Absolute dependence of phenylalanine and tyrosine biosynthetic enzyme on tryptophan in Candida maltosa

Candida maltosa synthesizes phenylalanine and tyrosine only via phenylpyruvate and p-hydroxyphenylpyruvate. Tryptophan is absolutely necessary for the enzymatic reaction of chorismate mutase and prephenate dehydrogenase; activity of prephenate dehydratase can be increased 2.5-fold in the presence of tryptophan. Activation of the chorismate mutase, prephenate dehydratase and prephenate dehydrogenase by tryptophan is competitive with respect to chorismate and prephenate with Ka 0.06mM, 0.56mM and 1.7mM. In addition tyrosine is a competitive inhibitor of chorismate mutase (Ki = 0.55mM) and prephenate dehydrogenase (Ki = 5.5mM).     

Kinetic studies on the mechanism of chorismate mutase/prephenate dehydratase from Escherichia coli K12

The effect of pH on chorismate mutase/prephenate dehydratase (chorismate pyruvate mutase/prephenate hydro-lyase (decarboxylating) EC 5.4.99.5/EC 4.2.1.51) from Escherichia coli K12 has been studied. While the maximum velocity of both activities is independent of pH, Km for chorismate or prephenate shows a complex pH dependence. Differences in mutase activity in acetate/phosphate/borate and citrate/phosphate/borate buffers were traced to inhibition by citrate. When a variety of analogues of citrate were tested as possible inhibitors of the enzyme, several were found to inhibit mutase and dehydratase activities to different extents, and by different mechanisms. Thus citrate competitively inhibits mutase activity, but inhibits dehydratase activity by either a non-competitive or an uncompetitive mechanism. Conversely, cis- and trans-aconitate competitively inhibit dehydratase activity, but are partially competitive inhibitors of mutase activity. The differential effects of these inhibitors on the two activities are consistent with the existence of two distinct active sites, but additionally suggest some degree of interconnection between them. The implications of these results for possible mechanisms of catalysis by chorismate mutase/prephenate dehydratase are discussed.     

Chorismate mutase-prephenate dehydratase from Escherichia coli: active sites of a bifunctional enzyme.

The relationship between the active sites of the bifunctional enzyme chorismate mutase-prephenate dehydratase has been examined. Steady-state kinetic investigations of the reactions with chorismate or prephenate as substrate and studies of the overall conversion of chorismate to phenylpyruvate indicate that there are two distinct active sites. One site is responsible for the mutase activity and the other for the dehydratase activity. Studies of the overall reaction using radioactive chorismate show that prephenate, which is formed from chorismate, dissociates from the mutase site and equilibrates with the bulk medium before combining at the dehydratase site. No evidence was obtained for direct channeling of prephenate from one site to the other, or for any strong interaction between the sites.     

Relationships Among Mycobacteria and Nocardiae Based upon Deoxyribonucleic Acid Reassociation

Chorismate mutase from Streptomyces aureofaciens was purified 12-fold. This enzyme preparation did not show any activity when tested for anthranilate synthetase, prephenate dehydrogenase, or prephenate dehydratase. The catalytic activity of chorismate mutase has a broad optimum between pH 7 and 8. The initial velocity data followed regular Michaelis-Menten kinetics with a K(m) of 5.3 x 10(-4) M, and the molecular weight of the enzyme was determined by sucrose gradient centrifugation to be 50,000. Heat inactivation of chorismate mutase, which occurs above temperatures of 60 C, is reversible. The enzyme activity can be restored even when chorismate mutase is treated at the temperature of a boiling-water bath for 15 min. Heat-denatured and renatured enzymes showed the same Michaelis constant and the same molecular weight as the native enzyme. l-Phenylalanine, l-tyrosine, l-tryptophan, and metabolites of the aromatic amino acid pathway were tested as potential modifiers of chorismate mutase activity. The activity of the enzyme was inhibited by none of these substances. Chorismate mutase of S. aureofaciens was not repressed in cells grown in minimal medium supplemented with l-phenylalanine, l-tyrosine, or l-tryptophan.     

