Purification of two forms of the associated 3-dehydroquinate hydro-lyase and shikimate:NADP+ oxidoreductase in Phaseolus mungo seedlings

Two associated enzymes, 3-dehydroquinate hydro-lyase (EC 4.2.1.10) and shikimate:NADP+ oxidoreductase (EC 1.1.1.25), have been purified from Phaseolus mungo seedlings. These enzymes were purified 6900- and 9700-fold, respectively, but they were not separable. Moreover, two activity bands of the shikimate:NADP+ oxidoreductase were detected after polyacrylamide gel electrophoresis and the two peaks also have 3-dehydroquinate hydro-lyase activity. The two forms of the associated enzymes showed only small differences in molecular weight, Km value, pH optimum and the responses to some inhibitors.     

Subcellular localization of the common shikimate-pathway enzymes in Pisum sativum L.

5-Enolpyruvylshikimate 3-phosphate (EPSP) synthase (3-phosphoshikimate 1-carboxyvinyltransferase; EC 2.5.1.19), 3-dehydroquinate dehydratase (EC 4.2.1.10) and shikimate: NADP⁺ oxidoreductase (EC 1.1.1.25) were present in intact chloroplasts and root plastids isolated from pea seedling extracts by sucrose and modified-silica density gradient centrifugation. In young (approx. 10-d-old) seedling shoots the enzymes were predominantly chloroplastic; high-performance anion-exchange chromatography resolved minor isoenzymic activities not observed in density-gradientpurified chloroplasts. The initial enzyme of the shikimate pathway, 3-deoxy-d-arabino-heptulosonate 7-phosphate synthase (EC 4.1.2.15) was also associated with intact density-gradient-purified chloroplasts. 3-Dehydroquinate synthase (EC 4.6.1.3) and shikimate kinase (EC 2.7.1.71) were detected together with the other pathway enzymes in stromal preparations from washed chloroplasts. Plastidic EPSP synthase was inhibited by micromolar concentrations of the herbicide glyphosate.Abbreviations DAHP 3-deoxy-d-arabino-heptulosonate 7-phosphate - DEAE diethylaminoethyl - DHQase 3-dehydroquinate dehydratase - DTT dithiothreitol - EPSP 5-enolpyruvylshikimate 3-phosphate - SORase shikimate:NADP⁺ oxidoreductase     

Alicyclic acid metabolism in plants 8. Association, of two enzymes of the shikimate pathway in shoots of Phaseolus mungo seedlings

The association of two enzymes involved in the shikimate pathway,3-dehydroquinate hydro-lyase (EC 4.2.1.10 [EC] ) and shikimate: NADPoxidoreductase (EC 1.1.1.25 [EC] ), was studied with shoots of etiolated4-day-old Phaseolus mungo seedlings. The enzymes were not separableby ammonium sulfate fractionation, sucrose density gradientcentrifugation, polyacrylamide gel electrophoresis and chromatographyon Sephadex G-100 and DEAE-Sephadex A-50. The results are discussedin relation to the channelling function of metabolites in thealicyclic acid metabolism in higher plants. (Received October 28, 1975; )     

Aggregation and separability of the shikimate pathway enzymes in yeasts

Gel filtration was employed to estimate the molecular weights and to determine possible physical aggregation of enzymes [5-dehydroquinate synthase (DHQ synthase), 5-dehydroquinase (DHQase, EC 4.2.1.10), shikimate: NADP oxidoreductase (EC 1.1.1.25), shikimate kinase (EC 2.7.1.71), 3-enolpyruvylshikimate 5-phosphate synthase (EPSP synthase)] in the shikimate pathway in eleven species of yeasts. The five enzymes were not aggregated in extracts of Hansenula henricii, H. fabianii, H. anomala, Candida utilis, Pichia guilliermondii, and Lodderomyces elongisporus. Two enzymes (DHQase and shikimate:NADP oxidoreductase) were not separable by this method and by ion exchange chromatography, and we conclude that they exist as an aggregate in these yeasts. Evidence is presented for an enzyme aggregate containing five activities, with a molecular weight of approximately 280,000 in Rhodosporidium spaerocarpum, Rh. toruloides, Rhodotorula rubra, Saccharomycopsis lipolytica, and Saccharomyces cerevisiae. Similarities between the enzymes in the shikimate pathway of plants, bacteria, and other fungi and those of investigated yeasts are discussed.     

