Purification and kinetic analysis of the two recombinant arogenate dehydrogenase isoforms of Arabidopsis thaliana.

The present study reports the first purification and kinetic characterization of two plant arogenate dehydrogenases (EC 1.3.1.43), an enzyme that catalyses the oxidative decarboxylation of arogenate into tyrosine in presence of NADP. The two Arabidopsis thaliana arogenate dehydrogenases TyrAAT1 and TyrAAT2 were overproduced in Escherichia coli and purified to homogeneity. Biochemical comparison of the two forms revealed that at low substrate concentration TyrAAT1 is four times more efficient in catalyzing the arogenate dehydrogenase reaction than TyrAAT2. Moreover, TyrAAT2 presents a weak prephenate dehydrogenase activity whereas TyrAAT1 does not. The mechanism of the dehydrogenase reaction catalyzed by these two forms has been investigated using steady-state kinetics. For both enzymes, steady-state velocity patterns are consistent with a rapid equilibrium, random mechanism in which two dead-end complexes, E-NADPH-arogenate and E-NADP-tyrosine, are formed.     

Crystal structure of prephenate dehydrogenase from Aquifex aeolicus. Insights into the catalytic mechanism

The enzyme prephenate dehydrogenase catalyzes the oxidative decarboxylation of prephenate to 4-hydroxyphenylpyruvate for the biosynthesis of tyrosine. Prephenate dehydrogenases exist as either monofunctional or bifunctional enzymes. The bifunctional enzymes are diverse, since the prephenate dehydrogenase domain is associated with other enzymes, such as chorismate mutase and 3-phosphoskimate 1-carboxyvinyltransferase. We report the first crystal structure of a monofunctional prephenate dehydrogenase enzyme from the hyper-thermophile Aquifex aeolicus in complex with NAD+. This protein consists of two structural domains, a modified nucleotide-binding domain and a novel helical prephenate binding domain. The active site of prephenate dehydrogenase is formed at the domain interface and is shared between the subunits of the dimer. We infer from the structure that access to the active site is regulated via a gated mechanism, which is modulated by an ionic network involving a conserved arginine, Arg250. In addition, the crystal structure reveals for the first time the positions of a number of key catalytic residues and the identity of other active site residues that may participate in the reaction mechanism; these residues include Ser126 and Lys246 and the catalytic histidine, His147. Analysis of the structure further reveals that two secondary structure elements, beta3 and beta7, are missing in the prephenate dehydrogenase domain of the bifunctional chorismate mutase-prephenate dehydrogenase enzymes. This observation suggests that the two functional domains of chorismate mutase-prephenate dehydrogenase are interdependent and explains why these domains cannot be separated.     

A single cyclohexadienyl dehydrogenase specifies the prephenate dehydrogenase and arogenate dehydrogenase components of the dual pathways to L-tyrosine in Pseudomonas aeruginosa

Dual biosynthetic pathways diverge from prephenate to L-tyrosine in Pseudomonas aeruginosa, with 4-hydroxyphenylpyruvate and L-arogenate being the unique intermediates of these pathways. Prephenate dehydrogenase and arogenate dehydrogenase activities could not be separated throughout fractionation steps yielding a purification of more than 200-fold, and the ratio of activities was constant throughout purification. Thus, the enzyme is a cyclohexadienyl dehydrogenase. The native enzyme has a molecular weight of 150,000 and is a hexamer made up of identical 25,500 subunits. The enzyme is specific for NAD+ as an electron acceptor, and identical Km values of 0.25 mM were obtained for NAD+, regardless of whether activity was assayed as prephenate dehydrogenase or as arogenate dehydrogenase. Km values of 0.07 mM and 0.17 mM were calculated for prephenate and L-arogenate, respectively. Inhibition by L-tyrosine was noncompetitive with respect to NAD+, but was strictly competitive with respect to either prephenate or L-arogenate. With cyclohexadiene as variable substrate, similar Ki values for L-tyrosine of 0.06 mM (prephenate) and 0.05 mM (L-arogenate) were obtained. With NAD+ as the variable substrate, similar Ki values for L-tyrosine of 0.26 mM (prephenate) and 0.28 mM (L-arogenate), respectively, were calculated. This is the first characterization of a purified, monofunctional cyclohexadienyl dehydrogenase.     

Biochemical diversity for biosynthesis of aromatic amino acids among the cyanobacteria.

