PDK2) but much tighter with dimeric glutathione S-transferase (GST)-L2 (Kd approximately 3 microM), supporting the importance of bifunctional binding. Reduction of lipoyl groups resulted in approximately 8-fold tighter binding of PDK2 to GST-L2red, which was approximately 300-fold tighter than binding of 2 L2red and also much tighter than binding by GST-L1red and GST-L3red. The E2 60-mer bound approximately 18 PDK2 dimers with a Kd similar to GST-L2. E2.E1 bound more PDK2 (approximately 27.6) than E2 with approximately 2-fold tighter affinity. Lipoate reduction fostered somewhat tighter binding at more sites by E2 and severalfold tighter binding at the majority of sites on E2.E1. ATP and ADP decreased the affinity of PDK2 for E2 by 3-5-fold and adenosine 5'-(beta,gamma-imino)triphosphate or phosphorylation of E1 similarly reduced PDK2 binding to E2.E1. Reversible bifunctional binding to L2 with the mandatory singly held transition fits the proposed "hand-over-hand" movement of a kinase dimer to access E1 without dissociating from the complex. The gain in binding interactions upon lipoate reduction likely aids reduction-engendered stimulation of PDK2 activity; loosening of binding as a result of adenine nucleotides and phosphorylation may instigate movement of lipoyl domain-held kinase to a new E1 substrate.     

Inhibitor binding in a class 2 dihydroorotate dehydrogenase causes variations in the membrane-associated N-terminal domain

The flavin enzyme dihydroorotate dehydrogenase (DHOD; EC 1.3.99.11) catalyzes the oxidation of dihydroorotate to orotate, the fourth step in the de novo pyrimidine biosynthesis of UMP. The enzyme is a promising target for drug design in different biological and clinical applications for cancer and arthritis. The first crystal structure of the class 2 dihydroorotate dehydrogenase from rat has been determined in complex with its two inhibitors brequinar and atovaquone. These inhibitors have shown promising results as anti-proliferative, immunosuppressive, and antiparasitic agents. A unique feature of the class 2 DHODs is their N-terminal extension, which folds into a separate domain comprising two alpha-helices. This domain serves as the binding site for the two inhibitors and the respiratory quinones acting as the second substrate for the class 2 DHODs. The orientation of the first N-terminal helix is very different in the two complexes of rat DHOD (DHODR). Binding of atovaquone causes a 12 A movement of the first residue in the first alpha-helix. Based on the information from the two structures of DHODR, a model for binding of the quinone and the residues important for the interactions could be defined. His 56 and Arg 136, which are fully conserved in all class 2 DHODs, seem to play a key role in the interaction with the electron acceptor. The differences between the membrane-bound rat DHOD and membrane-associated class 2 DHODs exemplified by the Escherichia coli DHOD has been investigated by GRID computations of the hydrophobic probes predicted to interact with the membrane.     

Serine 948 and threonine 1042 are crucial residues for allosteric regulation of Escherichia coli carbamoylphosphate synthetase and illustrate coupling effects of activation and inhibition pathways

Escherichia coli carbamoylphosphate synthetase (CPSase) is a key enzyme in the pyrimidine nucleotides and arginine biosynthetic pathways. The enzyme harbors a complex regulation, being activated by ornithine and inosine 5'-monophosphate (IMP), and inhibited by UMP. CPSase mutants obtained by in vivo mutagenesis and selected on the basis of particular phenotypes have been characterized kinetically. Two residues, serine 948 and threonine 1042, appear crucial for allosteric regulation of CPSase. When threonine 1042 is replaced by an isoleucine residue, the enzyme displays a greatly reduced activation by ornithine. The T1042I mutated enzyme is still sensitive to UMP and IMP, although the effects of both regulators are reduced. When serine 948 is replaced by phenylalanine, the enzyme becomes insensitive to UMP and IMP, but is still activated by ornithine, although to a reduced extent. When correlating these observations to the structural data recently reported, it becomes clear that both mutations, which are located in spatially distinct regions corresponding respectively to the ornithine and the UMP/IMP binding sites, have coupled effects on the enzyme regulation. These results provide an illustration that coupling of regulatory pathways occurs within the allosteric subunit of E. coli CPSase.In addition, other mutants have been characterized, which display altered affinities for the different CPSase substrates and also slightly modified properties towards the allosteric effectors: P165S, P170L, A182V, P360L, S743N, T800F and G824D. Kinetic properties of these modified enzymes are also presented here and correlated to the crystal structure of E. coli CPSase and to the phenotype of the mutants.     

