Evidence for overlapping active sites in a multifunctional enzyme: immunochemical and chemical modification studies on C1-tetrahydrofolate synthase from Saccharomyces cerevisiae

The relationship of the active sites which catalyze the three reactions in the trifunctional enzyme C1-tetrahydrofolate synthase (C1-THF synthase) from Saccharomyces cerevisiae has been examined with immunochemical and chemical modification techniques. Immunotitration of the enzyme with a polyclonal antiserum resulted in identical inhibition curves for the dehydrogenase and cyclohydrolase activities which were distinctly different from the inhibition curve for the synthetase activity. During chemical modification with diethyl pyrocarbonate (DEPC), the three activities were inactivated at significantly different rates, indicating that at least three distinct essential residues are involved in the reaction with DEPC. The pH dependence of the reaction with DEPC was consistent with the modification of histidyl residues. Treatment of C1-THF synthase with N-ethylmaleimide (NEM) resulted in significant inactivation of only the dehydrogenase and cyclohydrolase activities, with the cyclohydrolase at least an order of magnitude more sensitive than the dehydrogenase. Inactivation of cyclohydrolase was biphasic at NEM concentrations above 0.1 mM, suggesting two essential cysteinyl residues were being modified. NADP+, a dehydrogenase substrate, protected both dehydrogenase and cyclohydrolase activities, but not synthetase activity, against inactivation by either reagent. Synthetase substrates had no protective ability. Pteroylpolyglutamates and p-aminobenzoic acid polyglutamates exhibited some protection of all three activities. The p-aminobenzoic acid polyglutamate series showed progressive protection with increasing chain length. These results are consistent with an overlapping site for the dehydrogenase and cyclohydrolase reactions, independent from the synthetase active site. Possible active-site configurations and the role of the polyglutamate tail in substrate binding are discussed.     

Site-directed mutagenesis and functional analysis of an active site tryptophan of insect chitinase

Chitinase is an enzyme used by insects to degrade the structural polysaccharide, chitin, during the molting process. Tryptophan 145 (W145) of Manduca sexta (tobacco hornworm) chitinase is a highly conserved residue found within a second conserved region of family 18 chitinases. It is located between aspartate 144 (D144) and glutamate 146 (E146), which are putative catalytic residues. The role of the active site residue, W145, in M. sexta chitinase catalysis was investigated by site-directed mutagenesis. W145 was mutated to phenylalanine (F), tyrosine (Y), isoleucine (I), histidine (H), and glycine (G). Wild-type and mutant forms of M. sexta chitinases were expressed in a baculovirus-insect cell line system. The chitinases secreted into the medium were purified and characterized by analyzing their catalytic activity and substrate or inhibitor binding properties. The wild-type chitinase was most active in the alkaline pH range. Several of the mutations resulted in a narrowing of the range of pH over which the enzyme hydrolyzed the polymeric substrate, CM-Chitin-RBV, predominantly on the alkaline side of the pH optimum curve. The range was reduced by about 1 pH unit for W145I and W145Y and by about 2 units for W145H and W145F. The W145G mutation was inactive. Therefore, the hydrophobicity of W145 appears to be critical for maintaining an abnormal pKa of a catalytic residue, which extends the activity further into the alkaline range. All of the mutant enzymes bound to chitin, suggesting that W145 was not essential for binding to chitin. However, the small difference in Km's of mutated enzymes compared to Km values of the wild-type chitinase towards both the oligomeric and polymeric substrates suggested that W145 is not essential for substrate binding but probably influences the ionization of a catalytically important group(s). The variations in kcat's among the mutated enzymes and the IC50 for the transition state inhibitor analog, allosamidin, indicate that W145 also influences formation of the transition state during catalysis.     

