Dihydroxy acid dehydratase from spinach contains a [2Fe-2S] cluster

Dihydroxy acid dehydratase, the third enzyme in the branched-chain amino acid biosynthetic pathway, has been purified to homogeneity (5000-fold) from spinach leaves. The molecular weights of dihydroxy acid dehydratase as determined by sodium dodecyl sulfate and native gel electrophoresis are 63,000 and 110,000, respectively, suggesting the native enzyme is a dimer. 2 moles of iron were found per mol of protein monomer. Chemical analyses of iron and labile sulfide gave an Fe/S2- ratio of 0.95. The EPR spectrum of dithionite-reduced enzyme (gavg = 1.91) is similar to spectra characteristic of Rieske Fe-S proteins and has a spin concentration of 1 spin/1.9 irons. These results strongly suggest that dihydroxy acid dehydratase contains a [2Fe-2S] cluster, a novel finding for enzymes of the hydrolyase class. In contrast to the Rieske Fe-S proteins, the redox potential of the Fe-S cluster is quite low (-470 mV). Upon addition of substrate, the EPR signal of the reduced enzyme changes to one typical of 2Fe ferredoxins (gavg = 1.95), and the visible absorption spectrum of the native enzyme shows substantial changes between 400 and 600 nm. Reduction of the Fe-S cluster decreases the enzyme activity by 6-fold under Vmax conditions. These results suggest the direct involvement of the [2Fe-2S] cluster of dihydroxy acid dehydratase in catalysis. Similar conclusions have been reached for the catalytic involvement of the [4Fe-4S] cluster of the hydrolyase aconitase (Emptage, M. H., Kent, T. A., Kennedy, M. C., Beinert, H., and Münck, E. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 4674-4678).     

Identification and characterization of the bacterial <Emphasis Type="SmallCaps">d</Emphasis>-gluconate dehydratase in <Emphasis Type="Italic">Achromobacter xylosoxidans</Emphasis>

Achromobacter xylosoxidans is known to utilize d-glucose via the modified Entner-Doudoroff pathway. Although d-gluconate dehydratase produced from this bacterium was purified and partially characterized previously, a gene that encodes this enzyme has not yet been identified. To obtain protein information on bacterial d-gluconate dehydratase, we partially purified d-gluconate dehydratase in A. xylosoxidans and investigated its biochemical properties. Two degenerate primers were designed based on the N-terminal amino acid sequence of the partially purified d-gluconate dehydratase. Through PCR performed using degenerate primers, a 1,782-bp DNA sequence encoding the A. xylosoxidans d-gluconate dehydratase (gnaD) was obtained. The deduced amino acid sequence of A. xylosoxidans gnaD showed strong similarity with that of proteins belonging to the dihydroxy-acid dehydratase/phosphogluconate dehydratase family (COG0129). This is in contrast to the archaeal d-gluconate dehydratase, which belongs to the enolase superfamily (COG4948). The phylogenetic tree showed that A. xylosoxidans d-gluconate dehydratase is closer to the 6-phosphogluconate dehydratase than the dihydroxy-acid dehydratase. Interestingly, a clade containing A. xylosoxidans enzyme was clustered with proteins annotated as a second and a third dihydroxy-acid dehydratase in the genomes of Clostridium acetobutylicum (Cac_ilvD2) and Streptomyces ceolicolor (Sco_ilvD2, Sco_ilvD3), indicating that the function of these enzymes is the dehydration of d-gluconate.     