Histidinol dehydrogenase from salmonella typhimurium and Escherichia coli. Purification, some characteristics and the amino acid sequence around a reactive thiol group.

The purification and some physical properties of histidinol dehydrogenase, L-histidinol-nicotinamide adenine dinucleotide oxido-reductase (EC 1.1.1.23) from either Salmonella typhimurium or Escherichia coli are reported in this paper. Modification of histidinol dehydrogenase with one equivalent of N-(4-dimethylamino-3,5-dinitrophenyl)maleimide at pH 6.8 yields an enzyme that is inactive toward the oxidation of L-histidinol. The modified cysteine residue was located in an acid insoluble tryptic core. The amino acid sequence around the reactive thiol group in S. typhimurium is: Leu-Cys-Gly-Val-Glu-Glu-Ile-Phe, and in E. coli is: Leu-Cys-Gly-Val-Glu-Asp-Val-Phe. These unique sequences show no homology to the reactive thiol groups from some other dehydrogenases.     

Mutagenesis of folylpolyglutamate synthetase indicates that dihydropteroate and tetrahydrofolate bind to the same site

The folylpolyglutamate synthetase (FPGS) enzyme of Escherichia coli differs from that of Lactobacillus casei in having dihydrofolate synthetase activity, which catalyzes the production of dihydrofolate from dihydropteroate. The present study undertook mutagenesis to identify structural elements that are directly responsible for the functional differences between the two enzymes. The amino terminal domain (residues 1-287) of the E. coli FPGS was found to bind tetrahydrofolate and dihydropteroate with the same affinity as the intact enzyme. The domain-swap chimera proteins between the E. coli and the L. casei enzymes possess both folate or pteroate binding properties and enzymatic activities of their amino terminal portion, suggesting that the N-terminal domain determines the folate substrate specificity. Recent structural studies have identified two unique folate binding sites, the omega loop in L. casei FPGS and the dihydropteroate binding loop in the E. coli enzyme. Mutants with swapped omega loops retained the activities and folate or pteroate binding properties of the rest of the enzyme. Mutating L. casei FPGS to contain an E. coli FPGS dihydropteroate binding loop did not alter its substrate specificity to using dihydropteroate as a substrate. The mutant D154A, a residue specific for the dihydropteroate binding site in E. coli FPGS, and D151A, the corresponding mutant in the L. casei enzyme, were both defective in using tetrahydrofolate as their substrate, suggesting that the binding site corresponding to the E. coli pteroate binding site is also the tetrahydrofolate binding site for both enzymes. Tetrahydrofolate diglutamate was a slightly less effective substrate than the monoglutamate with the wild-type enzyme but was a 40-fold more effective substrate with the D151A mutant. This suggests that the 5,10-methylenetetrahydrofolate binding site identified in the L. casei ternary structure may bind diglutamate and polyglutamate folate derivatives.     

Insight into the chemistry of flavin reduction and oxidation in Escherichia coli dihydroorotate dehydrogenase obtained by rapid reaction studies

