Structure and mutagenic conversion of E1 dehydrase: at the crossroads of dehydration, amino transfer, and epimerization

Pyridoxal 5'-phosphate (PLP) and pyridoxamine 5'-phosphate (PMP) are highly versatile coenzymes whose importance is well recognized. The capability of PLP/PMP-dependent enzymes to catalyze a diverse array of chemical reactions is attributed to fine-tuning of the cofactor-substrate interactions in the active site. CDP-6-deoxy-L-threo-D-glycero-4-hexulose 3-dehydrase (E1), along with its reductase (E3), catalyzes the C-3 deoxygenation of CDP-4-keto-6-deoxy-D-glucose to form the dehydrated product, CDP-4-keto-3,6-dideoxy- d-glucose, in the ascarylose biosynthetic pathway. This product is the progenitor to most 3,6-dideoxyhexoses, which are the major antigenic determinants of many Gram-negative pathogens. The dimeric [2Fe-2S] protein, E 1, cloned from Yersinia pseudotuberculosis, is the only known enzyme whose catalysis involves the direct participation of PMP in one-electron redox chemistry. E1 also contains an unusual [2Fe-2S] cluster with a previously unknown binding motif (C-X 57-C-X 1-C-X 7-C). Herein we report the first X-ray crystal structure of E1, which exhibits an aspartate aminotransferase (AAT) fold. A comparison of the E1 active site architecture with homologous structures uncovers residues critical for the dehydration versus transamination activity. Site-directed mutagenesis of four E1 residues, D194H, Y217H, H220K, and F345H, converted E 1 from a PMP-dependent dehydrase to a PLP/glutamate-dependent aminotransferase. The E1 quadruple mutant, having been conferred this altered enzyme activity, can transaminate the natural substrate to CDP-4,6-dideoxy-4-amino-D-galactose without E3. Taken together, these results provide the molecular basis of the functional switch of E1 toward dehydration, epimerization, and transamination. The insights gained from these studies can be used for the development of inhibitors of disease-relevant PLP/PMP-dependent enzymes.     

Mechanistic studies of the biosynthesis of 3,6-dideoxyhexoses in Yersinia pseudotuberculosis. Purification and stereochemical analysis of CDP-D-glucose oxidoreductase.

An NAD(+)-dependent CDP-D-glucose oxidoreductase which catalyzes the first step of the biosynthesis of CDP-ascarylose (CDP-3,6-dideoxy-L-arabino-hexose), converting CDP-D-glucose to CDP-4-keto-6-deoxy-D-glucose, was isolated from Yersinia pseudotuberculosis. A protocol consisting of DEAE-cellulose, Matrex Blue-A, hydroxylapatite, DEAE-Sephadex, Sephadex G-100, and NAD(+)-agarose column chromatography was used to purify this enzyme 6000-fold to homogeneity. This enzyme consists of two identical subunits, each with a molecular weight of 42,500. Using CDP-D-glucose as the substrate, the Km and Vmax of this catalysis were determined to be 222 microM and 8.3 mumols mg-1 min-1, respectively. Unlike most other oxidoreductases of its class which have a tightly bound NAD+, this highly purified CDP-D-glucose oxidoreductase showed an absolute requirement of NAD+ for its activity. Using chemically synthesized (6S)- and (6R)-CDP-D-[4-2H,6-3H]glucose as substrates, a stereochemical analysis showed this enzymatic reaction involves an intramolecular hydrogen migration from C-4 to C-6, and the displacement of C-6 hydroxyl group by the C-4 hydrogen occurs with inversion. Thus, despite the low cofactor affinity, this enzyme undergoes a mechanism consistent with that followed by other members of its type. Such a mechanistic and stereochemical convergency found for all sugar oxidoreductases so far characterized suggests the presence of a common progenitor of this class of enzyme.     

Mechanistic studies of the biosynthesis of 3,6-dideoxyhexoses in Yersinia pseudotuberculosis: purification and characterization of CDP-4-keto-6-deoxy-D-glucose-3-dehydrase.