Site-directed mutagenesis of a conserved region of the 5-enolpyruvylshikimate-3-phosphate synthase active site

The active site of the enzyme 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) has been probed using site-directed mutagenesis and inhibitor binding techniques. Replacement of a specific glycyl with an alanyl or a prolyl with a seryl residue in a highly conserved region confers glyphosate tolerance to several bacterial and plant EPSPS enzymes, suggesting a high degree of structural conservation between these enzymes. The glycine to alanine substitution corresponding to Escherichia coli EPSPS G96A increases the Ki(app) (glyphosate) of petunia EPSPS 5000-fold while increasing the Km(app)(phosphoenolpyruvate) about 40-fold. Substitution of this glycine with serine, however, abolishes EPSPS activity but results in the elicitation of a novel EPSP hydrolase activity whereby EPSP is converted to shikimate 3-phosphate and pyruvate. This highly conserved region is critical for the interaction of the phosphate moiety of phosphoenolpyruvate with EPSPS.     

Site-directed mutagenesis of two aromatic residues lining the active site pocket of the yeast Ltp1

We mutated Trp(134) and Tyr(135) of the yeast LMW-PTP to explore their catalytic roles, demonstrating that the mutations of Trp(134) to Tyr or Ala, and Tyr(135) to Ala, all interfere with the formation of the phosphorylenzyme intermediate, a phenomenon that can be seen by the decrease in the kinetic constant of the chemical step (k(3)). Furthermore, we noted that the Trp(134) to Ala mutation causes a dramatic drop in k(cat)/K(m) and a slight enhancement of the dissociation constant K(s). The conservative mutant W134Y shows a k(cat)/K(m) very close to that of wild type, probably compensating the two-fold decrease of k(3) with an increase in substrate affinity. The Y135A mutation enhances the substrate affinity, but reduces the enzyme phosphorylation rate. The replacement of Trp(134) with alanine interferes with the partition between phosphorylenzyme hydrolysis and phosphotransfer from the phosphorylenzyme to glycerol and abolish the enzyme activation by adenine. Finally, we found that mutation of Trp(134) to Ala causes a dramatic change in the pH-rate profile that becomes similar to that of the D132A mutant, suggesting that an aromatic residue in position 134 is necessary to assist the proper positioning of the proton donor in the transition state of the chemical step.     

Site-directed mutagenesis of active site residues of phosphite dehydrogenase

Phosphite dehydrogenase (PTDH) catalyzes the unusual oxidation of phosphite to phosphate with the concomitant reduction of NAD(+) to NADH. PTDH shares significant amino acid sequence similarity with D-hydroxy acid dehydrogenases (DHs), including strongly conserved catalytic residues His292, Glu266, and Arg237. Site-directed mutagenesis studies corroborate the essential role of His292 as all mutants of this residue were completely inactive. Histidine-selective inactivation studies with diethyl pyrocarbonate provide further evidence regarding the importance of His292. This residue is most likely the active site base that deprotonates the water nucleophile. Kinetic analysis of mutants in which Arg237 was changed to Leu, Lys, His, and Gln revealed that Arg237 is involved in substrate binding. These results agree with the typical role of this residue in D-hydroxy acid DHs. However, Glu266 does not play the typical role of increasing the pK(a) of His292 to enhance substrate binding and catalysis as the Glu266Gln mutant displayed an increased k(cat) and unchanged pH-rate profile compared to those of wild-type PTDH. The role of Glu266 is likely the positioning of His292 and Arg237 with which it forms hydrogen bonds in a homology model. Homology modeling suggests that Lys76 may also be involved in substrate binding, and this postulate is supported by mutagenesis studies. All mutants of Lys76 display reduced activity with large effects on the K(m) for phosphite, and Lys76Cys could be chemically rescued by alkylation with 2-bromoethylamine. Whereas a positively charged residue is absolutely essential for activity at the position of Arg237, Lys76 mutants that lacked a positively charged side chain still had activity, indicating that it is less important for binding and catalysis. These results highlight the versatility of nature's catalytic scaffolds, as a common framework with modest changes allows PTDH to catalyze its unusual nucleophilic displacement reaction and d-hydroxy acid DHs to oxidize alcohols to ketones.     