We examined the enzymology and regulatory patterns of the aromatic amino acid pathway in 48 strains of cyanobacteria including representatives from each of the five major grouping. Extensive diversity was found in allosteric inhibition patterns of 3-deoxy-D-arabinoheptulosonate 7-phosphate synthase, not only between the major groupings but also within several of the generic groupings. Unimetabolite inhibition by phenylalanine occurred in approximately half of the strains examined; in the other strains unimetabolite inhibition by tyrosine and cumulative, concerted, and additive patterns were found. The additive patterns suggest the presence of regulatory isozymes. Even though both arogenate and prephenate dehydrogenase activities were found in some strains, it seems clear that the arogenate pathway to tyrosine is a common trait that has been highly conserved among cyanobacteria. No arogenate dehydratase activities were found. In general, prephenate dehydratase activities were activated by tyrosine and inhibited by phenylalanine. Chorismate mutase, arogenate dehydrogenase, and shikimate dehydrogenase were nearly always unregulated. Most strains preferred NADP as the cofactor for the dehydrogenase activities. The diversity in the allosteric inhibition patterns for 3-deoxy-D-arabinoheptulosonate 7-phosphate synthase, cofactor specificities, and the presence or absence of prephenate dehydrogenase activity allowed the separation of subgroupings within several of the form genera, namely, Synechococcus, Synechocystis, Anabaena, Nostoc, and Calothrix.     

Response of aromatic-pathway enzymes to changing physiological states of growth in suspension cultures of Nicotiana silvestris

The activity levels of enzymes of aromatic amino acid biosynthesis respond to changing physiological states of growth, as illustrated by results obtained from suspension-cultured cells of Nicotiana silvestris Speg. et Comes line ANS 1 (2N=24). The experimental system provides a foundation for interpretations about overall regulation of enzyme levels in relationship to growth physiology. Levels of activity for shikimate dehydrogenase (EC 1.1.1.25), prephenate aminotransferase and arogenate dehydrogenase were followed throughout a growth cycle obtained by a conventional subculture protocol. Enzyme date were also obtained from cell cultures maintained in continuous exponential growth for greater than 10 generations (EE cells). Both shikimate dehydrogenase and prephenate aminotransferase exhibited elevated stationary-phase levels of enzyme, much of which was carried over into a subsequent subculture. At least 4 generations of exponential growth were required before diminution of the latter two enzymes to the levels characteristic of truly exponential-phase growth (EE cells) occurred. This is reminiscent of the overall behavior of 3-deoxy-D- arabino -heptulosonate 7-phosphate (DAHP) synthase (EC 4.1.2.15), specifically attributed to the properties of the cytosolic isozyme species (DAHP synthase-Co). Elevation of arogenate dehydrogenase also occurred in stationary-phase cells, but diminished rapidly during lag phase to reach the level characteristic of EE cells.     

Clues from Xanthomonas campestris about the evolution of aromatic biosynthesis and its regulation

The recent placement of major Gram-negative prokaryotes (Superfamily B) on a phylogenetic tree (including, e.g., lineages leading to Escherichia coli, Pseudomonas aeruginosa, and Acinetobacter calcoaceticus) has allowed initial insights into the evolution of the biochemical pathway for aromatic amino acid biosynthesis and its regulation to be obtained. Within this prokaryote grouping, Xanthomonas campestris ATCC 12612 (a representative of the Group V pseudomonads) has played a key role in facilitating deductions about the major evolutionary events that shaped the character of aromatic biosynthesis within this grouping. X. campestris is like P. aeruginosa (and unlike E. coli) in its possession of dual flow routes to both L-phenylalanine and L-tyrosine from prephenate. Like all other members of Superfamily B, X. campestris possesses a bifunctional P-protein bearing the activities of both chorismate mutase and prephenate dehydratase. We have found an unregulated arogenate dehydratase similar to that of P. aeruginosa in X. campestris. We separated the two tyrosine-branch dehydrogenase activities (prephenate dehydrogenase and arogenate dehydrogenase); this marks the first time this has been accomplished in an organism in which these two activities coexist. Superfamily B organisms possess 3-deoxy-D-arabino-heptulosonate 7-P (DAHP) synthase as three isozymes (e.g., in E. coli), as two isozymes (e.g., in P. aeruginosa), or as one enzyme (in X. campestris). The two-isozyme system has been deduced to correspond to the ancestral state of Superfamily B. Thus, E. coli has gained an isozyme, whereas X. campestris has lost one. We conclude that the single, chorismate-sensitive DAHP synthase enzyme of X. campestris is evolutionarily related to the tryptophan-sensitive DAHP synthase present throughout the rest of Superfamily B. In X. campestris, arogenate dehydrogenase, prephenate dehydrogenase, the P-protein, chorismate mutase-F, anthranilate synthase, and DAHP synthase are all allosteric proteins; we compared their regulatory properties with those of enzymes of other Superfamily B members with respect to the evolution of regulatory properties. The network of sequentially operating circuits of allosteric control that exists for feedback regulation of overall carbon flow through the aromatic pathway in X. campestris is thus far unique in nature.     