Chorismate mutase-prephenate dehydrogenase from Aerobacter aerogenes: evidence that the two reactions occur at one active site.

The relationship between the sites for catalysis of two reactions by the bifunctional enzyme chorismate mutase--prephenate dehydrogenase has been investigated. The results are consistent with the occurrence of both reactions at one active site. Comparisons have been made between experimental data for the time course of the overall reaction and computer simulations, according to various models for the relationship between the mutase and dehydrogenase sites. A model based on a single active site is consistent with the time course data if a minor proportion of the chorismate that reacts can be converted through to (hydroxyphenyl)pyruvate without the intermediate release of prephenate. Consistent with this requirement, some channeling of radioactivity from chorismate to (hydroxyphenyl)pyruvate has been detected. A model based on two separate sites has also been considered; the simulations show that if this model applies there is no need to postulate any channeling of the intermediate, prephenate, between the sites and there must be marked inhibition of the dehydrogenase reaction by chorismate. Since channeling has been observed and chorismate increases the dehydrogenase rate under all conditions, the two-site model appears unlikely. Consistent with the one-site model are the observations that a variety of inactivating conditions cause parallel loss of mutase and dehydrogenase activity and that identical protection against inactivation of both mutase and dehydrogenase by iodoacetamide is afforded by prephenate.     

基于结构域活性分析的大肠杆菌T蛋白结构研究

大肠杆菌T蛋白含有三个结构域:分支酸变位酶、预苯酸脱氢酶和调节结构域。文章作者分段克隆了T蛋白的分支酸变位酶、预苯酸脱氢酶和调节结构域等片段,并对其进行了活性研究。研究发现,定位于N末端的分支酸变位酶结构域的比活性虽然不高,而稳定性较好;同时拥有调节结构域和预苯酸脱氢酶结构域的C末端片段,其预苯酸脱氢酶比活性的剩余百分率虽然高于分支酸变位酶结构域,但稳定性较差。作者进而表达了C末端切除38个氨基酸的T/1-336片段,发现预苯酸脱氢酶活性彻底丧失,而其分支酸变位酶和调节结构域的活性却基本保留。这说明T蛋白中分支酸变位酶结构域拥有一个相对独立、完整的结构,而预苯酸脱氢酶结构域和调节结构域交织共存,结构松散。     

Monofunctional chorismate mutase from Bacillus subtilis: kinetic and 13C NMR studies on the interactions of the enzyme with its ligands

The interaction of the monofunctional chorismate mutase from Bacillus subtilis with chorismate and prephenate has been studied kinetically and by NMR spectroscopy with 13C specifically labeled substrates. Prephenate dominates the population of enzyme-bound species, and the "off" rate constant (approximately 60 s-1) obtained from line-broadening experiments is close to the value of kcat for chorismate (50 s-1) determined kinetically. The calculated "on" rate constant for prephenate (8 x 10(5) M-1 s-1) is similar to the value of kcat/Km for chorismate (5 x 10(5) M-1 s-1). The kinetic parameters of the Bacillus mutase are remarkably insensitive to pH over a wide range and display no solvent isotope effect. These results suggest that the enzyme-catalyzed reaction may be encounter controlled (slowed from the diffusion limit by some feature of the enzyme's active site) and that kcat for chorismate is determined by the product off rate. There is now no evidence to suggest that the skeletal rearrangement on the enzyme surface occurs by a pathway other than a pericyclic process.     