Substrate specificity engineering of beta-mannosidase and beta-glucosidase from Pyrococcus by exchange of unique active site residues

A beta-mannosidase gene (PH0501) was identified in the Pyrococcus horikoshii genome and cloned and expressed in E. coli. The purified enzyme (BglB) was most specific for the hydrolysis of p-nitrophenyl-beta-D-mannopyranoside (pNP-Man) (Km: 0.44 mM) with a low turnover rate (kcat: 4.3 s(-1)). The beta-mannosidase has been classified as a member of family 1 of glycoside hydrolases. Sequence alignments and homology modeling showed an apparent conservation of its active site region with, remarkably, two unique active site residues, Gln77 and Asp206. These residues are an arginine and asparagine residue in all other known family 1 enzymes, which interact with the catalytic nucleophile and equatorial C2-hydroxyl group of substrates, respectively. The unique residues of P. horikoshii BglB were introduced in the highly active beta-glucosidase CelB of Pyrococcus furiosus and vice versa, yielding two single and one double mutant for each enzyme. In CelB, both substitutions R77Q and N206D increased the specificity for mannosides and reduced hydrolysis rates 10-fold. In contrast, BglB D206N showed 10-fold increased hydrolysis rates and 35-fold increased affinity for the hydrolysis of glucosides. In combination with inhibitor studies, it was concluded that the substituted residues participate in the ground-state binding of substrates with an equatorial C2-hydroxyl group, but contribute most to transition-state stabilization. The unique activity profile of BglB seems to be caused by an altered interaction between the enzyme and C2-hydroxyl of the substrate and a specifically increased affinity for mannose that results from Asp206.     

Disruption of active site interactions with pyridoxal 5'-phosphate and substrates by conservative replacements in the glycine-rich loop of Escherichia coli D-serine dehydratase

We have used site-directed mutagenesis to examine the function of three putative active site residues (C278, G279, and G281) of the vitamin B6 enzyme D-serine dehydratase. These residues lie in or adjacent to a conserved glycine-rich loop that is known to interact with the pyridoxal 5'-phosphate cofactor in several B6 enzymes and that resembles the GXGXXG loop of nucleotide-binding sites. The cofactor affinity, catalytic properties, and spectral properties (UV, CD, fluorescence, and 31P NMR) of alanine variants C278A, G279A, and G281A were measured as well as the susceptibility of each variant to thiol modification by 5,5'-dithiobis(2-nitrobenzoic acid). The specific thiols modified in each variant and wild type D-serine dehydratase were identified by amino acid sequencing of labeled tryptic peptides. C278A, G279A, and G281A displayed 10-, 33-, and 22-fold lower affinities for pyridoxal 5'-phosphate than did wild type D-serine dehydratase and turnover numbers with D-serine that were 50, 6, and 60% of normal, respectively. The introduction of a methyl side chain into G281 enhanced catalytic efficiency with the substrates D-threonine, D-allo-threonine, and L-serine, whereas the methyl side chain at position 279 impaired catalysis of all substrates as well as cofactor affinity. The 31P NMR spectrum of D-serine dehydratase was minimally perturbed by the alanine substitutions, consistent with the view that neither G279 nor G281 interacts with the phosphate group of the cofactor (in contrast to the arrangement found in several other B6 enzymes). C311 was the single thiol modified by 5,5'-dithiobis(2-nitrobenzoic acid) in wild type D-serine dehydratase. Two normally inaccessible thiol groups, C233 and C278, were rendered susceptible to modification as a consequence of either G----A substitution, and modification of C278 was associated with inactivation of G279A and G281A. These observations suggest that small perturbations in the glycine-rich loop induce conformational changes spanning a considerable area around the active site.     

Alternative binding modes for chloramphenicol and 1-substituted chloramphenicol analogues revealed by site-directed mutagenesis and X-ray crystallography of chloramphenicol acetyltransferase