Three Different Classes of Aminotransferases Evolved Prephenate Aminotransferase Functionality in Arogenate-competent Microorganisms

The aromatic amino acids phenylalanine and tyrosine represent essential sources of high value natural aromatic compounds for human health and industry. Depending on the organism, alternative routes exist for their synthesis. Phenylalanine and tyrosine are synthesized either via phenylpyruvate/4-hydroxyphenylpyruvate or via arogenate. In arogenate-competent microorganisms, an aminotransferase is required for the transamination of prephenate into arogenate, but the identity of the genes is still unknown. We present here the first identification of prephenate aminotransferases (PATs) in seven arogenate-competent microorganisms and the discovery that PAT activity is provided by three different classes of aminotransferase, which belong to two different fold types of pyridoxal phosphate enzymes: an aspartate aminotransferase subgroup 1β in tested α- and β-proteobacteria, a branched-chain aminotransferase in tested cyanobacteria, and an N-succinyldiaminopimelate aminotransferase in tested actinobacteria and in the β-proteobacterium Nitrosomonas europaea. Recombinant PAT enzymes exhibit high activity toward prephenate, indicating that the corresponding genes encode bona fide PAT. PAT functionality was acquired without other modification of substrate specificity and is not a general catalytic property of the three classes of aminotransferases.     

Enzymological features of aromatic amino acid biosynthesis reflect the phylogeny of mycoplasmas

Acholeplasma laidlawii possesses a biochemical pathway for tyrosine and phenylalanine biosynthesis, while Mycoplasma iowae and Mycoplasma gallinarum do not. The detection of 7-phospho-2-dehydro-3-deoxy-D-arabino-heptonate (DAHP) synthase (EC 4.1.2.15), dehydro-shikimate reductase (EC 1.1.1.25) and 3-enol-pyruvoylshikimate-5-phosphate synthase (EC 2.5.1.19) activities in cell-free extracts established the presence in A. laidlawii of a functional shikimate pathway. L-Phenylalanine synthesis occurs solely through the phenylpyruvate route via prephenate dehydratase (EC 4.2.1.51), no arogenate dehydratase activity being found. Although arogenate dehydrogenase was detected, L-tyrosine synthesis appears to occur mainly through the 4-hydroxyphenylpyruvate route, via prephenate dehydrogenase (EC 1.3.1.12), which utilized NAD+ as a preferred coenzyme substrate. L-Tyrosine was found to be the key regulatory molecule governing aromatic biosynthesis. DAHP synthase was feedback inhibited by L-tyrosine, but not by L-phenylalanine or L-tryptophan; L-tyrosine was a potent feedback inhibitor of prephenate dehydrogenase and an allosteric activator of prephenate dehydratase. Chorismate mutase (EC 5.4.99.5) was sensitive to product inhibition by prephenate. Prephenate dehydratase was feedback inhibited by L-phenylalanine. It was also activated by hydrophobic amino acids (L-valine, L-isoleucine and L-methionine), similar to results previously found in a number of other genera that share the Gram-positive line of phylogenetic descent. Aromatic-pathway-encoded cistrons present in saprophytic large-genome mycoplasmas may have been eliminated in the parasitic small-genome mycoplasmas.     

Enzymic arrangement and allosteric regulation of the aromatic amino acid pathway in Neisseria gonorrhoeae

The pathway construction and allosteric regulation of phenylalanine and tyrosine biosynthesis was examined in Neisseria gonorrhoeae. A single 3-deoxy-d-arabino-heptulosonate 7-phosphate (DAHP) synthase enzyme sensitive to feedback inhibition by l-phenylalanine was found. Chorismate mutase and prephenate dehydratase appear to co-exist as catalytic components of a bifunctional enzyme, known to be present in related genera. The latter enzyme activities were both feedback inhibited by l-phenylalanine. Prephenate dehydratase was strongly activated by l-tyrosine. NAD⁺-linked prephenate dehydrogenase and arogenate dehydrogenase activities coeluted following ion-exchange chromatography, suggesting their identity as catalytic properties of a single broad-specificity cyclohexadienyl dehydrogenase. Each dehydrogenase activity was inhibited by 4-hydroxyphenylpyruvate, but not by l-tyrosine. Two aromatic aminotransferases were resolved, one preferring the l-phenylalanine:2-ketoglutarate substrate combination and the other preferring the l-tyrosine: 2-ketoglutarate substrate combination. Each aminotransferase was also able to transaminate prephenate. The overall picture of regulation is one in which l-tyrosine modulates l-phenylalanine synthesis via activation of prephenate dehydratase. l-Phenylalanine in turn regulates early-pathway flow through inhibition of DAHP synthase. The recent phylogenetic positioning of N. gonorrhoeae makes it a key reference organism for emerging interpretations about aromatic-pathway evolution.     

