Evidence for two distinct effector-binding sites in threonine deaminase by site-directed mutagenesis, kinetic, and binding experiments

A three-dimensional structure comparison between the dimeric regulatory serine-binding domain of Escherichia coli D-3-phosphoglycerate dehydrogenase [Schuller, D. J., Grant, G. A., and Banaszak, L. J. (1995) Nat. Struct. Biol. 2, 69-76] and the regulatory domain of E. coli threonine deaminase [Gallagher, D. T., Gilliland, G. L., Xiao, G., Zondlo, J., Fisher, K. E., Chinchilla, D. , and Eisenstein, E. (1998) Structure 6, 465-475] led us to make the hypothesis that threonine deaminase could have two binding sites per monomer. To test this hypothesis about the corresponding plant enzyme, site-directed mutagenesis was carried out on the recombinant Arabidopsis thaliana threonine deaminase. Kinetic and binding experiments demonstrated for the first time that each regulatory domain of the monomers of A. thaliana threonine deaminase possesses two different effector-binding sites constituted in part by Y449 and Y543. Our results demonstrate that Y449 belongs to a high-affinity binding site whose interaction with a first isoleucine induces conformational modifications yielding a conformer displaying a higher activity and with enhanced ability to bind a second isoleucine on a lower-affinity binding site containing Y543. Isoleucine interaction with this latter binding site is responsible for conformational modifications leading to final inhibition of the enzyme. Y449 interacts with both regulators, isoleucine and valine. However, interaction of valine with the high-affinity binding site induces different conformational modifications leading to reversal of isoleucine binding and reversal of inhibition.     

An efficient approach to identify ilvA mutations reveals an amino-terminal catalytic domain in biosynthetic threonine deaminase from Escherichia coli.

High-level expression of the regulatory enzyme threonine deaminase in Escherichia coli strains grown on minimal medium that are deficient in the activities of enzymes needed for branched-chain amino acid biosynthesis result in growth inhibition, possibly because of the accumulation of toxic levels of alpha-ketobutyrate, the product of the committed step in isoleucine biosynthesis. This condition affords a means for selecting genetic variants of threonine deaminase that are deficient in catalysis by suppression of growth inhibition. Strains harboring mutations in ilvA that decreased the catalytic activity of threonine deaminase were found to grow more rapidly than isogenic strains containing wild-type ilvA. Modification of the ilvA gene to introduce additional unique, evenly spaced restriction enzyme sites facilitated the identification of suppressor mutations by enabling small DNA fragments to be subcloned for sequencing. The 10 mutations identified in ilvA code for enzymes with significantly reduced activity relative to that of wild-type threonine deaminase. Values for their specific activities range from 40% of that displayed by wild-type enzyme to complete inactivation as evidenced by failure to complement an ilvA deletion strain to isoleucine prototrophy. Moreover, some mutant enzymes showed altered allosteric properties with respect to valine activation and isoleucine inhibition. The location of the 10 mutations in the 5' two-thirds of the ilvA gene is consistent with suggestions that threonine deaminase is organized functionally with an amino-terminal domain that is involved in catalysis and a carboxy-terminal domain that is important for regulation.     

Biochemical and mass spectrometric evidence for quaternary structure modifications of plant threonine deaminase induced by isoleucine

Arabidopsis thaliana threonine deaminase (TD) is a tetramer composed of identical approximately 59600 Da subunits. TD activity has been shown to be inhibited by isoleucine. This effect is reversed by a large excess of valine. Nondenaturant gel filtration, polyacrylamide gel electrophoresis, and mass spectrometry experiments demonstrated that binding of isoleucine on TD induces dimerization of the enzyme, whereas tetramerization is restored by addition of a high valine concentration. Nondenaturant gel filtration and electrospray ionization mass spectrometry of the enzyme in the presence of increasing amounts of isoleucine suggest a fast equilibrium between the tetramer and the dimer. Finally, study of TD mutants allowed us to focus on the specific role of each isoleucine-binding site.     