CDP-4-keto-6-deoxy-D-glucose-3-dehydrase (E1) is a PMP-dependent enzyme which plays an essential role in C-O bond cleavage leading to the formation of 3,6-dideoxyhexoses. Although E1 catalysis has long been recognized as a unique biological deoxygenation reaction, the catalytic mechanism of this unusual enzyme has never been fully elucidated. The lack of methods that would allow this enzyme's activity to be monitored directly has been an impediment to E1 purification and has consequently hampered the mechanistic studies. In order to circumvent this problem, we have developed a few convenient and sensitive methods to facilitate the E1 assay. The first method relies on the fact that E1-catalyzed dehydration is initiated by a proton abstraction from C-4' of the PMP-substrate adduct. By using a tritium-labeled cofactor in the incubation that was later quenched with charcoal, the amount of E1 present could be determined from the amount of released tritium in the supernatant. The second method was designed on the basis of the expectation that E1 will bind and rupture the C-F bond of a substrate analogue, CDP-4-keto-3,6-dideoxy-3-fluoro-D-glucose, which was derived from CDP-3-deoxy-3-fluoro-D-glucose. Since the bond length and electronegativity of the C-F group are similar to those of a C-OH group, we anticipated that the proposed compound would be processed by E1, an assumption which was later substantiated. Another assay useful for measuring E1 activity couples the E1 transformation with the subsequent reduction step catalyzed by CDP-6-deoxy-delta 3,4-D-glucoseen reductase (E3) to a thiobarbituric acid (TBA) reaction. Since the condensation product of TBA and malonaldehyde derived from oxidative degradation of the E1/E3 product gave a pink chromophore at 532 nm with a known absorption coefficient, the yield of deoxysugar formation could be directly deduced on the basis of the observed absorbance. The most conclusive evidence confirming the role of E1 was attained by a GC/MS assay which permits an unambiguous identification of the deoxysugar product generated from the E1 and E3 reactions. With these convenient and sensitive assays in hand, we have established a sequence of four columns that was effective in consistently producing pure E1 from Yersinia pseudotuberculosis. The overall purification may be as high as 26,000-fold. This purified enzyme consists of a single polypeptide chain in its native form, and the estimated molecular weight is 49,000.(ABSTRACT TRUNCATED AT 400 WORDS)     

Stereospecific labilization of the C-4' pro-S hydrogen of pyridoxamine 5'-phosphate in aspartate aminotransferase

In the course of a half-reaction of enzymic transamination, the aldimine adduct formed between the coenzyme pyridoxal 5'-phosphate and the amino acid substrate tautomerizes to the ketimine intermediate which is then hydrolyzed to the oxo acid product and the pyridoxamine 5'-phosphate form of the enzyme. In the reverse half-reaction the tautomerization is initiated by the removal of a proton from the pro-S position at C-4' of the PMP moiety of the ketimine intermediate. The present study investigates the question whether the pro-S hydrogen at C-4' of PMP is labilized by its active site environment independently of the formation of the ketimine intermediate, i.e. in the absence of substrate. Reconstitution of apoaspartate aminotransferase (mitochondrial isoenzyme from chicken) with [4'-3H] PMP results indeed in a stereospecific exchange of pro-S 3H with solvent water. The exchange follows first order kinetics (t 1/2 = 23 min at pH 7.5 and 25 degrees C). Unbound PMP showed no measurable exchange. Rigorous control experiments excluded the possibility that the observed exchange was due to a transamination reaction of the enzyme with contaminating oxo acid substrates. The newly observed stereospecific exchange reaction allows to investigate the acid/base properties of C-4' and the modulating effects of its active site environment independently of the preceding and following steps of enzymic transamination.     

CDP-6-deoxy-delta 3,4-glucoseen reductase from Yersinia pseudotuberculosis: enzyme purification and characterization of the cloned gene.