Chorismate mutase-prephenate dehydrogenase from Escherichia coli: spatial relationship of the mutase and dehydrogenase sites

The inhibition of the bifunctional enzyme chorismate mutase-prephenate dehydrogenase (4-hydroxyphenylpyruvate synthase) by substrate analogues has been investigated at pH 6.0 with the aim of elucidating the spatial relationship that exists between the sites at which each reaction occurs. Several chorismate and adamantane derivatives, as well as 2-hydroxyphenyl acetate and diethyl malonate, act as linear competitive inhibitors with respect to chorismate in the mutase reaction and with respect to chorismate in the mutase reaction and with respect to prephenate in the dehydrogenase reaction. The similarity of the dissociation constants for the interaction of these compounds with the free enzyme, as determined from the mutase and dehydrogenase reactions, indicates that the reaction of these inhibitors at a single site prevents the binding of both chorismate and prephenate. However, not all the groups on the enzyme, which are responsible for the binding of these two substrates, can be identical. At lower concentrations, citrate or malonate prevents reaction of the enzyme with prephenate, but not with chorismate. Nevertheless, the combining sites for chorismate and prephenate are in such close proximity that the diethyl derivative of malonate prevents the binding of both substrates. The results lead to the proposal that the sites at which chorismate and prephenate react on hydroxyphenylpyruvate synthase share common features and can be considered to overlap.     

Enzyme Alterations in Tyrosine and Phenylalanine Auxotrophs of Salmonella typhimurium

The enzyme activities specified by the tyrA and pheA genes were studied in wildtype strain Salmonella typhimurium and in phenylalanine and tyrosine auxotrophs. As in Aerobacter aerogenes and Escherichia coli, the wild-type enzymes of Salmonella catalyze two consecutive reactions: chorismate --> prephenate --> 4-hydroxy-phenylpyruvate (tyrA), and chorismate --> prephenate --> phenylpyruvate (pheA). A group of tyrA mutants capable of interallelic complementation had altered enzymes which retained chorismate mutase T activity but lacked prephenate dehydrogenase. Similarly, pheA mutants (in which interallelic complementation does not occur) had one group with altered enzymes which retained chorismate mutase P but lacked prephenate dehydratase. Tyrosine and phenylalanine auxotrophs outside of these categories showed loss of both activities of their respective bifunctional enzyme. TyrA mutants which had mutase T were considerably derepressed in this activity by tyrosine starvation and consequently excreted prephenate. A new and specific procedure was developed for assaying prephenate dehydrogenase activity.     

A kinetic and structural comparison of chorismate mutase/prephenate dehydratase from mutant strains of Escherichia coli K12 defective in the PheA gene

Three classes of mutant strains of Escherichia coli K12 defective in pheA, the gene coding for chorismate mutase/prephenate dehydratase, have been isolated: (1) those lacking prephenate dehydratase activity, (2) those lacking chorismate mutase activity, and (3) those lacking both activities. Chorismate mutase/prephenate dehydratase from the second class of mutants was less sensitive to inhibition by phenylalanine than wild-type enzyme and, along with the defective enzyme from the third class of mutants, could not be purified by affinity chromatography on Sepharosyl-phenylalanine. Pure chorismate mutase/prephenate dehydratase protein was prepared from two strains belonging to the first class. The chorismate mutase activity of these enzymes is kinetically similar to that of the wild-type enzyme except for a two- to threefold increase in both the K_a for chorismate and the K_is for inhibition by prephenate. In both cases only one change in the tryptic fingerprint was detected, resulting from a substitution of the threonine residue in the peptide Gln·Asn·Phe·Thr·Arg. This suggests that this residue is catalytically or structurally essential for the dehydratase activity.     