Regulation of expression of the ADE3 gene for yeast C1-tetrahydrofolate synthase, a trifunctional enzyme involved in one-carbon metabolism

C1-THF (5,6,7,8-tetrahydrofolate) synthase is a trifunctional protein catalyzing the sequential reactions specified by the enzymes 10-formyl-THF synthetase (EC 6.3.4.3), 5,10-methenyl-THF cyclohydrolase (EC 3.5.4.9), and 5,10-methylene-THF dehydrogenase (EC 1.5.1.5). These three activities supply the activated one-carbon units required for the biosynthesis of purines, thymidylate, the amino acids histidine and methionine, the vitamin pantothenic acid, and the formyl group of mitochondrial fMet-tRNAfMet. Extracts of Saccharomyces cerevisiae whose growth is dependent on the three activities of C1-THF synthase contain 2-3 times the level of enzyme activity of extracts from cells grown under conditions where they are independent of this enzyme. Repression of C1-THF synthase activity requires the simultaneous presence of adenine, histidine, methionine, and pantothenic acid. Starvation of the cells for any one of these nutrients leads to derepression of the enzyme. Drug-induced folate starvation also leads to derepression of enzyme activity. The response to changing nutritional conditions occurs within 1 h and is due to changes in the steady-state concentration of C1-THF synthase enzyme, rather than to activation or deactivation of a pre-existing pool of enzyme. Determination of the amount of C1-THF synthase mRNA under the various growth conditions by an in vitro translation/immunoprecipitation assay indicates that regulation of the enzyme occurs predominantly at a pretranslational level since steady-state levels of C1-THF synthase mRNA are 2-3-fold higher in derepressed cells than in repressed cells.     

Site-directed mutagenesis of active site residues in Bacillus subtilis alpha-amylase.

Site-directed mutagenesis of Bacillus subtilis N7 alpha-amylase has been performed to evaluate the roles of the active site residues in catalysis and to prepare an inactive catalytic-site mutant that can form a stable complex with natural substrates. Mutation of Asp-176, Glu-208, and Asp-269 to their amide forms resulted in over a 15,000-fold reduction of its specific activity, but all the mutants retained considerable substrate-binding abilities as estimated by gel electrophoresis in the presence of soluble starch. Conversion of His-180 to Asn resulted in a 20-fold reduction of kcat with a 5-fold increase in Km for a maltopentaose derivative. The relative affinities for acarbose vs. maltopentaose were also compared between the mutants and wild-type enzyme. The results are consistent with the roles previously proposed in Taka-amylase A and porcine pancreatic alpha-amylase based on their X-ray crystallographic analyses, although different pairs had been assigned as catalytic residues for each enzyme. Analysis of the residual activity of the catalytic-site mutants by gel electrophoresis has suggested that it derived from the wild-type enzyme contaminating the mutant preparations, which could be removed by use of an acarbose affinity column; thus, these mutants are completely devoid of activity. The affinity-purified mutant proteins should be useful for elucidating the complete picture of the interaction of this enzyme with starch.     

Site-directed mutagenesis of cysteine to threonine in Proteus vulgaris urease active site increases enzyme activity and stability

Cysteine-319 belongs to the flexible flap at the active site of Proteus vulgaris urease. Replacing this cysteine by threonine resulted in a 20-fold increase of specific activity. Temperature stability increased, susceptibility to inhibition by dipyridyl disulfide decreased, and pH optimum shifted from 8 to 6.9. K _m (35 to 12 mM) and V_max (47.4 to 1.8 mol min^–1) were substancially altered. Both variants of the enzyme were irreversibly inhibited by phenylmethanesulfonyl fluoride.     