The 3,6-dideoxyhexoses, usually confined to the cell wall lipopolysaccharide of gram-negative bacteria, are essential to serological specificity and are formed via a complex biosynthetic pathway beginning with CDP-D-hexoses. In particular, the biosynthesis of CDP-ascarylose, one of the naturally occurring 3,6-dideoxyhexoses, consists of five enzymatic steps, with CDP-6-deoxy-delta 3,4-glucoseen reductase (E3) participating as the key enzyme in this catalysis. This enzyme has been previously purified from Yersinia pseudotuberculosis by an unusual procedure (protocol I) including a trypsin digestion step (O. Han, V.P. Miller, and H.-W. Liu, J. Biol. Chem. 265:8033-8041, 1990). However, the cloned gene showed disparity with the expected gene characteristics, and upon expression, the resulting gene product exhibited no E3 activity. These findings strongly suggested that the protein isolated by protocol I may have been misidentified as E3. A reinvestigation of the purification protocol produced a new and improved procedure (protocol II) consisting of DEAE-Sephacel, phenyl-Sepharose, Cibacron blue A, and Sephadex G-100 chromatography, which efficiently yielded a new homogeneous enzyme composed of a single polypeptide with a molecular weight of 39,000. This highly purified protein had a specific activity nearly 8,000-fold higher than that of cell lysates, and more importantly, the corresponding gene (ascD) was found to be part of the ascarylose biosynthetic cluster. Presented are the identification and confirmation of the E3 gene through cloning and overexpression and the culminating purification and unambiguous assignment of homogeneous E3. The nucleotide and translated amino acid sequences of the genuine E3 are also presented.     

Studies of the biosynthesis of 3,6-dideoxyhexoses: molecular cloning and characterization of the asc (ascarylose) region from Yersinia pseudotuberculosis serogroup VA.

The 3,6-dideoxyhexoses are found in the lipopolysaccharides of gram-negative bacteria, where they have been shown to be the dominant antigenic determinants. Of the five 3,6-dideoxyhexoses known to occur naturally, four have been found in various strains of Salmonella enterica (abequose, tyvelose, paratose, and colitose) and all five, including ascarylose, are present among the serotypes of Yersinia pseudotuberculosis. Although there exists one report of the cloning of the rfb region harboring the abequose biosynthetic genes from Y. pseudotuberculosis serogroup HA, the detailed genetic principles underlying a 3,6-dideoxyhexose polymorphism in Y. pseudotuberculosis have not been addressed. To extend the available information on the genes responsible for 3,6-dideoxyhexose formation in Yersinia spp. and facilitate a comparison with the established rfb (O antigen) cluster of Salmonella spp., we report the production of three overlapping clones containing the entire gene cluster required for CDP-ascarylose biosynthesis. On the basis of a detailed sequence analysis, the implications regarding 3,6-dideoxyhexose polymorphism among Salmonella and Yersinia spp. are discussed. In addition, the functional cloning of this region has allowed the expression of Ep (alpha-D-glucose cytidylyltransferase), Eod (CDP-D-glucose 4,6-dehydratase), E1 (CDP-6-deoxy-L-threo-D-glycero-4- hexulose-3-dehydrase), E3 (CDP-6-deoxy-delta 3,4-glucoseen reductase), Eep (CDP-3,6-dideoxy-D-glycero-D- glycero-4-hexulose-5-epimerase), and Ered (CDP-3,6-dideoxy-L-glycero-D-glycero-4-hexulose-4-reductase), facilitating future mechanistic studies of this intriguing biosynthetic pathway.     

A retro-evolution study of CDP-6-deoxy-D-glycero-L-threo-4-hexulose-3-dehydrase (E1) from Yersinia pseudotuberculosis: implications for C-3 deoxygenation in the biosynthesis of 3,6-dideoxyhexoses

CDP-6-deoxy-l-threo-d-glycero-4-hexulose-3-dehydrase (E1), which catalyzes C-3 deoxygenation of CDP-4-keto-6-deoxyglucose in the biosynthesis of 3,6-dideoxyhexoses, shares a modest sequence identity with other B6-dependent enzymes, albeit with two important distinctions. It is a rare example of a B6-dependent enzyme that harbors a [2Fe-2S] cluster, and a highly conserved lysine that serves as an anchor for PLP in most B6-dependent enzymes is replaced by histidine at position 220 in E1. Since alteration of His220 to a lysine residue may produce a putative progenitor of E1, the H220K mutant was constructed and tested for the ability to process the predicted substrate, CDP-4-amino-4,6-dideoxyglucose, using PLP as the coenzyme. Our data showed that H220K-E1 has no dehydrase activity, but can act as a PLP-dependent transaminase. However, the reaction is not catalytic since PLP cannot be regenerated during turnover. Reported herein are the results of this investigation and the implications for the role of His220 in the catalytic mechanism of E1.     