Leucine-160 of chloramphenicol acetyltransferase (CAT) has been replaced by site-directed mutagenesis to investigate enzyme-ligand interactions at the 1-hydroxyl substituent of the substrate chloramphenicol. The consequences of the substitution of Leu-160 by glutamine and by phenylalanine were deduced from the steady-state kinetic parameters for acetyl transfer from acetyl-CoA to the 3-hydroxyl of chloramphenicol and its analogues 1-deoxychloramphenicol and 1-acetylchloramphenicol. The acetyl group of the latter, which is a substrate both in vivo and in vitro, could potentially bind in a similar position to the 1-hydroxyl of chloramphenicol, in close proximity to the side chain of Leu-160. In the case of Gln-160 CAT, large increases in Km for the three acetyl acceptors were accompanied by small decreases in kcat and in apparent affinity for acetyl-CoA. Such results are consistent with the introduction of the relatively hydrophilic amide in place of the delta-methyl groups of Leu-160. The kinetic properties of Phe-160 CAT were unexpected in that Km for each of the three acetyl acceptors was unchanged or reduced, compared to the equivalent parameters for the wild-type enzyme, whereas kcat fell significantly (44-83-fold) in each case. The ratios of specificity constants (kcat/Km) for the acetylation of chloramphenicol compared with the alternative acyl acceptors were similar for wild-type and mutant enzymes. As the residue substitutions for Leu-160 do not result in enhanced discrimination against the binding and acetylation of 1-acetylchloramphenicol, it appears unlikely that the 1-acetyl group binds to the CAT active site in the same position as that occupied by the 1-hydroxyl of chloramphenicol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparation and application of an affinity matrix for phosphatidylinositol-specific phospholipase C

A non-hydrolyzable phosphonate analogue of phosphatidyl inositol, racemic myo-inosityl-(1)-5-oxa-16-trifluoroacetamidohexadecyl phosphonate, was synthesized. This phosphonate inhibited the activity of phosphatidyl inositol-specific phospholipase C (PI-PLC) from Bacillus cereus with an IC50 of approximately 10 mM. Removal of the trifluoroacetyl blocking group followed by covalent binding of the phosphonate to cyanogen bromide activated Sepharose 4B via the amino group produced an affinity matrix specific for the PI-PLC from B. cereus. This affinity matrix was used to purify the phospholipase C from a complex mixture of proteins in a single step. Competition experiments with myo-inositol in the elution medium indicated that specific binding of the enzyme to the matrix most likely involves the enzyme active site. The inositol phosphonate derivatized matrix was stable over several months in neutral and alkaline media and was used repeatedly without loss of binding capacity. These results show that affinity matrices employing myo-inositol phosphonate ligands are useful for isolation and binding studies of PI-PLC and possibly of other enzymes interacting with phosphoinositides or myo-inositol phosphate derivatives.     

Roles of β-d-ribofuranose ring and the functional groups of the d-ribose moiety of adenosylcobalamin in the diol dehydratase reaction

Four analogs of adenosylcobalamin (AdoCbl) modified in the d-ribose moiety of the Coβ ligand were synthesized, and their coenzyme properties were studied with diol dehydratase of Klebsiella pneumoniae ATCC 8724. 2′-Deoxyadenosylcobalamin (2′-dAdoCbl) and 3′-deoxyadenosylcobalamin (3′-dAdoCbl) were active as coenzyme. 2′,3′-Secoadenosylcobalamin (2′,3′-secoAdoCbl), an analog bearing the same functional groups as AdoCbl but nicked between the 2′ and 3′ in the ribose moiety, and its 2′,3′-dialdehyde derivative (2′,3′-secoAdoCbl dialdehyde) were totally inactive analogs of the coenzyme. It is therefore evident that the β-d-ribofuranose ring itself, possibly its rigid structure, is essential and much more important than the functional groups of the ribose moiety for coenzyme function (relative importance; β-d-ribofuranose ring ⪢ 3′-OH ⪢ 2′-OH ⪢ ether group). With 2′-dAloCbl and 3′-dAdoCbl as enzymes. an absorption peak at 478 nm appeared during enzymatic reaction, suggesting homolysis of the CCo bound to form cob(II)alamin as intermediate. In the absence of substrate, the complexes of the enzyme with these active analogs underwent rapid inactivation by oxygen. This suggests that their CCo bond is activated even in the absence of substrate by binding to the apoprotein. No significant spectral changes were observed with 2′,3′-secoAdoCbl upon binding to the apoenzyme. In contrast, spectroscopic observation indicates that 2′,3′-secoAdoCbl dialdehyde, another inactive analog, underwent gradual and irreversible cleavage of the CCo bond by interaction with the apodiol dehydratase, forming the enzyme-bound cob(II)alamin without intermediates.     