Cloning, expression, purification, and characterization of biosynthetic threonine deaminase from Escherichia coli

Feedback inhibition of the regulatory enzyme threonine deaminase by isoleucine provides an important level of enzymic control over branched chain amino acid biosynthesis in Escherichia coli. Cloning ilvA, the structural gene for threonine deaminase, under control of the trc promoter results in expression of active enzyme upon induction by isopropyl 1-thio-beta-D-galactoside to levels of approximately 20% of the soluble protein in cell extracts. High level expression of threonine deaminase has facilitated the development of a rapid and efficient protocol for the purification of gram quantities of enzyme with a specific activity 3-fold greater than previous preparations. The catalytic activity of threonine deaminase is absolutely dependent on the presence of pyridoxal phosphate, and the tetrameric molecule is isolated containing 1 mol of cofactor/56,000-Da chain. Wild-type threonine deaminase demonstrates a sigmoidal dependence of initial velocity on threonine concentration in the absence of isoleucine, consistent with a substrate-promoted conversion of the enzyme from a low activity to a high activity conformation. The enzymic dehydration of threonine to alpha-ketobutyrate measured by steady-state kinetics, performed at 20 degrees C in 0.05 M potassium phosphate, pH 7.5, is described by a Hill coefficient, nH, of 2.3 and a K0.5 of 8.0 mM. The negative allosteric effector L-isoleucine strongly inhibits the enzyme, yielding a value for nH of 3.9 and K0.5 of 74 mM whereas enzyme activity is greatly increased by L-valine, which yields nearly hyperbolic kinetics characterized by a value for nH of 1.0 and a K0.5 of 5.7 mM. Thus, these effectors promote dramatic and opposing effects on the transition from the low activity to the high activity conformation of the tetrameric enzyme.     

Biosynthesis of branched-chain amino acids in Schizosaccharomyces pombe: regulatory properties of threonine deaminase

Biosynthetic threonine deaminase (TD) from Schizosaccharomyces pombe has been partially purified from crude extracts by treatment with protamine sulfate, ammonium sulfate precipitation, and gel filtration through Sephadex G-25. In both crude extracts and purified preparations, TD showed marked stimulation by pyridoxal phosphate. A pH optimum for activity was found at pH 9.0, whereas the inhibition caused by the natural feedback inhibitor, l-isoleucine, was maximal at pH 7.4. l-Threonine exhibits homotropic cooperative effects at low pH (7.0-8.0), which are eliminated at pH 9.0, and the affinity for substrate (in terms of K(m)) increased with increasing pH. Enzyme activity could be completely inhibited by isoleucine over a pH range of 7.4 to 9.0; the amount of isoleucine required for 50% inhibition increased with increasing pH. Isoleucine inhibition was pseudocompetitive with respect to substrate and increased the cooperative effects of threonine. l-Valine was found to reverse isoleucine inhibition; it also activated the enzyme in a pH range of 7.0 to 8.0 by eliminating the cooperative effects of threonine, thus normalizing the substrate saturation curves at these pH values. l-Leucine was shown to be a competitive inhibitor with respect to threonine, and to be able partially to reverse isoleucine inhibition. Treatment of TD with mercurials did not result in desensitization to isoleucine inhibition. However, at pH 10, virtually no sensitivity of the enzyme to isoleucine was observed while activity remained strong, which suggests the existence of separate sites on the TD molecule for binding threonine and isoleucine. A tentative model is presented which unifies the kinetic results reported here in terms of the interactions of TD with its effector molecules.     

The Role of ACT-Like Subdomain in Bacterial Threonine Dehydratases

In bacteria, threonine dehydratases could convert L-threonine to 2-ketobutyrate. Some threonine dehydratases contain only a catalytic domain, while others contain an N-terminal catalytic domain and a C-terminal regulatory domain composed of one or two ACT-like subdomains. However, the role of the ACT-like subdomain in threonine dehydratases is not clear. Here, nine different bacterial threonine dehydratases were studied. Three of the nine contain no ACT-like subdomain, four of them contain a single ACT-like subdomain, and two of them contain two ACT-like subdomains. The nine genes encoding these threonine dehydratases were individually overexpressed in E. coli BL21(DE3), and the enzymes were purified to homogeneity. Activities of the purified enzymes were analyzed after incubation at different temperatures and different pHs. The results showed that threonine dehydratases with a single ACT-like subdomain are more stable at higher temperatures and a broad range of pH than those without ACT-like subdomain or with two ACT-like subdomains. Furthermore, the specific activity of threonine dehydratases increases with the increase of the number of ACT-like subdomains they contain. The results suggest that the ACT-like subdomain plays an important role in bacterial threonine dehydratases.     