Crystal structure at 1.8 A resolution of CDP-D-glucose 4,6-dehydratase from Yersinia pseudotuberculosis

CDP-D-glucose 4,6-dehydratase catalyzes the conversion of CDP-D-glucose to CDP-4-keto-6-deoxyglucose in an NAD(+)-dependent manner. The product of this conversion is a building block for a variety of primary antigenic determinants in bacteria, possibly implicated directly in reactive arthritis. Here, we describe the solution of the high-resolution crystal structure of CDP-D-glucose 4,6-dehydratase from Yersinia pseudotuberculosis in the resting state. This structure represents the first CDP nucleotide utilizing dehydratase of the short-chain dehydrogenase/reductase (SDR) family to be determined, as well as the first tetrameric structure of the subfamily of SDR enzymes in which NAD(+) undergoes a full reaction cycle. On the basis of a comparison of this structure with structures of homologous enzymes, a chemical mechanism is proposed in which Tyr157 acts as the catalytic base, initiating hydride transfer by abstraction of the proton from the sugar 4'-hydroxyl. Concomitant with the removal of the proton from the 4'-hydroxyl oxygen, the sugar 4'-hydride is transferred to the B face of the NAD(+) cofactor, forming the reduced cofactor and a CDP-4-keto-d-glucose intermediate. A conserved Lys161 most likely acts to position the NAD(+) cofactor so that hydride transfer is favorable and/or to reduce the pK(a) of Tyr157. Following substrate oxidation, we propose that Lys134, acting as a base, would abstract the 5'-hydrogen of CDP-4-keto-D-glucose, priming the intermediate for the spontaneous loss of water. Finally, the resulting Delta(5,6)-glucoseen intermediate would be reduced suprafacially by the cofactor, and reprotonation at C-5' is likely mediated by Lys134.     

Dismutase activity of ADP-L-glycero-D-manno-heptose 6-epimerase: evidence for a direct oxidation/reduction mechanism

The first positive evidence for the utilization of a direct C-6' ' oxidation/reduction mechanism by ADP-l-glycero-d-manno-heptose 6-epimerase is reported here. The epimerase (HldD or AGME, formerly RfaD) operates in the biosynthetic pathway of l-glycero-d-manno-heptose, which is a conserved sugar in the core region of lipopolysaccharide (LPS) of Gram-negative bacteria. The stereochemical inversion catalyzed by the epimerase is interesting as it occurs at an "unactivated" stereocenter that lacks an acidic C-H bond, and therefore, a direct deprotonation/reprotonation mechanism cannot be employed. Instead, the epimerase employs a transient oxidation strategy involving a tightly bound NADP(+) cofactor. A recent study ruled out mechanisms involving transient oxidation at C-4' ' and C-7' ' and supported a mechanism that involves an initial oxidation directly at the C-6' ' position to generate a 6' '-keto intermediate (Read, J. A., Ahmed, R. A., Morrison, J. P., Coleman, W. G., Jr., Tanner, M. E. (2004) J. Am. Chem. Soc. 126, 8878-8879). A subsequent nonstereospecific reduction of the ketone intermediate can generate either epimer of the ADP-heptose. In this work, an intermediate analogue containing an aldehyde functionality at C-6' ', ADP-beta-d-manno-hexodialdose, is prepared in order to probe the ability of the enzyme to catalyze redox chemistry at this position. It is found that incubation of the aldehyde with a catalytic amount of the epimerase leads to a dismutation process in which one-half of the material is oxidized to ADP-beta-d-mannuronic acid and the other half is reduced to ADP-beta-d-mannose. Transient reduction of the enzyme-bound NADP(+) was monitored by UV spectroscopy and implicates the cofactor's involvement during catalysis.     