Dihydroorotate dehydrogenase (DHOD) oxidizes dihydroorotate (DHO) to orotate in the only redox reaction of pyrimidine biosynthesis. The enzyme from Escherichia coli is a membrane-bound FMN-containing enzyme that is thought to use ubiquinone as the oxidizing substrate. The chemistry of the reduction of the flavin in DHOD from E. coli by the substrate dihydroorotate (DHO) was studied at 4 degrees C in anaerobic stopped-flow experiments conducted over a broad range of pH values. A Michaelis complex that was characterized by a approximately 20 nm red-shift of the oxidized flavin absorbance formed within the dead-time of the stopped-flow instrument ( approximately 1 ms) upon mixing with DHO. The flavin of the intermediate was reduced by DHO, forming a reduced flavin-orotate charge-transfer complex. The rate constant for the flavin reduction reaction increased with pH, from a value of 1 s(-1) at pH 6.5 to approximately 360 s(-1) at pH values greater than an observed pK(a) of 9.5 which was ascribed to Ser175, the active-site base. At all pH values, the reduced flavin-orotate charge-transfer complex dissociated too slowly to be catalytically relevant. Therefore, the oxidizing quinone substrate must bind to the reduced enzyme-orotate complex at a site distinct from the substrate binding site, in agreement with steady-state kinetic studies [Bj?rnberg, O., Grüner, A.-C., Roepstorff, P., and Jensen, K. F. (1999) Biochemistry 38, 2899-2908]. Menadione was used as a model quinone substrate to oxidize dithionite-reduced DHOD. The reduced enzyme-orotate complex reacted rapidly with menadione (180 s(-1)), demonstrating that the reduced enzyme-orotate complex is a catalytically competent intermediate.     

Engineering the quaternary structure of an enzyme: construction and analysis of a monomeric form of malate dehydrogenase from Escherichia coli.

The citric acid cycle enzyme, malate dehydrogenase (MDH), is a dimer of identical subunits. In the crystal structures of 2 prokaryotic and 2 eukaryotic forms, the subunit interface is conformationally homologous. To determine whether or not the quaternary structure of MDH is linked to the catalytic activity, mutant forms of the enzyme from Escherichia coli have been constructed. Utilizing the high-resolution structure of E. coli MDH, the dimer interface was analyzed critically for side chains that were spatially constricted and needed for electrostatic interactions. Two such residues were found, D45 and S226. At their nearest point in the homodimer, they are in different subunits, hydrogen bond across the interface, and do not interact with any catalytic residues. Each residue was mutated to a tyrosine, which should disrupt the interface because of its large size. All mutants were cloned and purified to homogeneity from an mdh- E. coli strain (BHB111). Gel filtration of the mutants show that D45Y and D45Y/S226Y are both monomers, whereas the S226Y mutant remains a dimer. The monomeric D45Y and D45Y/S226Y mutants have 14,000- and 17,500-fold less specific activity, respectively, than the native enzyme. The dimeric S226Y has only 1.4-fold less specific activity. All forms crystallized, indicating they were not random coils. Data have been collected to 2.8 A resolution for the D45Y mutant. The mutant is not isomorphous with the native protein and work is underway to solve the structure by molecular replacement.     

Mechanism of flavin reduction in the class 1A dihydroorotate dehydrogenase from Lactococcus lactis

Dihydroorotate dehydrogenases (DHODs) oxidize dihydroorotate (DHO) to orotate (OA) using the FMN prosthetic group to abstract a hydride equivalent from C6 and a protein residue (cysteine for class 1A DHODs) to deprotonate C5. The fundamental question of whether the scission of the two DHO C-H bonds is concerted or stepwise was addressed for the class 1A enzyme from Lactococcus lactis by determining kinetic isotope effects (KIEs) on flavin reduction in anaerobic stopped-flow experiments. Isotope effects were determined at two pH values. At pH 7.0, KIEs were approximately 2-fold for DHO labeled singly at the 5-position or the 6-position and approximately 4-fold for DHO labeled at both the 5- and 6-positions. At pH 8.5, the KIEs observed for DHO labeled at the 5-position, the 6-position, and the 5- and 6-positions were approximately 2-, approximately 3-, and approximately 6-fold, respectively. These isotope effects are consistent with a concerted oxidation of DHO. The pH dependence of reduction was also determined, and a pKa of 8.3 was found. This pKa can be attributed to the ionization of the active site cysteine which deprotonates C5 of DHO during the reaction. To further investigate the importance of the active site base, two site-directed mutants were also studied: Cys130Ala (removal of the active site base) and Cys130Ser (replacement with the active site base used by class 2 DHODs). Both mutant enzymes exhibited binding affinities for DHO similar to that of the wild-type enzyme. Reduction of both mutants was extremely slow compared to that of the wild type; the rate of reduction increased with pH, showing no sign of a plateau. Interestingly, double-deuterium isotope effects on the Cys130Ser mutant also showed a concerted mechanism for flavin reduction.