The Crystal Structure of Aquifex aeolicus Prephenate Dehydrogenase Reveals the Mode of Tyrosine Inhibition

TyrA proteins belong to a family of dehydrogenases that are dedicated to l-tyrosine biosynthesis. The three TyrA subclasses are distinguished by their substrate specificities, namely the prephenate dehydrogenases, the arogenate dehydrogenases, and the cyclohexadienyl dehydrogenases, which utilize prephenate, l-arogenate, or both substrates, respectively. The molecular mechanism responsible for TyrA substrate selectivity and regulation is unknown. To further our understanding of TyrA-catalyzed reactions, we have determined the crystal structures of Aquifex aeolicus prephenate dehydrogenase bound with NAD⁺ plus either 4-hydroxyphenylpyuvate, 4-hydroxyphenylpropionate, or l-tyrosine and have used these structures as guides to target active site residues for site-directed mutagenesis. From a combination of mutational and structural analyses, we have demonstrated that His-147 and Arg-250 are key catalytic and binding groups, respectively, and Ser-126 participates in both catalysis and substrate binding through the ligand 4-hydroxyl group. The crystal structure revealed that tyrosine, a known inhibitor, binds directly to the active site of the enzyme and not to an allosteric site. The most interesting finding though, is that mutating His-217 relieved the inhibitory effect of tyrosine on A. aeolicus prephenate dehydrogenase. The identification of a tyrosine-insensitive mutant provides a novel avenue for designing an unregulated enzyme for application in metabolic engineering.Tyrosine serves as a precursor for the synthesis of proteins and secondary metabolites such as quinones (1-3), alkaloids (4), flavonoids (5), and phenolic compounds (5, 6). In prokaryotes and plants, these compounds are important for viability and normal development (7).The TyrA protein family consists of dehydrogenase homologues that are dedicated to the biosynthesis of l-tyrosine. These enzymes participate in two independent metabolic branches that result in the conversion of prephenate to l-tyrosine, namely the arogenate route and the 4-hydroxyphenylpyruvate (HPP)³ routes. Although both of these pathways utilize a common precursor and converge to produce a common end-product, they differ in the sequential order of enzymatic steps. Through the HPP route, prephenate is first decarboxylated by prephenate dehydrogenase (PD) to yield HPP, which is subsequently transaminated to l-tyrosine via a TyrB homologue (8). Alternatively, through the arogenate route, prephenate is first transaminated to l-arogenate by prephenate aminotransferase and then decarboxylated by arogenate dehydrogenase (AD) to yield l-tyrosine (9-11) (see Fig. 1A).Open in a separate windowFIGURE 1.A, metabolic routes from chorismate leading to the synthesis of l-tyrosine and l-phenylalanine. In the arogenate, 4-hydroxyphenylpyruvate, or phenylpyruvate route, prephenate and arogenate are branch point intermediates in both l-tyrosine and l-phenylalanine biosynthesis. Prephenate dehydrogenase catalyzes the oxidative decarboxylation of prephenate with NAD⁺ to produce hydroxyphenylpyruvate, NADH, and CO₂ (40). B, a comparison of the chemical structure of the three ligands, HPP, HPpropionate, and tyrosine, used in the crystallization of A. aeolicus prephenate dehydrogenase. These ligands all have an -OH at the C4 position and a propionyl side chain at the C1 position of the ring.There are three classes of TyrA enzymes that catalyze the oxidative decarboxylation reactions in these two pathways. The enzymes are distinguished by the affinity for cyclohexadienyl substrates. PD and AD accept prephenate or l-arogenate, respectively, whereas the cyclohexadienyl dehydrogenases can catalyze the reaction using either substrate (12).To ensure efficient metabolite distribution of the pathway intermediates, TyrA enzymes are highly regulated by various control mechanisms, including feedback inhibition, and genetic regulation by the Tyr operon (13-16). In some cases, l-tyrosine competes directly with substrate, be it