3-dehydroquinate production by oxidative fermentation and further conversion of 3-dehydroquinate to the intermediates in the shikimate pathway

3-Dehydroquinate production from quinate by oxidative fermentation with Gluconobacter strains of acetic acid bacteria was analyzed for the first time. In the bacterial membrane, quinate dehydrogenase, a typical quinoprotein containing pyrroloquinoline quinone (PQQ) as the coenzyme, functions as the primary enzyme in quinate oxidation. Quinate was oxidized to 3-dehydroquinate with the final yield of almost 100% in earlier growth phase. Resting cells, dried cells, and immobilized cells or an immobilized membrane fraction of Gluconobacter strains were found to be useful biocatalysts for quinate oxidation. 3-Dehydroquinate was further converted to 3-dehydroshikimate with a reasonable yield by growing cells and also immobilized cells. Strong enzyme activities of 3-dehydroquinate dehydratase and NADP-dependent shikimate dehydrogenase were detected in the soluble fraction of the same organism and partially fractionated from each other. Since the shikimate pathway is remote from glucose in the metabolic pathway, the entrance into the shikimate pathway from quinate to 3-dehydroquinate looks advantageous to produce metabolic intermediates in the shikimate pathway.     

Conversion of quinate to 3-dehydroshikimate by Ca-alginate-immobilized membrane of Gluconobacter oxydans IFO 3244 and subsequent asymmetric reduction of 3-dehydroshikimate to shikimate by immobilized cytoplasmic NADP-shikimate dehydrogenase

The membrane fraction of Gluconobacter oxydans IFO 3244, involving membrane-bound quinoprotein quinate dehydrogenase and 3-dehydroquinate dehydratase, was immobilized into Ca-alginate beads. The Ca-alginate-immobilized bacterial membrane catalyzed a sequential reaction of quinate oxidation to 3-dehydroquinate and its spontaneous conversion to 3-dehydroshikimate under neutral pH. An almost 100% conversion rate from quinate to 3-dehydroshikimate was observed. NADP-Dependent cytoplasmic enzymes from the same organism, shikimate dehydrogenase and D-glucose dehydrogenase, were immobilized together with different carriers as an asymmetric reduction system forming shikimate from 3-dehydroshikimate. Blue Dextran 2000, Blue Dextran-Sepharose-4B, DEAE-Sephadex A-50, DEAE-cellulose, and hydroxyapatite were effective carriers of the two cytoplasmic enzymes, and the 3-dehydroshikimate initially added was converted to shikimate at 100% yield. The two cytoplasmic enzymes showed strong affinity to Blue Dextran 2000 and formed a soluble form of immobilized catalyst having the same catalytic efficiency as that of the free enzymes. This paper may be the first one on successful immobilization of NAD(P)-dependent dehydrogenases.     

Enzymatic preparation of metabolic intermediates, 3-dehydroquinate and 3-dehydroshikimate, in the shikimate pathway

A method for enzymatic preparation of 3-dehydroquinate and 3-dehydroshikimate in the shikimate pathway was established by controlling the enzyme activity of 3-dehydroquinate dehydratase. When quinate was incubated with the membrane fraction of acetic acid bacteria at pH 5.0, 3-dehydroquinate was formed as the predominant product. 3-Dehydroshikimate was the sole product when incubated at pH 8.0. Mutual separation of the metabolic intermediates was also exemplified.     

Non-light-dependent Shikimate Pathway in Plastids from Pea Roots

Non-green plastids (leucoplasts) isolated from pea roots are shown to be considerably active in forming aromatic amino acids by the shikimate pathway which, in contrast to the chloroplast pathway, is independent of light. Supply of phosphoenolpyruvate and 3-dehydroquinate, 3-dehydroshikimate, shikimate and quinate effectively enhances the formation of aromatic amino acids suggesting an intra- or/and intercellular intermediate transport.     