Purified recombinant hypothetical protein coded by open reading frame Rv1885c of Mycobacterium tuberculosis exhibits a monofunctional AroQ class of periplasmic chorismate mutase activity

Naturally occurring variants of the enzyme chorismate mutase are known to exist that exhibit diversity in enzyme structure, regulatory properties, and association with other proteins. Chorismate mutase was not annotated in the initial genome sequence of Mycobacterium tuberculosis (Mtb) because of low sequence similarity between known chorismate mutases. Recombinant protein coded by open reading frame Rv1885c of Mtb exhibited chorismate mutase activity in vitro. Biochemical and biophysical characterization of the recombinant protein suggests its resemblance to the AroQ class of chorismate mutases, prototype examples of which include the Escherichia coli and yeast chorismate mutases. We also demonstrate that unlike the corresponding proteins of E. coli, Mtb chorismate mutase does not have any associated prephenate dehydratase or dehydrogenase activity, indicating its monofunctional nature. The Rv1885c-encoded chorismate mutase showed allosteric regulation by pathway-specific as well as cross-pathway-specific ligands, as evident from proteolytic cleavage protection and enzyme assays. The predicted N-terminal signal sequence of Mtb chorismate mutase was capable of functioning as one in E. coli, suggesting that Mtb chorismate mutase belongs to the AroQ class of chorismate mutases. It was evident that Rv1885c may not be the only enzyme with chorismate mutase enzyme function within Mtb, based on our observation of the presence of chorismate mutase activity displayed by another hypothetical protein coded by open reading frame Rv0948c, a novel instance of the existence of two monofunctional chorismate mutases ever reported in any pathogenic bacterium.     

Exploration of swapping enzymatic function between two proteins: A simulation study of chorismate mutase and isochorismate pyruvate lyase

The enzyme chorismate mutase EcCM from Escherichia coli catalyzes one of the few pericyclic reactions in biology, the transformation of chorismate to prephenate. The isochorismate pyruvate lyase PchB from Pseudomonas aeroginosa catalyzes another pericyclic reaction, the isochorismate to salicylate transformation. Interestingly, PchB possesses weak chorismate mutase activity as well thus being able to catalyze two distinct pericyclic reactions in a single active site. EcCM and PchB possess very similar folds, despite their low sequence identity. Using molecular dynamics simulations of four combinations of the two enzymes (EcCM and PchB) with the two substrates (chorismate and isochorismate) we show that the electrostatic field due to EcCM at atoms of chorismate favors the chorismate to prephenate transition and that, analogously, the electrostatic field due to PchB at atoms of isochorismate favors the isochorismate to salicylate transition. The largest differences between EcCM and PchB in electrostatic field strengths at atoms of the substrates are found to be due to residue side chains at distances between 0.6 and 0.8 nm from particular substrate atoms. Both enzymes tend to bring their non‐native substrate in the same conformation as their native substrate. EcCM and to a lower extent PchB fail in influencing the forces on and conformations of the substrate such as to favor the other chemical reaction (isochorismate pyruvate lyase activity for EcCM and chorismate mutase activity for PchB). These observations might explain the difficulty of engineering isochorismate pyruvate lyase activity in EcCM by solely mutating active site residues.     

Redesign of MST enzymes to target lyase activity instead promotes mutase and dehydratase activities

The isochorismate and salicylate synthases are members of the MST family of enzymes. The isochorismate synthases establish an equilibrium for the conversion chorismate to isochorismate and the reverse reaction. The salicylate synthases convert chorismate to salicylate with an isochorismate intermediate; therefore, the salicylate synthases perform isochorismate synthase and isochorismate-pyruvate lyase activities sequentially. While the active site residues are highly conserved, there are two sites that show trends for lyase-activity and lyase-deficiency. Using steady state kinetics and HPLC progress curves, we tested the “interchange” hypothesis that interconversion of the amino acids at these sites would promote lyase activity in the isochorismate synthases and remove lyase activity from the salicylate synthases. An alternative, “permute” hypothesis, that chorismate-utilizing enzymes are designed to permute the substrate into a variety of products and tampering with the active site may lead to identification of adventitious activities, is tested by more sensitive NMR time course experiments. The latter hypothesis held true. The variant enzymes predominantly catalyzed chorismate mutase–prephenate dehydratase activities, sequentially generating prephenate and phenylpyruvate, augmenting previously debated (mutase) or undocumented (dehydratase) adventitious activities.     