prephenate or l-arogenate for the active site of arogenate or cyclohexadienyl dehydrogenases (14, 17-19). The product HPP can also serve as an efficient competitive inhibitor with respect to prephenate (20). Additionally, at the protein level PDs are only shown to be regulated at distinct allosteric sites or domains to modulate their activity. For example, the results of kinetic studies on the bifunctional Escherichia coli chorismate mutase-prephenate dehydrogenase (CM-PD) have indicated that this enzyme likely possesses a distinct allosteric site for binding tyrosine (21). In contrast, the Bacillus subtilis PD is the only enzyme reported to be competitively inhibited by HPP and l-tyrosine but is also noncompetitively inhibited by l-phenylalanine and l-tryptophan (12, 22). Additional regulatory control is thought to originate through a C-terminal aspartate kinase-CM-TyrA domain of the B. subtilis PD (23).Biochemical analyses of PD from E. coli CM-PD have provided a framework for understanding the molecular mechanism of the TyrA enzymes. The E. coli PD-catalyzed reaction proceeds though a rapid equilibrium, random kinetic mechanism with catalysis as the rate-limiting step (24). Additionally, studies of the pH dependence of the kinetic parameters V and V/K indicate that a deprotonated group facilitates hydride transfer from prephenate to NAD⁺ by polarizing the 4-hydroxyl group of prephenate, whereas a protonated residue is required for binding prephenate to the enzyme·NAD⁺ complex (25). The conserved residues His-197 and Arg-294 have been identified through extensive mutagenesis studies to fulfill these two roles (26, 27). Further analyses of the activities of wild-type protein and site-directed variants in the presence of a series of inhibitory substrate analogues support the idea that Arg-294 binds prephenate through the ring carboxylate (26).The structures of AD from Synechocystis sp. and PD from Aquifex aeolicus (both in complex with NAD⁺) have been reported by Legrand et al. (28) and by our group (29), respectively. Analyses of these structures have provided structural information on the conserved histidine and arginine residues. The structure A. aeolicus PD has also led to the identification of other active site residues that may play a role in enzyme catalysis, most notably Ser-126, which we propose facilitates catalysis by orienting the catalytic histidine and the nicotinamide moiety of NAD⁺ into their catalytically efficient conformations. Ambiguities can arise from examination of the binary complexes, because prephenate has only been modeled in the active site. For example, analysis of the AD structure by Legrand et al. (28) places Arg-217 (equivalent to Arg-294 in E. coli and Arg-250 in A. aeolicus) too far from the active site to play a role in prephenate binding. Thus, the full complement of interactions between prephenate and TyrA proteins are still largely unknown, as are the interactions of the enzymes with l-tyrosine.To further investigate the importance of residues involved in ligand binding, specificity, and catalysis, we have carried out co-crystallization studies of A. aeolicus PD with NAD⁺ and prephenate, with NAD⁺ and 4-hydroxyphenylpropionate (HPpropionate), a product analogue, and with NAD⁺ and l-tyrosine. Accordingly, this study provides the first direct evidence that l-tyrosine binds to the active site of a prephenate dehydrogenase. We have investigated the role of Ser-126, His-147, His-217, and Arg-250 through the kinetic analysis of site-directed mutants and structural analysis of the co-crystal complexes. To understand the role of active site residues in substrate selectivity, comparative structural analysis of AD and PD was also conducted. The current study provides a basis for understanding the mechanism of substrate selectivity between the different classes of TyrA enzymes and details how A. aeolicus PD can accept prephenate as substrate and l-tyrosine as a competitive inhibitor.     

Phenylalanine biosynthesis in Arabidopsis thaliana. Identification and characterization of arogenate dehydratases