Biosynthesis of colitose: expression, purification, and mechanistic characterization of GDP-4-keto-6-deoxy-D-mannose-3-dehydrase (ColD) and GDP-L-colitose synthase (ColC)

L-Colitose is a 3,6-dideoxyhexose found in the O-antigen of Gram-negative lipopolysaccharides. To study the biosynthesis of this unusual sugar, we have cloned and sequenced the L-colitose biosynthetic gene cluster from Yersinia pseudotuberculosis VI. The colD and colC genes in this cluster have been overexpressed and each gene product has been purified and characterized. Our results showed that ColD functions as GDP-4-keto-6-deoxy-D-mannose-3-dehydrase responsible for C-3 deoxygenation of GDP-4-keto-6-deoxy-D-mannose. This enzyme is coenzyme B(6)-dependent and its catalysis is initiated by a transamination step in which pyridoxal 5'-phosphate (PLP) is converted to pyridoxamine 5'-phosphate (PMP) in the presene of L-glutamate. This coenzyme forms a Schiff base with the keto sugar substrate and the resulting adduct undergoes a PMP-mediated beta-dehydration reaction to give a sugar enamine intermediate, which after tautomerization and hydrolysis to release ammonia yields GDP-4-keto-3,6-dideoxy-D-mannose as the product. The combined transamination-deoxygenation activity places ColD in a class by itself. Our studies also established ColC as GDP-L-colitose synthase, which is a bifunctional enzyme catalyzing the C-5 epimerization of GDP-4-keto-3,6-dideoxy-D-mannose and the subsequent C-4 keto reduction of the resulting L-epimer to give GDP-L-colitose. Reported herein are the detailed accounts of the overexpression, purification, and characterization of ColD and ColC. Our studies show that their modes of action in the biosynthesis of GDP-L-colitose represent a new deoxygenation paradigm in deoxysugar biosynthesis.     

Interaction of the chiral pyruvate analog, 2-keto-3-bromobutyrate, with pyruvate lyases. 2-Keto-3-deoxygluconate-6-phosphate aldolase of Pseudomonas putida.

The enzyme 2-keto-3-deoxygluconate-6-P aldolase of Pseudomonas putida is inactivated by one of the chiral forms of 2-keto-(3RS)-3-bromobutyric acid (bromoketobutyrate). The inactivation shows saturation kinetics and competition with pyruvate. The minimal inactivation half-time is 4 min and that concentration of bromoketobutyrate half-saturating the enzyme is 2 mM. (3RS)-[3-3H]bromoketobutyrate is catalytically detritiated during enzyme inactivation. A kinetic analysis of rates gave data consistent with both catalysis and inactivation occurring at a single protein site, the catalytic site. The enzyme only detritiates one of the two optical isomers of bromoketobutyrate, and that form which is detritiated also alkylates the catalytic site. The inactive isomer of reagent degrades, with inversion, to L-lactate so that the chiral form specific for the enzyme is 2-keto-(3S)-3-bromobutyrate. Thus, as is the case with bromopyruvate, the enzyme catalyzes protonation of the re face at C-3 of the enzyme-reagent eneamine. As a result, bromoketobutyrate could serve as a chiral probe for stereochemical constraints of selected pyruvate-specific lyase active sites.     

The molecular architecture of QdtA,a sugar 3,4‐ketoisomerase from Thermoanaerobacterium thermosaccharolyticum

Unusual di- and trideoxysugars are often found on the O-antigens of Gram-negative bacteria, on the S-layers of Gram-positive bacteria, and on various natural products. One such sugar is 3-acetamido-3,6-dideoxy-d-glucose. A key step in its biosynthesis, catalyzed by a 3,4-ketoisomerase, is the conversion of thymidine diphosphate (dTDP)−4-keto-6-deoxyglucose to dTDP-3-keto-6-deoxyglucose. Here we report an X-ray analysis of a 3,4-ketoisomerase from Thermoanaerobacterium thermosaccharolyticum. For this investigation, the wild-type enzyme, referred to as QdtA, was crystallized in the presence of dTDP and its structure solved to 2.0-Å resolution. The dimeric enzyme adopts a three-dimensional architecture that is characteristic for proteins belonging to the cupin superfamily. In order to trap the dTDP-4-keto-6-deoxyglucose substrate into the active site, a mutant protein, H51N, was subsequently constructed, and the structure of this protein in complex with the dTDP–sugar ligand was solved to 1.9-Å resolution. Taken together, the structures suggest that His 51 serves as a catalytic base, that Tyr 37 likely functions as a catalytic acid, and that His 53 provides a proton shuttle between the C-3′ hydroxyl and the C-4′ keto group of the hexose. This study reports the first three-dimensional structure of a 3,4-ketoisomerase in complex with its dTDP–sugar substrate and thus sheds new molecular insight into this fascinating class of enzymes.     