Sites and mechanisms of aconitase inactivation by peroxynitrite: modulation by citrate and glutathione

Aconitases are iron-sulfur cluster-containing proteins present both in mitochondria and cytosol of cells; the cubane iron-sulfur (Fe-S) cluster in the active site is essential for catalytic activity, but it also renders aconitase highly vulnerable to reactive oxygen and nitrogen species. This study examined the sites and mechanisms of aconitase inactivation by peroxynitrite (ONOO-), a strong oxidant and nitrating agent readily formed from superoxide anion and nitric oxide generated by mitochondria. ONOO- inactivated aconitase in a dose-dependent manner (half-maximal inhibition was observed with approximately 3 microM ONOO-). Low levels of ONOO- caused the conversion of the Fe-S cluster from the [4Fe-4S]2+ form to the inactive [3Fe-4S]1+ form with the loss of labile iron, as confirmed by low-temperature EPR analysis. In the presence of the substrate, citrate, 66-fold higher concentrations of ONOO- were required for half-maximal inhibition. The protective effects of citrate corresponded to its binding to the active site. The inactivation of aconitase in the presence of citrate was due to ONOO--mediated cysteine thiol loss and tyrosine nitration in the enzyme as shown by Western blot analyses. LC/MS/MS analyses revealed that ONOO- treatment to aconitase resulted in nitration of tyrosines 151 and 472 and oxidation to sulfonic acid of cysteines 126 and 385. The latter is one of the three cysteine residues in aconitase that binds to the Fe-S cluster. All other modified tyrosine and cysteine residues were adjacent to the binding site, thus suggesting that these modifications caused conformational changes leading to active-site disruption. Aconitase cysteine thiol modifications other than oxidation to sulfonic acid, such as S-glutathionylation, also decreased aconitase activity, thus indicating that glutathionylation may be an important means of modulating aconitase activity under oxidative and nitrative stress. Taken together, these results demonstrate that the Fe-S cluster in the active site, cysteine 385 bound to the Fe-S cluster, and tyrosine and cysteine residues in the vicinity of the active site are important targets of oxidative and/or nitrative attack, which is selectively controlled by the mitochondrial matrix citrate levels. The mechanisms inherent in aconitase inactivation by ONOO- are discussed in terms of the mitochondrial matrix metabolic and thiol redox state.     

Phylogenetic analysis, homology modelling, molecular dynamics and docking studies of caffeoyl–CoA-O- methyl transferase (CCoAOMT 1 and 2) isoforms isolated from subabul (Leucaena leucocephala)

Caffeoyl coenzyme A O-methyltransferase (CCoAOMT) is an important enzyme that participates in lignin biosynthesis especially in the formation of cell wall ferulic esters of plants. It plays a pivotal role in the methylation of the 3-hydroxyl group of caffeoyl CoA. Two cDNA clones that code CCoAOMT were isolated earlier from subabul and in the present study; 3D models of CCoAOMT1 and CCoAOMT2 enzymes were built using the MODELLER7v7 software to find out the substrate binding sites. These two proteins differed only in two amino acids and may have little or no functional redundancy. Refined models of the proteins were obtained after energy minimization and molecular dynamics in a solvated water layer. The models were further assessed by PROCHECK, WHATCHECK, Verify_3D and ERRAT programs and the results indicated that these models are reliable for further active site and docking analysis. The refined models showed that the two proteins have 9 and 10 α-helices, 6 and 7 β-sheets respectively. The models were used for docking the substrates CoA, SAM, SAH, caffeoyl CoA, feruloyl CoA, 5-hydroxy feruloyl CoA and sinapyl CoA which showed that CoA and caffeoyl CoA are binding with high affinity with the enzymes in the presence and absence of SAM. It appears therefore that caffeoyl CoA is the substrate for both the isoenzymes. The results also indicated that CoA and caffeoyl CoA are binding with higher affinity to CCoAOMT2 than CCoAOMT1. Therefore, CCoAOMT2 conformation is thought to be the active form that exists in subabul. Docking studies indicated that conserved active site residues Met58, Thr60, Val63, Glu82, Gly84, Ser90, Asp160, Asp162, Thr169, Asn191 and Arg203 in CCoAOMT1 and CCoAOMT2 enzymes create the positive charge to balance the negatively charged caffeoyl CoA and play an important role in maintaining a functional conformation and are directly involved in donor-substrate binding.     