There is much uncertainty as to whether plants use arogenate, phenylpyruvate, or both as obligatory intermediates in Phe biosynthesis, an essential dietary amino acid for humans. This is because both prephenate and arogenate have been reported to undergo decarboxylative dehydration in plants via the action of either arogenate (ADT) or prephenate (PDT) dehydratases; however, neither enzyme(s) nor encoding gene(s) have been isolated and/or functionally characterized. An in silico data mining approach was thus undertaken to attempt to identify the dehydratase(s) involved in Phe formation in Arabidopsis, based on sequence similarity of PDT-like and ACT-like domains in bacteria. This data mining approach suggested that there are six PDT-like homologues in Arabidopsis, whose phylogenetic analyses separated them into three distinct subgroups. All six genes were cloned and subsequently established to be expressed in all tissues examined. Each was then expressed as a Nus fusion recombinant protein in Escherichia coli, with their substrate specificities measured in vitro. Three of the resulting recombinant proteins, encoded by ADT1 (At1g11790), ADT2 (At3g07630), and ADT6 (At1g08250), more efficiently utilized arogenate than prephenate, whereas the remaining three, ADT3 (At2g27820), ADT4 (At3g44720), and ADT5 (At5g22630) essentially only employed arogenate. ADT1, ADT2, and ADT6 had k(cat)/Km values of 1050, 7650, and 1560 M(-1) S(-1) for arogenate versus 38, 240, and 16 M(-1) S(-1) for prephenate, respectively. By contrast, the remaining three, ADT3, ADT4, and ADT5, had k(cat)/Km values of 1140, 490, and 620 M(-1) S(-1), with prephenate not serving as a substrate unless excess recombinant protein (>150 microg/assay) was used. All six genes, and their corresponding proteins, are thus provisionally classified as arogenate dehydratases and designated ADT1-ADT6.     

Synthesis of chiral arogenic acid via immobilized microbial proteins

Although l-(8S)-arogenate has been recognized as a potential precursor of l-phenylalanine or l-tyrosine biosynthesis for only a few years, it is widely distributed in nature. The biochemical formation of arogenate has involved its isolation from the culture supernatant of a mutant strain of Neurospora crassa, a lengthy procedure of 20-day duration. We now report an improved approach using immobilized crude enzyme extracts from a cyanobacterium. The starting materials, chorismic acid or prephenic acid, are readily available, and overall yields ranging from 40 to 60% are obtained. The whole procedure takes only 1 day. Crude, unfractionated enzyme extracts from Synechocystis sp. ATCC 29108 are immobilized on a phenoxyacetyl cellulose solid support. The hydrophobic binding of the extract proteins did not denature chorismate mutase or prephenate aminotransferase, the enzymes catalyzing the conversion of chorismate to prephenate and prephenate to arogenate, respectively. This microbial system was ideally suited for preparation of arogenate, since other enzyme activities which might compete for prephenate or chorismate as substrates, or which might further metabolize arogenate, were absent or inactive under the conditions used. In addition to the substrates prephenate or chorismate, pyridoxal-5′-phosphate (the coenzyme required for transamination), as well as leucine (amino donor for transamination of prephenate), was added. The reaction product, arogenate, was separated from the starting materials by preparative thin-layer chromatography.     

Terminal phenylalanine and tyrosine biosynthesis of Microtetraspora glauca

The enzymes of the terminal steps of the phenylalanine and tyrosine biosynthesis were partially purified and characterized in Microtetraspora glauca, a spore-forming member of the order Actinomycetales. This bacterium relies exclusively on the phenylpyruvate route for phenylalanine synthesis, no arogenate dehydratase activity being found. Prephenate dehydratase is subject to feedback inhibition by phenylalanine, tyrosine and tryptophan, each acting as competitive inhibitor by increasing the Km of 72 microM for prephenate. Based on the results of gel chromatography on Sephadex G-200, the molecular mass of about 110,000 Da is not altered by any of the effectors. The enzyme is quite sensitive to inhibition by 4-hydroxymercuribenzoate. Microtetraspora glauca can utilize arogenate and 4-hydroxyphenylpyruvate as intermediates in tyrosine biosynthesis. Prephenate and arogenate dehydrogenase activities copurifying from ion exchange columns with coincident profiles were detected. From gel-filtration columns the two activities eluted at an identical molecular-mass position of about 68,000 Da. The existence of a single protein exhibiting substrate ambiguity is consistent with the findings, that both dehydrogenases have similar chromatographic properties, exhibit cofactor requirement for NAD and are inhibited to the same extent by tyrosine and 4-hydroxymercuribenzoate.     