Stereochemistry and kinetic isotope effects in the bovine plasma amine oxidase catalyzed oxidation of dopamine.

The stereochemistry of the bovine plasma amine oxidase catalyzed oxidation of 2-(3,4-dihydroxyphenyl)-ethylamine (domapine) has been investigated by comparing 3H/14C ratios of 3,4-dibenzyloxyphenethyl alcohols, derived from 3,4-dihydroxyphenylacetaldehydes, to starting dopamines chirally labeled at C-1 and C-2. The oxidation of [2RS-3H]-, [2R-3H]-, and [2S-3H]dopamine leads to products which have retained 53, 59, and 47% of their tritium. Similarly, oxidation of [1RS-3H]-, [1R-3H]-, and [1S-3H]dopamine leads to an 80, 80, and 92% retention of tritium. The configurational purity of tritium at C-2 of dopamine and C-1 of the dopamine precursor 3-methoxy-4-hydroxyphenethylamine has been confirmed employing dopamine-beta-hydroxylase (specific for the pro-R hydrogen at C-2) and pea seedling amine oxidase (specific for the pro-S hydrogen at C-1). In addition, chromatographically resolved isozymes of bovine plasma amine oxidase have been demonstrated to lead to the same stereochemical result as pooled enzyme fractions. We have been able to rule out carbon interchange and tritium transfer in the ethylamine side chain of dopamine as the source of the apparent nonstereospecificity. Estimated primary tritium isotope effects are 1 for [2-3H]dopamines and 5--6 and 26--34 for [1R-3H]- and [1S-3H]dopamine, respectively. We propose the presence of alternate dopamine binding modes, characterized by absolute but opposing stereochemistries and differential primary tritium isotope effects at C-1.     

The stereospecific labilization of the C-4' pro-S hydrogen of pyridoxamine 5'-phosphate is abolished in (Lys258----Ala) aspartate aminotransferase

Reconstitution of wild-type apoaspartate aminotransferase from Escherichia coli with [4'-3H]pyridoxamine 5'-phosphate results in stereospecific release of the pro-S C-4' 3H to the solvent. The reaction follows first-order kinetics (t1/2 = 15 min at pH 7.5 and 25 degrees C), its rate constant being similar to that found previously with mitochondrial aspartate aminotransferase from chicken (Tobler, H.P., Christen, P., and Gehring, H. (1986) J. Biol. Chem. 261, 7105-7108). Substituting the active site residue Lys258 by alanine via site-directed mutagenesis yields a catalytically inactive enzyme (Malcolm, B. A., and Kirsch, J. F. (1985) Biochem. Biophys. Res. Commun. 132, 915-921). This mutant enzyme fails to release any measurable 3H from bound [4'-3H]pyridoxamine 5'-phosphate. The data are consistent with earlier proposals that Lys258 is indispensable for the ketimine/aldimine tautomerization, and corroborate the previous conclusion that 3H exchange from enzyme-bound pyridoxamine 5'-phosphate mechanistically corresponds to the deprotonation at C-4' of the ketimine intermediate during the transamination reaction.     

Stereochemical trends in copper amine oxidase reactions

Copper amine oxidases (EC 1.4.3.6) exhibit atypical stereochemical patterns in the reactions they catalyze. Dopamine and tyramine are oxidized with abstraction of the pro-R hydrogen by the porcine plasma amine oxidase, the pro-S hydrogen by pea seedling amine oxidase and a net nonstereospecific proton abstraction by the bovine plasma enzyme. This provides the first example in which a reaction catalyzed by enzymes in the same formal class occurs by all three possible stereochemical routes. To assess the underlying mechanistic significance of this heterogeneity, we have established the stereochemical course of the oxidation of tyramine by five additional copper amine oxidases using 1H NMR spectroscopy. Reactions catalyzed by rabbit and sheep serum amine oxidases are nonstereospecific. These enzymes exhibit rare mirror image binding with differential flux through two opposite and stereospecific reaction pathways. Differential primary kinetic isotope effects are observed for each mode, 8 and 4.6 for pro-S abstraction and 2.6 and 2.7 for pro-R abstraction by the sheep and rabbit amine oxidases, respectively. Tyramine oxidations catalyzed by the soybean and chick pea amine oxidases and porcine kidney diamine oxidase, however, are all stereospecific, occurring with loss of the pro-S hydrogen at C-1. Solvent exchange profiles are consistent within each stereochemical class of enzyme; the pro-R and nonstereospecific enzymes exchange solvent into C-2 of product aldehydes, the pro-S enzymes do not.     