Enzymatic characterization of human mitochondrial C1-tetrahydrofolate synthase

A human mitochondrial isozyme of C1-tetrahydrofolate (THF) synthase was previously identified by its similarity to the human cytoplasmic C1-THF synthase. All C1-THF synthases characterized to date, from yeast to human, are trifunctional, containing the activities of 5,10-methylene-THF dehydrogenase, 5,10-methenyl-THF cyclohydrolase, and 10-formyl-THF synthetase. Here we report on the enzymatic characterization of the recombinant human mitochondrial isozyme. Enzyme assays of purified human mitochondrial C1-THF synthase protein revealed only the presence of 10-formyl-THF synthetase activity. Gel filtration and crosslinking studies indicated that human mitochondrial C1-THF synthase exists as a homodimer in solution. Steady-state kinetic characterization of the 10-formyl-THF synthetase activity was performed using (6R,S)-H4-PteGlu1, (6R,S)-H4-PteGlu3, and (6R,S)-H4-PteGlu5 substrates. The (6R,S)-H4-PteGlun Km dropped from greater than 500 microM for the monoglutamate to 15 microM and 3.6 microM for the tri- and pentaglutamates, respectively. The Km values for formate and ATP also are lowered when THF polyglutamates are used. The formate Km dropped 79-fold and the ATP Km dropped more than 5-fold when (6R,S)-H4-PteGlu5 was used as the substrate in place of (6R,S)-H4-PteGlu1.     

Immunolocalization of C1-tetrahydrofolate synthase in the rat kidney

The distribution of the trifunctional enzyme C1-tetrahydrofolate synthase (C1-THF synthase) was examined in the rat kidney by immunolocalization with anti-C1-THF synthase serum using the peroxidase-antiperoxidase method. C1-THF synthase immunoreactivity was detected in both distal and proximal epithelial cells. Staining of the distal tubule epithelia was more intense and granular whereas staining of the proximal tubule epithelia was diffuse. All cells of the cortical collecting duct showed positive granular staining. In the outer medullary collecting duct, the intercalated cells showed intense granular cytoplasmic staining and the principal cells were either negative or weakly positive. The ascending thick limb of Henle's loop was also positive. Glomeruli and the inner medulla showed no staining for C1-THF synthase.     

Site-directed mutagenesis of the active site cysteine in Klebsiella aerogenes urease.

Cysteine 319 in the large subunit of Klebsiella aerogenes urease was identified as an essential catalytic residue based on chemical modification studies (Todd, M.J., and Hausinger, R.P. (1991) J. Biol. Chem. 266, 24327-24331). Through site-directed mutagenesis, this cysteine has been changed independently to alanine, serine, aspartate, and tyrosine. None of these mutations (C319A, C319S, C319D, and C319Y, respectively) affected the size or level of synthesis of the urease subunits as monitored by polyacrylamide gel electrophoresis. The wild type enzyme and each of the mutant proteins was purified and their properties were compared. The C319Y protein possessed no detectable activity, while activity was reduced in C319A, C319S, and C319D to 48, 4.5, and 0.03% of wild type levels under normal assay conditions. All of the active mutants had a small increase in Km when compared to the wild type value. The active mutants displayed a greatly reduced sensitivity to inactivation by iodoacetamide in comparison to the wild type enzyme, confirming our previous assignment of the essential cysteine to this residue based on active site peptide mapping. In contrast to the wild type enzyme, inactivation of the mutant proteins was not affected by the presence of the competitive inhibitor phosphate, suggesting that the remaining slow rate of iodoacetamide inactivation is due to modification away from the active site. The pH dependence of urease activity was substantially altered in the active mutants with C319S and C319D showing a pH optimum near 5.2, and C319A near 6.7, compared to the pH 7.75 optimum of wild type urease. These data are consistent with Cys-319 facilitating catalysis at neutral and basic pH values by participating as a general acid.     