Clues fromXanthomonas campestris about the evolution of aromatic biosynthesis and its regulation

Summary The recent placement of major Gramnegative prokaryotes (Superfamily B) on a phylogenetic tree (including, e.g., lineages leading toEscherichia coli, Pseudomonas aeruginosa, andAcinetobacter calcoaceticus) has allowed initial insights into the evolution of the biochemical pathway for aromatic amino acid biosynthesis and its regulation to be obtained. Within this prokaryote grouping,Xanthomonas campestris ATCC 12612 (a representative of the Group V pseudomonads) has played a key role in facilitating deductions about the major evolutionary events that shaped the character of aromatic biosynthesis within this grouping.X. campestris is likeP. aeruginosa (and unlikeE. coli) in its possession of dual flow routes to bothl-phenylalanine andl-tyrosine from prephenate. Like all other members of Superfamily B,X. campestris possesses a bifunctional P-protein bearing the activities of both chorismate mutase and prephenate dehydratase. We have found an unregulated arogenate dehydratase similar to that ofP. aeruginosa inX. campestris. We separated the two tyrosine-branch dehydrogenase activities (prephenate dehydrogenase and arogenate dehydrogenase); this marks the first time this has been accomplished in an organism in which these two activities coexist. Superfamily B organisms possess 3-deoxy-d-arabino-heptulosonate 7-P (DAHP) synthase as three isozymes (e.g., inE. coli), as two isozymes (e.g., inP. aeruginosa), or as one enzyme (inX. campestris). The two-isozyme system has been deduced to correspond to the ancestral state of Superfamily B. Thus,E. coli has gained an isozyme, whereasX. campestris has lost one. We conclude that the single, chorismate-sensitive DAHP synthase enzyme ofX. campestris is evolutionarily related to the tryptophan-sensitive DAHP synthase present throughout the rest of Superfamily B. InX. campestris, arogenate dehydrogenase, prephenate dehydrogenase, the P-protein, chorismate mutase-F, anthranilate synthase, and DAHP synthase are all allosteric proteins; we compared their regulatory properties with those of enzymes of other Superfamily B members with respect to the evolution of regulatory properties. The network of sequentially operating circuits of allosteric control that exists for feedback regulation of overall carbon flow through the aromatic pathway inX. campestris is thus far unique in nature.     

Purification of arogenate dehydrogenase from Phenylobacterium immobile

Phenylobacterium immobile, a bacterium which is able to degrade the herbicide chloridazon, utilizes for L-tyrosine synthesis arogenate as an obligatory intermediate which is converted in the final biosynthetic step by a dehydrogenase to tyrosine. This enzyme, the arogenate dehydrogenase, has been purified for the first time in a 5-step procedure to homogeneity as confirmed by electrophoresis. The Mr of the enzyme that consists of two identical subunits amounts to 69000 as established by gel electrophoresis after cross-linking the enzyme with dimethylsuberimidate. The Km values were 0.09 mM for arogenate and 0.02 mM for NAD+. The enzyme has a high specificity with respect to its substrate arogenate.     

Structural analysis of a 3-deoxy-D-arabino-heptulosonate 7-phosphate synthase with an N-terminal chorismate mutase-like regulatory domain

3-Deoxy-D-arabino-heptulosonate 7-phosphate synthase (DAHPS) catalyzes the first step in the biosynthesis of a number of aromatic metabolites. Likely because this reaction is situated at a pivotal biosynthetic gateway, several DAHPS classes distinguished by distinct mechanisms of allosteric regulation have independently evolved. One class of DAHPSs contains a regulatory domain with sequence homology to chorismate mutase-an enzyme further downstream of DAHPS that catalyzes the first committed step in tyrosine/phenylalanine biosynthesis-and is inhibited by chorismate mutase substrate (chorismate) and product (prephenate). Described in this work, structures of the Listeria monocytogenes chorismate/prephenate regulated DAHPS in complex with Mn(2+) and Mn(2+) + phosphoenolpyruvate reveal an unusual quaternary architecture: DAHPS domains assemble as a tetramer, from either side of which chorismate mutase-like (CML) regulatory domains asymmetrically emerge to form a pair of dimers. This domain organization suggests that chorismate/prephenate binding promotes a stable interaction between the discrete regulatory and catalytic domains and supports a mechanism of allosteric inhibition similar to tyrosine/phenylalanine control of a related DAHPS class. We argue that the structural similarity of chorismate mutase enzyme and CML regulatory domain provides a unique opportunity for the design of a multitarget antibacterial.     