PLP and PMP radicals: a new paradigm in coenzyme B6 chemistry

Enzymes frequently rely on a broad repertoire of cofactors to perform chemically challenging transformations. The B6 coenzymes, composed of pyridoxal 5'-phosphate (PLP) and pyridoxamine 5'-phosphate (PMP), are used by many transaminases, racemases, decarboxylases, and enzymes catalyzing alpha,beta and beta,gamma-eliminations. Despite the variety of reactions catalyzed by B6-dependent enzymes, the mechanism of almost all such enzymes is based on their ability to stabilize high-energy anionic intermediates in their reaction pathways by the pyridinium moiety of PLP/PMP. However, there are two notable exceptions to this model, which are discussed in this article. The first enzyme, lysine 2,3-aminomutase, is a PLP-dependent enzyme that catalyzes the interconversion of L-lysine to L-beta-lysine using a one-electron-based mechanism utilizing a [4Fe-4S] cluster and S-adenosylmethionine. The second enzyme, CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase, is a PMP-dependent enzyme involved in the formation of 3,6-dideoxysugars in bacteria. This enzyme also contains an iron-sulfur cluster and uses a one-electron based mechanism to catalyze removal of a C-3 hydroxy group from a 4-hexulose. In both cases, the participation of free radicals in the reaction pathway has been established, placing these two B6-dependent enzymes in an exclusive class by themselves.     

The structure of GDP-4-keto-6-deoxy-D-mannose-3-dehydratase: a unique coenzyme B6-dependent enzyme

L-colitose is a 3,6-dideoxysugar found in the O-antigens of some Gram-negative bacteria such as Escherichia coli and in marine bacteria such as Pseudoalteromonas tetraodonis. The focus of this investigation, GDP-4-keto-6-deoxy-D-mannose-3-dehydratase, catalyzes the third step in colitose production, which is the removal of the hydroxyl group at C3' of GDP-4-keto-6-deoxymannose. It is an especially intriguing PLP-dependent enzyme in that it acts as both a transaminase and a dehydratase. Here we present the first X-ray structure of this enzyme isolated from E. coli Strain 5a, type O55:H7. The two subunits of the protein form a tight dimer with a buried surface area of approximately 5000 A2. This is a characteristic feature of the aspartate aminotransferase superfamily. Although the PLP-binding pocket is formed primarily by one subunit, there is a loop, delineated by Phe 240 to Glu 253 in the second subunit, that completes the active site architecture. The hydrated form of PLP was observed in one of the enzyme/cofactor complexes described here. Amino acid residues involved in anchoring the cofactor to the protein include Gly 56, Ser 57, Asp 159, Glu 162, and Ser 183 from one subunit and Asn 248 from the second monomer. In the second enzyme/cofactor complex reported, a glutamate ketimine intermediate was found trapped in the active site. Taken together, these two structures, along with previously reported biochemical data, support the role of His 188 as the active site base required for catalysis.     

Tyrosine 265 of alanine racemase serves as a base abstracting alpha-hydrogen from L-alanine: the counterpart residue to lysine 39 specific to D-alanine.

Alanine racemase of Bacillus stearothermophilus has been proposed to catalyze alanine racemization by means of two catalytic bases: lysine 39 (K39) abstracting specifically the alpha-hydrogen of D-alanine and tyrosine 265 (Y265) playing the corresponding role for the antipode L-alanine. The role of K39 as indicated has already been verified [Watanabe, A., Kurokawa, Y., Yoshimura, T., Kurihara, T., Soda, K., and Esaki, N. (1999) J. Biol. Chem. 274, 4189-4194]. We here present evidence for the functioning of Y265 as the base catalyst specific to L-alanine. The Y265-->Ala mutant enzyme (Y265A), like Y265S and Y265F, was a poor catalyst for alanine racemization. However, Y265A and Y265S catalyzed transamination with D-alanine much more rapidly than the wild-type enzyme, and the bound coenzyme, pyridoxal 5'-phosphate (PLP), was converted to pyridoxamine 5'-phosphate (PMP). The rate of transamination catalyzed by Y265F was about 9% of that by the wild-type enzyme. However, Y265A, Y265S, and Y265F were similar in that L-alanine was inert as a substrate in transamination. The apo-form of the wild-type enzyme catalyzes the abstraction of tritium non-specifically from both (4'S)- and (4'R)-[4'-(3)H]PMP in the presence of pyruvate. In contrast, apo-Y265A abstracts tritium virtually from only the R-isomer. This indicates that the side-chain of Y265 abstracts the alpha-hydrogen of L-alanine and transfers it supra-facially to the pro-S position at C-4' of PMP. Y265 is the counterpart residue to K39 that transfers the alpha-hydrogen of D-alanine to the pro-R position of PMP.     