Conversion of Quinate to 3-Dehydroshikimate by Ca-Alginate-Immobilized Membrane of Gluconobacter oxydans IFO 3244 and Subsequent Asymmetric Reduction of 3-Dehydroshikimate to Shikimate by Immobilized Cytoplasmic NADP-Shikimate Dehydrogenase

The membrane fraction of Gluconobacter oxydans IFO 3244, involving membrane-bound quinoprotein quinate dehydrogenase and 3-dehydroquinate dehydratase, was immobilized into Ca-alginate beads. The Ca-alginate-immobilized bacterial membrane catalyzed a sequential reaction of quinate oxidation to 3-dehydroquinate and its spontaneous conversion to 3-dehydroshikimate under neutral pH. An almost 100% conversion rate from quinate to 3-dehydroshikimate was observed. NADP-Dependent cytoplasmic enzymes from the same organism, shikimate dehydrogenase and D-glucose dehydrogenase, were immobilized together with different carriers as an asymmetric reduction system forming shikimate from 3-dehydroshikimate. Blue Dextran 2000, Blue Dextran-Sepharose-4B, DEAE-Sephadex A-50, DEAE-cellulose, and hydroxyapatite were effective carriers of the two cytoplasmic enzymes, and the 3-dehydroshikimate initially added was converted to shikimate at 100% yield. The two cytoplasmic enzymes showed strong affinity to Blue Dextran 2000 and formed a soluble form of immobilized catalyst having the same catalytic efficiency as that of the free enzymes. This paper may be the first one on successful immobilization of NAD(P)-dependent dehydrogenases.     

High shikimate production from quinate with two enzymatic systems of acetic acid bacteria

3-Dehydroshikimate was formed with a yield of 57-77% from quinate via 3-dehydroquinate by two successive enzyme reactions, quinoprotein quinate dehydrogenase (QDH) and 3-dehydroquinate dehydratase, in the cytoplasmic membranes of acetic acid bacteria. 3-Dehydroshikimate was then reduced to shikimate (SKA) with NADP-dependent SKA dehydrogenase (SKDH) from the same organism. When SKDH was coupled with NADP-dependent D-glucose dehydrogenase (GDH) in the presence of excess D-glucose as an NADPH re-generating system, SKDH continued to produce SKA until 3-dehydroshikimate added initially in the reaction mixture was completely converted to SKA. Based on the data presented, a strategy for high SKA production was proposed.     

Effect of shade treatment on biosynthesis of catechins in tea plants

When tea plants were shaded with black lawn cloth for severaldays in the field, the accumulations of (—)-epicatechin,(—)-epicatechin-3-gallate, (—)-epigallocatechinand (—)-epigallocatechin-3-gallate decreased in newlydeveloping tea shoots. Radioactive tracer studies showed thatthe conversions of glucose-U-¹⁴C, shikimic acid-G-¹⁴C and phenylalanine-U-¹⁴Cinto (—)-epicatechin and (—)-epigallocatechin moietieswere depressed by the shade treatment for tea plants but theincorporation of trans-cinnamic acid-3-¹⁴C was not affected.The treatment was found to have no significant effect on theactivities of phospho-2-keto-3-deoxy-heptonate. aldolase (EC.4.1.2.15 [EC] ), 3-dehydroquinate synthase (EC. 4.6.1.3 [EC] ), 3-dehydroquinatedehydratase (EC. 4.2.1.10 [EC] ), shikimate dehydrogenase (EC. 1.1.1.25 [EC] )and trans-cinnamate 4-monooxygenase (EC. 1.14.13.11 [EC] ) in theshoots, whereas the activity of phenylalanine ammonia-lyase(EC. 4.3.1.5 [EC] ) clearly decreased. (Received March 17, 1980; )     

Domain structure and interaction within the pentafunctional arom polypeptide.