Enzymology of l-Tyrosine Biosynthesis in Mung Bean (Vigna radiata [L.] Wilczek)

The enzymes of the 4-hydroxyphenylpyruvate (prephenate dehydrogenase and 4-hydroxyphenylpyruvate aminotransferase) and pretyrosine (prephenate aminotransferase and pretyrosine dehydrogenase) pathways of l-tyrosine biosynthesis were partially purified from mung bean (Vigna radiata [L.] Wilczek) seedlings. NADP-dependent prephenate dehydrogenase and pretyrosine dehydrogenase activities coeluted from ion exchange, adsorption, and gel-filtration columns, suggesting that a single protein (52,000 daltons) catalyzes both reactions. The ratio of the activities of partially purified prephenate to pretyrosine dehydrogenase was constant during all purification steps as well as after partial inactivation caused by p-hydroxymercuribenzoic acid or heat. The activity of prephenate dehydrogenase, but not of pretyrosine dehydrogenase, was inhibited by l-tyrosine at nonsaturating levels of substrate. The K(m) values for prephenate and pretyrosine were similar, but the specific activity with prephenate was 2.9 times greater than with pretyrosine.Two peaks of aromatic aminotransferase activity utilizing l-glutamate or l-aspartate as amino donors and 4-hydroxyphenylpyruvate, phenylpyruvate, and/or prephenate as keto acid substrates were eluted from DEAE-cellulose. Of the three keto acid substrates, 4-hydroxyphenylpyruvate was preferentially utilized by 4-hydroxyphenylpyruvate aminotransferase whereas prephenate was best utilized by prephenate aminotransferase. The identity of a product of prephenate aminotransferase as pretyrosine following reaction with prephenate was established by thin layer chromatography of the dansyl-derivative.     

Phylobiochemical Characterization of Class-Ib Aspartate/Prephenate Aminotransferases Reveals Evolution of the Plant Arogenate Phenylalanine Pathway

The aromatic amino acid Phe is required for protein synthesis and serves as the precursor of abundant phenylpropanoid plant natural products. While Phe is synthesized from prephenate exclusively via a phenylpyruvate intermediate in model microbes, the alternative pathway via arogenate is predominant in plant Phe biosynthesis. However, the molecular and biochemical evolution of the plant arogenate pathway is currently unknown. Here, we conducted phylogenetically informed biochemical characterization of prephenate aminotransferases (PPA-ATs) that belong to class-Ib aspartate aminotransferases (AspAT Ibs) and catalyze the first committed step of the arogenate pathway in plants. Plant PPA-ATs and succeeding arogenate dehydratases (ADTs) were found to be most closely related to homologs from Chlorobi/Bacteroidetes bacteria. The Chlorobium tepidum PPA-AT and ADT homologs indeed efficiently converted prephenate and arogenate into arogenate and Phe, respectively. A subset of AspAT Ib enzymes exhibiting PPA-AT activity was further identified from both Plantae and prokaryotes and, together with site-directed mutagenesis, showed that Thr-84 and Lys-169 play key roles in specific recognition of dicarboxylic keto (prephenate) and amino (aspartate) acid substrates. The results suggest that, along with ADT, a gene encoding prephenate-specific PPA-AT was transferred from a Chlorobi/Bacteroidetes ancestor to a eukaryotic ancestor of Plantae, allowing efficient Phe and phenylpropanoid production via arogenate in plants today.     

A monofunctional prephenate dehydrogenase created by cleavage of the 5' 109 bp of the tyrA gene from Erwinia herbicola.

A cohesive phylogenetic cluster that is limited to enteric bacteria and a few closely related genera possesses a bifunctional protein that is known as the T-protein and is encoded by tyrA. The T-protein carries catalytic domains for chorismate mutase and for cyclohexadienyl dehydrogenase. Cyclohexadienyl dehydrogenase can utilize prephenate or L-arogenate as alternative substrates. A portion of the tyr A gene cloned from Erwinia herbicola was deleted in vitro with exonuclease III and fused in-frame with a 5' portion of lacZ to yield a new gene, denoted tyrA*, in which 37 N-terminal amino acids of the T-protein are replaced by 18 amino acids encoded by the polycloning site/5' portion of the lacZ alpha-peptide of pUC19. The TyrA* protein retained dehydrogenase activity but lacked mutase activity, thus demonstrating the separability of the two catalytic domains. While the Km of the TyrA* dehydrogenase for NAD+ remained unaltered, the Km for prephenate was fourfold greater and the Vmax was almost twofold greater than observed for the parental T-protein dehydrogenase. Activity with L-arogenate, normally a relatively poor substrate, was reduced to a negligible level. The prephenate dehydrogenase activity encoded by tyrA* was hypersensitive to feedback inhibition by L-tyrosine (a competitive inhibitor with respect to prephenate), partly because the affinity for prephenate was reduced and partly because the Ki value for L-tyrosine was decreased from 66 microM to 14 microM. Thus, excision of a portion of the chorismate mutase domain is shown to result in multiple extra-domain effects upon the cyclohexadienyl dehydrogenase domain of the bifunctional protein.(ABSTRACT TRUNCATED AT 250 WORDS)