Probing the overlap of chorismate mutase and prephenate dehydrogenase sites in the escherichia coli T-protein: a dehydrogenase-selective inhibitor

An inhibitor of prephenate dehydrogenase has been identified that has no effect on the chorismate mutase activity in the Escherichia coli T-protein, thus supporting the idea of two separate active sites.     

Enzyme-enzyme interaction and the biosynthesis of aromatic amino acids in Escherichia coli.

The technique of affinity chromatography has been used to demonstrate that enzymes involved in the biosynthesis of tyrosine and phenylalanine in Escherichia coli undergo reversible interactions. Thus it has been shown that the aromatic amino acid aminotransferase (aromatic-amino-acid: 2-oxoglutarate amino-transferase, EC 2.6.1.57) reacts specifically with chorismate mutaseprephenate dehydrogenase (chorismate pyruvate mutase, EC 5.4.99.5 and prephenate: NAD+ oxidoreductase (decarboxylating), EC 1.3.1.12) in the absence of reactants and with chorimate mutase-prephenatedehydratase (prephenate hydro-lyase (decarboxylating), EC 4.2.1.51) in the presence of phyenylpyruvate. Tyrosine causes dissociation of the aminotransferase: mutasedehydrogenase complex while dissociation of the aminotransferase-mutasedehydratase complex occurs on omission of phenylpyruvate. Only the active form of chorismate mutase-prephenate dehydrogenase participates in complex formation.     

Bacillus subtilis chorismate mutase is partially diffusion-controlled.

The effect of viscosogens on the enzyme-catalyzed rearrangement of chorismate to prephenate has been studied. The steady-state parameters kcat and kcat/Km for the monofunctional chorismate mutase from Bacillus subtilis (BsCM) decreased significantly with increasing concentrations of glycerol, whereas the 'sluggish' BsCM mutants C75A and C75S were insensitive to changes in microviscosity. The latter results rule out extraneous interactions of the viscosogen as an explanation for the effects observed with the wild-type enzyme. Additional control experiments show that neither viscosogen-induced shifts in the pH-dependence of the enzyme-catalyzed reaction nor small perturbations of the conformational equilibrium of chorismate can account for the observed effects. Instead, BsCM appears to be limited by substrate binding and product release at low and high substrate concentrations, respectively. Analysis of the kinetic data indicates that diffusive transition states are between 30 and 40% rate-determining in these concentration regimes; the chemical step must contribute to the remaining kinetic barrier. The relatively low value of the 'on' rates for chorismate and prephenate (approximately 2 x 106 m-1.s-1) probably reflects the need for a rare conformation of the enzyme, the ligand, or both for successful binding. Interestingly, the chorismate mutase domain of the bifunctional chorismate mutase-prephenate dehydratase from Escherichia coli, which has steady-state kinetic parameters comparable to those of BsCM but has a much less accessible active site, is insensitive to changes in viscosity and the reaction it catalyses is not diffusion-controlled.     

Design, synthesis, and evaluation of aza inhibitors of chorismate mutase

A series of aza inhibitors (4-9) of chorismate mutase (E.C. 5.4.99.5) was designed, prepared, and evaluated against the enzyme by monitoring the direct inhibition of the chorismate, 1, to prephenate, 2, conversion. None of these aza inhibitors displayed tighter binding to the enzyme than the native substrate chorismate or greater inhibitory action than the previously reported ether analogue, 3. Furthermore, no time-dependent loss of enzyme activity was observed in the presence of the two potentially reactive aza inhibitors (7 and 9). These results in conjunction with inhibition data from a broader series of chorismate mutase inhibitors allowed a novel proposal for the mechanistic role of chorismate mutase to be developed. This proposed mechanism was computationally verified and correlated with crystallographic studies of various chorismate mutases.