The AROM locus of Aspergillus nidulans specifies a pentafunctional polypeptide catalysing five consecutive steps leading to the production of 5-enolpyruvylshikimate 3-phosphate in the shikimate pathway. Aided by oligonucleotide-mediated site-directed mutagenesis, the whole AROM locus and various overlapping subfragments from within it have been fused to the powerful hybrid trc promoter in the Escherichia coli plasmid pKK233-2. Expression of these subfragments in appropriate aro mutants of E. coli has (a) allowed the delineation of functional domains within the arom polypeptide, (b) shown that the arom polypeptide falls in two independently folding and functioning regions, the N-terminal half specifying 3-dehydroquinate (DHQ) synthase and EPSP synthase and the C-terminus specifying shikimate kinase, biosynthetic 3-dehydroquinase (DHQase) and shikimate dehydrogenase, and (c) strongly suggested an interaction between the DHQ synthase and EPSP synthase domains to stabilise the EPSP synthase activity. In addition an isoenzyme of biosynthetic DHQase, catabolic DHQase, encoded by the QUTE gene of A. nidulans has been transcribed from the trc promoter and upon isopropyl-thio-beta-D-galactoside induction produces up to 20% of the total soluble cell protein.     

Molecular Characterization of Quinate and Shikimate Metabolism in Populus trichocarpa

The shikimate pathway leads to the biosynthesis of aromatic amino acids essential for protein biosynthesis and the production of a wide array of plant secondary metabolites. Among them, quinate is an astringent feeding deterrent that can be formed in a single step reaction from 3-dehydroquinate catalyzed by quinate dehydrogenase (QDH). 3-Dehydroquinate is also the substrate for shikimate biosynthesis through the sequential actions of dehydroquinate dehydratase (DQD) and shikimate dehydrogenase (SDH) contained in a single protein in plants. The reaction mechanism of QDH resembles that of SDH. The poplar genome encodes five DQD/SDH-like genes (Poptr1 to Poptr5), which have diverged into two distinct groups based on sequence analysis and protein structure prediction. In vitro biochemical assays proved that Poptr1 and -5 are true DQD/SDHs, whereas Poptr2 and -3 instead have QDH activity with only residual DQD/SDH activity. Poplar DQD/SDHs have distinct expression profiles suggesting separate roles in protein and lignin biosynthesis. Also, the QDH genes are differentially expressed. In summary, quinate (secondary metabolism) and shikimate (primary metabolism) metabolic activities are encoded by distinct members of the same gene family, each having different physiological functions.     

The oxidation of d-quinate and related acids by Acetomonas oxydans

1. Growing cells of a small number of strains of Acetomonas oxydans oxidized d-quinate to 5-dehydroquinate. 2. d-Shikimate was oxidized to 4,5-dihydroxy-3-oxocyclohex-1-ene-1-carboxylate (3-dehydroshikimate, formerly 5-dehydroshikimate). 3. d-Dihydroshikimate was oxidized to the corresponding 5-dehydro compound, but epidihydroshikimate oxidation by growing cells was not observed. 4. Cell-free extracts oxidized d-quinate to 5-dehydroquinate with the consumption of the stoicheiometric amount of oxygen, but oxidation of shikimate and dihydroshikimate did not go to completion. 5. Oxidation of quinate was brought about by a constitutive particulate enzyme probably localized in the cytoplasmic membrane. No evidence was found for the participation of NAD, NADP or free flavine compounds in electron transport, but the system was cytochrome-linked.     

The two types of 3-dehydroquinase have distinct structures but catalyze the same overall reaction.

The structures of enzymes catalyzing the reactions in central metabolic pathways are generally well conserved as are their catalytic mechanisms. The two types of 3-dehydroquinate dehydratase (DHQase) are therefore most unusual since they are unrelated at the sequence level and they utilize completely different mechanisms to catalyze the same overall reaction. The type I enzymes catalyze a cis-dehydration of 3-dehydroquinate via a covalent imine intermediate, while the type II enzymes catalyze a trans-dehydration via an enolate intermediate. Here we report the three-dimensional structures of a representative member of each type of biosynthetic DHQase. Both enzymes function as part of the shikimate pathway, which is essential in microorganisms and plants for the biosynthesis of aromatic compounds including folate, ubiquinone and the aromatic amino acids. An explanation for the presence of two different enzymes catalyzing the same reaction is presented. The absence of the shikimate pathway in animals makes it an attractive target for antimicrobial agents. The availability of these two structures opens the way for the design of highly specific enzyme inhibitors with potential importance as selective therapeutic agents.     