Comparison of Kinetic Properties Between Plant and Fungal Amine Oxidases

Abstract

Kinetic properties of novel amine oxidases isolated from a mold Aspergillus niger AKU 3302 were compared to those of typical plant amine oxidase from pea seedling (EC 1.4.3.6). Pea amine oxidase showed highest affinity with diamines, such as putrescine and cadaverine, while fungal enzymes oxidized preferably n-hexylamine and tyramine. All enzymes were inhibited by carbonyl reagents, copper chelating agents, some substrate analogs and alkaloids, but there were quite significant differences in the sensitivity and inhibition modes. Aminoguanidine, which strongly inhibited pea amine oxidases showed only little effect on fungal enzymes. Substrate analogs such as 1,5-diamino-3-pentanone and l-amino-3-phenyl-3-propanone, which were potent competitive inhibitors of pea amine oxidases, inhibited fungal enzymes much more weakly and non competitively. Also various alkaloids behaving as competitive inhibitors of pea amine oxidases inhibited the fungal enzymes non competitively. Very surprising was the potent inhibition of fungal enzymes by artificial substrates of pea amine oxidases, E- and Z-1,4-diamino-2-butene. The relationships between the different inhibition modes and possible binding at the active site are discussed.     

Phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate as substrates or inhibitors of procaryotic and eucaryotic enzymes degrading dinucleoside tetraphosphates

The substrate specificity of procaryotic and eucaryotic AppppA-degrading enzymes was investigated with phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate (AppppA). App(CH2)ppA (I), App(CHBr)ppA (II), and Appp(CH2)pA (III), but not Ap(CH2)pp(CH2)pA (IV), are substrates for lupin AppppA hydrolase (EC 3.6.1.17) and phosphodiesterase I (EC 3.1.4.1). None of the four analogues is hydrolyzed by bacterial AppppA hydrolase (EC 3.6.1.41), and only analogue III is degraded by yeast AppppA phosphorylase (EC 2.7.7.53). The analogues are competitive inhibitors of all four enzymes. The affinity of analogue IV is 3-40-fold lower than that of analogues I-III for all four enzymes. Introduction of one methylene (as in I and III) [or bromomethylene (as in II)] group into AppppA results in a 3-15-fold increase of its affinity for lupin and Escherichia coli AppppA hydrolases. The same modifications only negligibly (10-30%) affect its affinity for yeast AppppA phosphorylase and decrease its affinity for lupin phosphodiesterase I about 2.5-fold. The data provide further evidence for the heterogeneity among catalytic sites of all four AppppA-degrading enzymes.     

Kinetic and inhibition studies of phospholipase A2 with short-chain substrates and inhibitors

The action of the phospholipases A2 (PLA2s) from Naja naja naja, Naja naja atra, and Crotalus atrox venoms as well as the enzyme from porcine pancreas on a number of short-chain, water-soluble substrates was studied. The inhibition of these enzymes by short-chain phosphonate- and thiophosphonate-containing phospholipid analogues was also examined. The kinetic patterns observed for the action of the venom PLA2s on substrates containing phosphocholine head groups all deviated from a classical Michaelis-Menten-type behavior. With a substrate containing an anionic head group, the kinetic pattern observed was more normal. In contrast, Michaelis-Menten-type behavior was observed for the action of the porcine pancreatic PLA2 acting on all of the substrates studied. A short-chain phospholipid analogue in which the enzyme-susceptible ester was replaced with a phosphonate group was found to be a tight-binding inhibitor of the venom PLA2s with IC50 values that were some 10(4)-10(5)-fold lower than the concentration of substrate used in the assay. The degree of inhibition was found to depend dramatically on the stereochemical arrangement of substituents in the inhibitor which strongly suggests that the inhibitors are binding directly to the active site of the PLA2s. By comparison, the phosphonate analogue functioned as a poor inhibitor of the porcine pancreatic PLA2. Direct inhibitor binding studies indicated that the short-chain phosphonate inhibitor bound weakly to the venom enzymes in the absence of the short-chain substrates. Several other unusual features of the inhibition were also observed. The data are interpreted in terms of a model in which the enzyme and substrate form a lipid-protein aggregate at substrate concentrations below the critical micelle concentration (cmc). Possible reasons for the selective binding of the inhibitor to the enzyme-substrate microaggregate are discussed.     