Site-directed mutagenesis of selected residues at the active site of aryl-alcohol oxidase, an H2O2-producing ligninolytic enzyme

Aryl-alcohol oxidase provides H(2)O(2) for lignin biodegradation, a key process for carbon recycling in land ecosystems that is also of great biotechnological interest. However, little is known of the structural determinants of the catalytic activity of this fungal flavoenzyme, which oxidizes a variety of polyunsaturated alcohols. Different alcohol substrates were docked on the aryl-alcohol oxidase molecular structure, and six amino acid residues surrounding the putative substrate-binding site were chosen for site-directed mutagenesis modification. Several Pleurotus eryngii aryl-alcohol oxidase variants were purified to homogeneity after heterologous expression in Emericella nidulans, and characterized in terms of their steady-state kinetic properties. Two histidine residues (His502 and His546) are strictly required for aryl-alcohol oxidase catalysis, as shown by the lack of activity of different variants. This fact, together with their location near the isoalloxazine ring of FAD, suggested a contribution to catalysis by alcohol activation, enabling its oxidation by flavin-adenine dinucleotide (FAD). The presence of two aromatic residues (at positions 92 and 501) is also required, as shown by the conserved activity of the Y92F and F501Y enzyme variants and the strongly impaired activity of Y92A and F501A. By contrast, a third aromatic residue (Tyr78) does not seem to be involved in catalysis. The kinetic and spectral properties of the Phe501 variants suggested that this residue could affect the FAD environment, modulating the catalytic rate of the enzyme. Finally, L315 affects the enzyme k(cat), although it is not located in the near vicinity of the cofactor. The present study provides the first evidence for the role of aryl-alcohol oxidase active site residues.     

Site-directed mutagenesis at the active site Trp120 of Aspergillus awamori glucoamylase

Trp120 of Aspergillus awamori glucoamylase has previously been shown by chemical modification to be essential for activity and tentatively to be located near subsite 4 of the active site. To further test its role, restriction sites were inserted in the cloned A.awamori gene around the Trp120 coding region, and cassette mutagenesis was used to replace it with His, Leu, Phe and Tyr. All four mutants displayed 2% or less of the maximal activity (kcat) of wild-type glucoamylase towards maltose and maltoheptaose. Michaelis constants (KM) of mutants decreased 2- to 3-fold for maltose and were essentially unchanged for maltoheptaose compared with the wild type, except for a greater than 3-fold decrease for maltoheptaose with the Trp120----Tyr mutant. This mutant also bound isomaltose more strongly and had more selectivity for its hydrolysis than wild-type glucoamylase. A subsite map generated from malto-oligosaccharide substrates having 2-7 D-glucosyl residues indicated that subsites 1 and 2 had greater affinity for D-glucosyl residues in the Trp120----Tyr mutant than in wild-type glucoamylase. These results suggest that Trp120 from a distant subsite is crucial for the stabilization of the transition-state complex in subsites 1 and 2.     

Site-directed mutagenesis studies of acetylglutamate synthase delineate the site for the arginine inhibitor

N-acetyl-l-glutamate synthase (NAGS), the first enzyme of bacterial/plant arginine biosynthesis and an essential activator of the urea cycle in animals, is, respectively, arginine-inhibited and activated. Site-directed mutagenesis of recombinant Pseudomonas aeruginosa NAGS (PaNAGS) delineates the arginine site in the PaNAGS acetylglutamate kinase-like domain, and, by extension, in human NAGS. Key residues for glutamate binding are identified in the acetyltransferase domain. However, the acetylglutamate kinase-like domain may modulate glutamate binding, since one mutation affecting this domain increases the K_m for glutamate. The effects on PaNAGS of two mutations found in human NAGS deficiency support the similarity of bacterial and human NAGSs despite their low sequence identity.     