GDP-perosamine synthase: structural analysis and production of a novel trideoxysugar

Perosamine or 4-amino-4,6-dideoxy- d-mannose is an unusual sugar found in the O-antigens of some Gram-negative bacteria such as Vibrio cholerae O1 (the causative agent of cholera) or Escherichia coli O157:H7 (the leading cause of food-borne illnesses). It and similar deoxysugars are added to the O-antigens of bacteria via the action of glycosyltransferases that employ nucleotide-linked sugars as their substrates. The focus of this report is GDP-perosamine synthase, a PLP-dependent enzyme that catalyzes the last step in the formation of GDP-perosamine, namely, the amination of the sugar C-4'. Here we describe the three-dimensional structure of the enzyme from Caulobacter crescentus determined to a nominal resolution of 1.8 A and refined to an R-factor of 17.9%. The overall fold of the enzyme places it into the well-characterized aspartate aminotransferase superfamily. Each subunit of the dimeric enzyme contains a seven-stranded mixed beta-sheet, a two-stranded antiparallel beta-sheet, and 12 alpha-helices. Amino acid residues from both subunits form the active sites of the GDP-perosamine synthase dimer. Recently, the structure of another PLP-dependent enzyme, GDP-4-keto-6-deoxy- d-mannose-3-dehydratase (or ColD), was determined in our laboratory, and this enzyme employs the same substrate as GDP-perosamine synthase. Unlike GDP-perosamine synthase, however, ColD functions as a dehydratase that removes the sugar C-3' hydroxyl group. By purifying the ColD product and reacting it with purified GDP-perosamine synthase, we have produced a novel GDP-linked sugar, GDP-4-amino-3,4,6-trideoxy- d-mannose. Details describing the X-ray structural investigation of GDP-perosamine synthase and the enzymatic synthesis of GDP-4-amino-3,4,6-trideoxy- d-mannose are presented.     

Identification of an unusual [2Fe-2S]-binding motif in the CDP-6-deoxy-D-glycero-l-threo-4-hexulose-3-dehydrase from Yersinia pseudotuberculosis: implication for C-3 deoxygenation in the biosynthesis of 3,6-dideoxyhexoses

CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase (E(1)) catalyzes the C-3 deoxygenation in the biosynthesis of 3,6-dideoxyhexoses in Yersinia pseudotuberculosis. E(1) is a pyridoxamine 5'-phosphate (PMP)-dependent enzyme that also contains a [2Fe-2S] center. This iron-sulfur cluster is catalytically essential, since removal of the [2Fe-2S] center leads to inactive enzyme. To identify the [2Fe-2S] core in E(1) and to study the effect of impairing the iron-sulfur cluster on the activity of E(1), a series of E(1) cysteine mutants were constructed and their catalytic properties were characterized. Our results show that E(1) displays a cluster-binding motif (C-X(57)-C-X(1)-C-X(7)-C) that has not been observed previously for [2Fe-2S] proteins. The presence of such an unusual iron-sulfur cluster in E(1), along with the replacement of the active site lysine by a histidine residue (H220), reflects a distinct evolutionary path for this enzyme. The cysteine residues (C193, C251, C253, C261) implicated in the binding of the iron-sulfur cluster in E(1) are conserved in the sequences of its homologues. It is likely that E(1) and its homologues constitute a new subclass in the family of iron-sulfur proteins, which are distinguished not only by their cluster ligation patterns but also by the chemistry used in catalyzing a simple, albeit mechanistically challenging, reaction.