The importance of the amide bond nearest the thiol group in enzymatic reactions of coenzyme A

Analogues of coenzyme A (CoA) and of CoA thioesters have been prepared in which the amide bond nearest the thiol group has been modified. An analogue of acetyl-CoA in which this amide bond is replaced with an ester linkage was a good substrate for the enzymes carnitine acetyltransferase, chloramphenicol acetyltransferase, and citrate synthase, with K(m) values 2- to 8-fold higher than those of acetyl-CoA and V(max) values from 14 to >80% those of the natural substrate. An analogue in which an extra methylene group was inserted between the amide bond and the thiol group showed less than 4-fold diminished binding to the three enzymes but exhibited less than 1% activity relative to acetyl-CoA with carnitine acetyltransferase and no measurable activity with the other two enzymes. Analogues of several CoA thioesters in which the amide bond was replaced with a hemithioacetal linkage exhibited no measurable activity with the appropriate enzymes. The results indicate that some aspects of the amide bond and proper distance between this amide and the thiol/thioester moiety are critical for activity of CoA ester-utilizing enzymes.     

Enzymatically stable 5' mRNA cap analogs: synthesis and binding studies with human DcpS decapping enzyme

Four novel 5' mRNA cap analogs have been synthesized with one of the pyrophosphate bridge oxygen atoms of the triphosphate linkage replaced with a methylene group. The analogs were prepared via reaction of nucleoside phosphor/phosphon-1-imidazolidates with nucleoside phosphate/phosphonate in the presence of ZnCl2. Three of the new cap analogs are completely resistant to degradation by human DcpS, the enzyme responsible for hydrolysis of free cap resulting from 3' to 5' cellular mRNA decay. One of the new analogs has very high affinity for binding to human DcpS. Two of these analogs are Anti Reverse Cap Analogs which ensures that they are incorporated into mRNA chains exclusively in the correct orientation. These new cap analogs should be useful in a variety of biochemical studies, in the analysis of the cellular function of decapping enzymes, and as a basis for further development of modified cap analogs as potential anti-cancer and anti-parasite drugs.     

Purification and characterization of rat heart and brain catechol methyltransferase.

In an effort to detect the similarities and differences in the properties of rat heart, brain and liver catechol methyltransferase (S-adenosyl-L-methionine:catechol O-methyltransferase, EC 2.1.1.6), we have determined the cellular distribution of this enzyme activity and extensively purified the soluble and microsomal enzymes present in these tissues. Purification of soluble heart (688-fold) and brain enzymes (240-fold) were achieved using an affinity chromatographic system. The properties of these enzymes were compared with respect to their molecular weights, substrate specificities, inhibitor specificities and immunological properties. The characteristics of the enzyme active sites were investigated using various methyl acceptor substrates and various analogs of S-adenosylmethionine as methyl donors. A series of analogs of S-adenosylhomocysteine was also evaluated as inhibitors of these enzymes. The immunological properties of the purified soluble and microsomal enzymes from heart and brain were investigated using an antibody isolated from rabbits which had been immunized with the soluble rat liver enzyme. In general the properties of catechol methyltransferases isolated from heart and brain were similar to the properties of the enzyme isolated from liver. Some minor differences in substrate and inhibitor specificities were observed which might suggest slight differences in the active sites of these enzymes.     