Study and reengineering of the binding sites and allosteric regulation of biosynthetic threonine deaminase by isoleucine and valine in Escherichia coli

Biosynthetic threonine deaminase (TD) is a key enzyme for the synthesis of isoleucine which is allosterically inhibited and activated by Ile and Val, respectively. The binding sites of Ile and Val and the mechanism of their regulations in TD are not clear, but essential for a rational design of efficient productive strain(s) for Ile and related amino acids. In this study, structure-based computational approach and site-directed mutagenesis were combined to identify the potential binding sites of Ile and Val in Escherichia coli TD. Our results demonstrated that each regulatory domain of the TD monomer possesses two nonequivalent effector-binding sites. The residues R362, E442, G445, A446, Y369, I460, and S461 only interact with Ile while E347, G350, and F352 are involved not only in the Ile binding but also in the Val binding. By further considering enzyme kinetic data, we propose a concentration-dependent mechanism of the allosteric regulation of TD by Ile and Val. For the construction of Ile overproducing strain, a novel TD mutant with double mutation of F352A/R362F was also created, which showed both higher activity and much stronger resistance to Ile inhibition comparing to those of wild-type enzyme. Overexpression of this mutant TD in E. coli JW3591 significantly increased the production of ketobutyrate and Ile in comparison to the reference strains overexpressing wild-type TD or the catabolic threonine deaminase (TdcB). This work builds a solid basis for the reengineering of TD and related microorganisms for Ile production.     

Functional and structural analyses of threonine dehydratase from Corynebacterium glutamicum.

Threonine dehydratase activity is an important element in the flux control of isoleucine biosynthesis. The enzyme of Corynebacterium glutamicum demonstrates a marked sigmoidal dependence of initial velocity on the threonine concentration, a dependence that is consistent with substrate-promoted conversion of the enzyme from a low-activity to a high-activity conformation. In the presence of the negative allosteric effector isoleucine, the K0.5 increased from 21 to 78 mM and the cooperativity, as expressed by the Hill coefficient increased from 2.4 to 3.7. Valine promoted opposite effects: the K0.5 was reduced to 12 mM, and the enzyme exhibited almost no cooperativity. Sequence determination of the C. glutamicum gene for this enzyme revealed an open reading frame coding for a polypeptide of 436 amino acids. From this information and the molecular weight determination of the native enzyme, it follows that the dehydratase is a tetramer with a total mass of 186,396 daltons. Comparison of the deduced polypeptide sequence with the sequences of known threonine dehydratases revealed surprising differences from the C. glutamicum enzyme in the carboxy-terminal portion. This portion is greatly reduced in size, and a large gap of 95 amino acids must be introduced to achieve homology. Therefore, the C. glutamicum enzyme must be considered a small variant of threonine dehydratase that is typically controlled by isoleucine and valine but has an altered structure reflecting a topological difference in the portion of the protein most likely to be important for allosteric regulation.     

细菌苏氨酸脱水酶受L-异亮氨酸反馈抑制的关键在于其调控结构域

苏氨酸脱水酶是细菌L-异亮氨酸合成途径中的关键酶,酶活力受终产物L-异亮氨酸的反馈抑制。苏氨酸脱水酶包含催化结构域及调控结构域,其中调控结构域所起的作用有待进一步研究。本文在大肠杆菌中分别克隆表达了四种不同的苏氨酸脱水酶:来自谷氨酸棒杆菌的苏氨酸脱水酶CgIlvA及其不合调控结构域的突变体CgIlvA~M和来自大肠杆菌的苏氨酸脱水酶EcIlvA及其不合调控结构域的突变体EcIlvA~M。通过蛋白纯化和酶活分析发现,CgIlvA~M和EcIlvA~M的酶活力比CgIlvA和EcIlvA的酶活力有所降低,但它们不再受L-异亮氨酸的反馈抑制,说明L-异亮氨酸对苏氨酸脱水酶的反馈抑制是通过其调控结构域来实现的。     

Involvement of threonine deaminase in repression of the isoleucine-valine and leucine pathways in Saccharomyces cerevisiae

l-Threonine deaminase (l-threonine dehydratase [deaminating], EC 4.2.2.16) has been shown to be involved in the regulation of three of the enzymes of isoleucine-valine biosynthesis in yeast. Mutations affecting the affinity of the enzyme for isoleucine also affected the repression of acetohydroxyacid synthase, dihydroxyacid dehydrase, and reductoisomerase. The data indicate that isoleucine must be bound for effective repression of these enzymes to take place. In a strain with a nonsense mutation midway in liv 1, the gene for threonine deaminase, starvation for isoleucine or valine did not lead to derepression of the three enzymes; starvation for leucine did. The effect of the nonsense mutation is recessive; it is tentatively concluded, therefore, that intact threonine deaminase is required for derepression by two of the effectors for multivalent repression, but not by the third. A model is presented which proposes that a regulatory species of leu tRNA(leu) is the key intermediate for repression and that threonine deaminase is a positive element, regulating the available pool of charged leu tRNA by binding it.     