Site-directed mutagenesis and high-resolution NMR spectroscopy of the active site of porphobilinogen deaminase

The active site of porphobilinogen (PBG)1 deaminase (EC 4.3.1.8) from Escherichia coli has been found to contain an unusual dipyrromethane derived from four molecules of 5-aminolevulinic acid (ALA) covalently linked to Cys-224, one of the two cysteine residues conserved in E. coli and human deaminase. By use of a hemA- strain of E. coli the enzyme was enriched from [5-13C]ALA and examined by 1H-detected multiple quantum coherence spectroscopy, which revealed all of the salient features of a dipyrromethane composed of two PBG units linked head to tail and terminating in a CH2-S bond to a cysteine residue. Site-specific mutagenesis of Cys-99 and Cys-242, respectively, has shown that substitution of Ser for Cys-99 does not affect the enzymatic activity, whereas substitution of Ser for Cys-242 removes essentially all of the catalytic activity as measured by the conversion of the substrate PBG to uro'gen I. The NMR spectrum of the covalent complex of deaminase with the suicide inhibitor 2-bromo-[2,11-13C2]PBG reveals that the aninomethyl terminus of the inhibitor reacts with the enzyme's cofactor at the alpha-free pyrrole. NMR spectroscopy of the ES2 complex confirmed a PBG-derived head-to-tail dipyrromethane attached to the alpha-free pyrrole position of the enzyme. A mechanistic rationale for deaminase is presented.     

Site-directed mutagenesis of firefly luciferase active site amino acids: a proposed model for bioluminescence color.

Under physiological conditions firefly luciferase catalyzes the highly efficient emission of yellow-green light from the substrates luciferin, Mg-ATP, and oxygen. In nature, bioluminescence emission by beetle luciferases is observed in colors ranging from green (approximately 530 nm) to red (approximately 635 nm), yet all known luciferases use the same luciferin substrate. In an earlier report [Branchini, B. R., Magyar, R. M., Murtiashaw, M. H., Anderson, S. M., and Zimmer, M. (1998) Biochemistry 37, 15311-15319], we described the effects of mutations at His245 on luciferase activity. In the context of molecular modeling results, we proposed that His245 is located at the luciferase active site. We noted too that the H245 mutants displayed red-shifted bioluminescent emission spectra. We report here the construction and purification of additional His245 mutants, as well as mutants at residues Lys529 and Thr343, all of which are stringently conserved in the beetle luciferase sequences. Analysis of specific activity and steady-state kinetic constants suggested that these residues are involved in luciferase catalysis and the productive binding of substrates. Bioluminescence emission spectroscopy studies indicated that point mutations at His245 and Thr343 produced luciferases that emitted light over the color range from green to red. The results of mutational and biochemical studies with luciferase reported here have enabled us to propose speculative mechanisms for color determination in firefly bioluminescence. An essential role for Thr343, the participation of His245 and Arg218, and the involvement of bound AMP are indicated.     

Molecular genetic analysis of Saccharomyces cerevisiae C1-tetrahydrofolate synthase mutants reveals a noncatalytic function of the ADE3 gene product and an additional folate-dependent enzyme.

In eucaryotes, 10-formyltetrahydrofolate (formyl-THF) synthetase, 5,10-methenyl-THF cyclohydrolase, and NADP(+)-dependent 5,10-methylene-THF dehydrogenase activities are present on a single polypeptide termed C1-THF synthase. This trifunctional enzyme, encoded by the ADE3 gene in the yeast Saccharomyces cerevisiae, is thought to be responsible for the synthesis of the one-carbon donor 10-formyl-THF for de novo purine synthesis. Deletion of the ADE3 gene causes adenine auxotrophy, presumably as a result of the lack of cytoplasmic 10-formyl-THF. In this report, defined point mutations that affected one or more of the catalytic activities of yeast C1-THF synthase were generated in vitro and transferred to the chromosomal ADE3 locus by gene replacement. In contrast to ADE3 deletions, point mutations that inactivated all three activities of C1-THF synthase did not result in an adenine requirement. Heterologous expression of the Clostridium acidiurici gene encoding a monofunctional 10-formyl-THF synthetase in an ade3 deletion strain did not restore growth in the absence of adenine, even though the monofunctional synthetase was catalytically competent in vivo. These results indicate that adequate cytoplasmic 10-formyl-THF can be produced by an enzyme(s) other than C1-THF synthase, but efficient utilization of that 10-formyl-THF for purine synthesis requires a nonenzymatic function of C1-THF synthase. A monofunctional 5,10-methylene-THF dehydrogenase, dependent on NAD+ for catalysis, has been identified and purified from yeast cells (C. K. Barlowe and D. R. Appling, Biochemistry 29:7089-7094, 1990). We propose that the characteristics of strains expressing full-length but catalytically inactive C1-THF synthase could result from the formation of a purine-synthesizing multienzyme complex involving the structurally unchanged C1-THF synthase and that production of the necessary one-carbon units in these strains is accomplished by an NAD+ -dependent 5,10-methylene-THF dehydrogenase.     