The use of fluoro- and deoxy-substrate analogs to examine binding specificity and catalysis in the enzymes of the sorbitol pathway

The carbohydrate specificity of the two enzymes that catalyze the metabolic interconversions in the sorbitol pathway, aldose reductase and sorbitol dehydrogenase, has been examined through the use of fluoro- and deoxy-substrate analogs. Hydrogen bonding has been shown to be the primary mode of interaction by which these enzymes specifically recognize and bind their respective polyol substrates. Aldose reductase has broad substrate specificity, and all of the fluoro- and deoxysugars that were examined are substrates for this enzyme. Unexpectedly, both 3-fluoro- and 4-fluoro-D-glucose were found to be better substrates, with significantly lower K(m) and higher Kcat/K(m) values than those of D-glucose. A more discriminating pattern of substrate specificity is observed for sorbitol dehydrogenase. Neither the 2-fluoro nor the 2-deoxy analogs of D-glucitol were found to be substrates or inhibitors, suggesting that the 2-hydroxyl group of sorbitol is a hydrogen bond donor. The 4-fluoro and 4-deoxy analogs are poorer substrates than sorbitol, also implying a binding role for this hydroxyl group. In contrast, both 6-fluoro- and 6-deoxy-D-glucitol are very good substrates for sorbitol dehydrogenase, indicating that the primary hydroxyl group at this position is not involved in substrate recognition by this enzyme.     

PHOSPHONATE ANALOGS OF CARBOCYCLIC PHOSPHORIBOSYLAMINE AND CARBOCYCLIC GLYCINAMIDE RIBONUCLEOTIDE

Abstract

Analogs of intermediates in the de novo purine nucleotide biosynthetic pathway were synthesized to study the binding requirements of the corresponding enzymes. Because of the instability of the natural stubstrates, such as phosphoribosylamine, the use of the structurally stable phosphonate moiety and the carbocyclic ribose yields ideal analogs for these studies. In addition, these analogs can act as potential inhibitors of the de novo pathway leading to the design of anticancer agents. Enzyme studies with GAR synthetase and GAR transformylase reveal that the title compounds can act as substrates or inhibitors of the de novo enzymes.     

Contribution of a conserved arginine near the active site of Escherichia coli D-serine dehydratase to cofactor affinity and catalytic activity

We have employed site-directed mutagenesis to investigate the contribution of a conserved arginyl residue to the catalytic activity and cofactor affinity of D-serine dehydratase, a model pyridoxal 5'-phosphate (vitamin B6) enzyme. Replacement of R-120 in the active site peptide of D-serine dehydratase by L decreased the affinity of the enzyme for pyridoxal 5'-phosphate by 20-fold and reduced turnover by 5-8-fold. kappa cat displayed modified substrate alpha-deuterium isotope effects and altered dependence on both temperature and pH. Analysis of the pH rate profiles of DSD and the R-120----L variant indicated that R-120 interacts electrostatically with catalytically essential ionizable groups at the active site of wild type D-serine dehydratase. The decrease in cofactor affinity observed for DSD(R120L) was not accompanied by significant perturbations in the UV, CD, or 31P NMR spectrum of the holoenzyme, suggesting that the contribution of R-120 to pyridoxal phosphate affinity may be indirect or else involve an interaction with a cofactor functional group other than the 5'-phosphoryl moiety. The properties of two other site-directed variants of D-serine dehydratase indicated that the pyridoxal 5'-phosphate:K-118 Schiff base was indifferent to a small change in the shape of the side chain at position 117 (I-117----L), whereas replacement of K-118 by H resulted in undetectable levels of enzyme. A poor ability to bind cofactor may have rendered DSD(K118H) susceptible to intracellular proteolysis.     

Inhibition of ribose-5-phosphate isomerase by 4-phosphoerythronate.

Hoping to exploit the special affinity of enzymes for unstable intermediates in substrate transformation, we have determined the effectiveness of possible analogs of ene-diolate intermediates as inhibitors of spinach ribose-5-phosphate isomerase. 4-Phosphoerythronic acid was found to be a very strong competitive inhibitor, with a Ki value almost 3 orders of magnitude lower than the Km value of ribose 5-phosphate, and very much lower than the Ki value of any other inhibitor that was examined.