The Mycobacterium tuberculosis shikimate pathway genes: Evolutionary relationship between biosynthetic and catabolic 3-dehydroquinases

Summary The Mycobacterium tuberculosis shikimate pathway genes designated aroB and aroQ encoding 3-dehydroquinate synthase and 3-dehydroquinase, respectively were isolated by molecular cloning and their nucleotide sequences determined. The deduced dehydroquinate synthase amino acid sequence from M. tuberculosis showed high similarity to those of equivalent enzymes from prokaryotes and filamentous fungi. Surprisingly, the deduced M. tuberculosis 3-dehydroquinase amino acid sequence showed no similarity to other characterised prokaryotic biosynthetic 3-dehydroquinases (bDHQases). A high degree of similarity was observed, however, to the fungal catabolic 3-dehydroquinases (cDHQases) which are active in the quinic acid utilisation pathway and are isozymes of the fungal bDHQases. This finding indicates a common ancestral origin for genes encoding the catabolic dehydroquinases of fungi and the biosynthetic dehydroquinases present in some prokaryotes. Deletion of genes encoding shikimate pathway enzymes represents a possible approach to generation of rationally attenuated strains of M. tuberculosis for use as live vaccines.     

Characterization of shikimate dehydrogenase homologues of Corynebacterium glutamicum

The function of three Corynebacterium glutamicum shikimate dehydrogenase homologues, designated as qsuD (cgR_0495), cgR_1216, and aroE (cgR_1677), was investigated. A disruptant of aroE required shikimate for growth, whereas a qsuD-deficient strain did not grow in medium supplemented with either quinate or shikimate as sole carbon sources. There was no discernible difference in growth rate between wild-type and a cgR_1216-deficient strain. Enzymatic assays showed that AroE both reduced 3-dehydroshikimate, using NADPH as cofactor, and oxidized shikimate, the reverse reaction, using NADP⁺ as cofactor. The reduction reaction was ten times faster than the oxidation. QsuD reduced 3-dehydroquinate using NADH and oxidized quinate using NAD⁺ as cofactor. Different from the other two homologues, the product of cgR_1216 displayed considerably lower enzyme activity for both the reduction and the oxidation. The catalytic reaction of QsuD and AroE was highly susceptible to pH. Furthermore, reduction of 3-dehydroshikimate by AroE was inhibited by high concentrations of shikimate, but neither quinate nor aromatic amino acids had any effect on the reaction. Expression of qsuD mRNA was strongly enhanced in the presence of shikimate, whereas that of cgR_1216 and aroE decreased. We conclude that while AroE is the main catalyst for shikimate production in the shikimate pathway, QsuD is essential for quinate/shikimate utilization.     

L-Aspartate semialdehyde and a 6-deoxy-5-ketohexose 1-phosphate are the precursors to the aromatic amino acids in Methanocaldococcus jannaschii

No orthologs are present in the genomes of the archaea encoding genes for the first two steps in the biosynthesis of the aromatic amino acids leading to 3-dehydroquinate (DHQ). The absence of these genes prompted me to examine the nature of the reactions involved in the archaeal pathway leading to DHQ in Methanocaldococcus jannaschii. Here I report that 6-deoxy-5-ketofructose 1-phosphate and l-aspartate semialdehyde are precursors to DHQ. The sugar, which is derived from glucose 6-P, supplies a "hydroxyacetone" fragment, which, via a transaldolase reaction, undergoes an aldol condensation with the l-aspartate semialdehyde to form 2-amino-3,7-dideoxy-D-threo-hept-6-ulosonic acid. Despite the fact that both hydroxyacetone and hydroxyacetone-P were measured in the cell extracts and confirmed to arise from glucose 6-P, neither compound was found to serve as a precursor to DHQ. This amino sugar then undergoes a NAD dependent oxidative deamination to produce 3,7-dideoxy-d-threo-hept-2,6-diulosonic acid which cyclizes to 3-dehydroquinate. The protein product of the M. jannaschii MJ0400 gene catalyzes the transaldolase reaction and the protein product of the MJ1249 gene catalyzes the oxidative deamination and the cyclization reactions. The DHQ is readily converted into dehydroshikimate and shikimate in M. jannaschii cell extracts, consistent with the remaining steps and genes in the pathway being the same as in the established shikimate pathway.