Site-directed mutagenesis identifies catalytic residues in the active site of Escherichia coli phosphofructokinase.

Six active site mutants of Escherichia coli phosphofructokinase have been constructed and characterized using steady-state kinetics. All but one of the mutants (ES222) have significantly lower maximal activity, implicating these residues in the catalytic process. Replacement of Asp127, the key catalytic residue in the forward reaction with Glu, results in an enzyme with wild-type cooperative and allosteric behavior but severely decreased Fru6P binding. Replacement of the same residue with Tyr abolishes cooperativity while retaining sensitivity to allosteric inhibition and activation. Thus, this mutant has uncoupled homotropic from heterotropic allostery. Mutation of Asp103 to Ala results in an enzyme which retains wild-type Fru6P-binding characteristics with reduced activity. GDP, which allosterically activates the wild-type enzyme, acts as a mixed inhibitor for this mutant. Mutation of Thr125 to Ala and Asp129 to Ser produces mutants with impaired Fru6P binding and decreased cooperativity. In the presence of the activator GDP, both these mutants display apparent negative cooperativity. In addition, ATP binding is now allosterically altered by GDP. These results extend the number of active site residues known to participate in the catalytic process and help to define the mechanisms behind catalysis and homotropic and heterotropic allostery.     

Site-directed mutagenesis and biochemical analysis of the endogenous ligands in the ferrous active site of clavaminate synthase. The His-3 variant of the 2-His-1-carboxylate model

The facial 2-His-1-carboxylate (Asp/Glu) motif has emerged as the structural paradigm for metal binding in the alpha-ketoglutarate (alpha-KG)-dependent nonheme iron oxygenases. Clavaminate synthase (CS2) is an unusual member of this enzyme family that mediates three different, nonsequential reactions during the biosynthesis of the beta-lactamase inhibitor clavulanic acid. In this study, covalent modification of CS2 by the affinity label N-bromoacetyl-L-arginine near His297, which is within the HRV signature of a His-2 motif, suggested this histidine could play a role in metal coordination. However, site-specific mutagenesis of eight His residues to Gln identified His145 and His280, but not His297, as involved in iron binding. Weak homology of His145 and its flanking sequence and the presence of Glu147 fitting the canonical acidic residue of the His-Xaa-Asp/Glu signature are consistent with His145 being a coordinating ligand (His-1). His280 and its flanking sequence, which give poor alignments to most other members of this enzyme family, are similar among a subset of these enzymes and notably to CarC, an apparent oxygenase involved in carbapenem biosynthesis. The separation of His145 and His280 is more than twice that seen in the current 2-His-1-carboxylate model and may define an alternative iron binding motif, which we propose as His-3. These ligand assignments, based on kinetic measurements of both oxidative cyclization/desaturation and hydroxylation assays, establish that no histidine ligand switching occurs during the catalytic cycle. These results are confirmed in a recent X-ray crystal structure of CS1, a highly similar isozyme of CS2 (81% identical). Tyr299, Tyr300 in CS2 modified by N-bromoacetyl-L-arginine, is hydrogen bonded to Glu146 (Glu147 in CS2) in this structure and well-positioned for reaction with the affinity label.