Isoleucine Auxotrophy Due to Feedback Hypersensitivity of Biosynthetic Threonine Deaminase

Isoleucine-deficient mutants of Salmonella typhimurium were isolated. Three groups of mutants can be discerned by their nutritional requirements and enzyme patterns. (i) Mutants which grow with isoleucine alone are devoid of biosynthetic threonine deaminase (TD). (ii) Mutants growing with isoleucine and valine are devoid of transaminase B. (iii) Mutants growing with either isoleucine or threonine have normal levels of TD. However, the sensitivity of this enzyme to feedback inhibition by isoleucine is greatly enhanced. The inhibitory effect of isoleucine can be counterbalanced by high concentrations of threonine. These results indicate that the production of isoleucine in the mutants is restricted to a low level not sufficient to support the growth of the cells. This hypothesis is confirmed by studies with revertants of an isoleucine-threonine mutant. In nine revertants, wild-type properties of TD have been restored. In four revertants, the hypersensitivity of TD is unchanged, but the strains produce a greatly enhanced quantity of threonine, which is excreted into the culture medium. It follows, that hypersensitivity of TD to inhibition by isoleucine is the cause of the nutritional requirement of isoleucine-threonine mutants.     

The ACT domain family

A novel ligand-binding domain, named the 'ACT domain', was recently identified by a PSI-BLAST search. The archetypical ACT domain is the C-terminal regulatory domain of 3-phosphoglycerate dehydrogenase (3PGDH), which folds with a ferredoxin-like betaalphabetabetaalphabeta topology. A pair of ACT domains form an eight-stranded antiparallel sheet with two molecules of the allosteric inhibitor serine bound in the interface. The ACT domain is found in a variety of contexts and is proposed to be a conserved regulatory ligand binding fold. Rat phenylalanine hydroxylase has a regulatory domain with a similar fold, but different ligand-binding mode. Putative ACT domains in some proteins of unknown structure (e.g. acetohydroxyacid synthase regulatory subunits) may also fold like the 3PGDH regulatory domain. The regulatory domain of threonine deaminase, although not a member of the ACT sequence family, is similar in structure to the paired 3PGDH regulatory domains. Repeats of ACT-like domains can create nonequivalent ligand-binding sites with the potential for complex regulatory patterns. The structures and mechanisms of such systems have only begun to be examined.     

Threonine dehydratase activity from several yeast species is activated and affected by phosphate

Abstract The threonine dehydratase activity of several yeast species was examined. Of 14 species tested, Candida maltosa, Pichia guilliermondii, Pichia pinus and Yarrowia lipolytica were found to produce an enzyme whose activity was increased about 20-fold in the presence of phosphate ions. It is suggested that phosphate affects the allosteric properties of the enzyme and leads, thereby, to an alteration of the binding of threonine (substrate), isoleucine (negative effector), and valine (positive effector) as well as to an alteration of the effects of temperature on the enzyme including changes in temperature optimum, energy of activation, and heat inactivation.     

Molecular Evolution of Threonine Dehydratase in Bacteria

Threonine dehydratase converts L-threonine to 2-ketobutyrate. Several threonine dehydratases exist in bacteria, but their origins and evolutionary pathway are unknown. Here we analyzed all the available threonine dehydratases in bacteria and proposed an evolutionary pathway leading to the genes encoding three different threonine dehydratases CTD, BTD1 and BTD2. The ancestral threonine dehydratase might contain only a catalytic domain, but one or two ACT-like subdomains were fused during the evolution, resulting BTD1 and BTD2, respectively. Horizontal gene transfer, gene fusion, gene duplication, and gene deletion may occur during the evolution of this enzyme. The results are important for understanding the functions of various threonine dehydratases found in bacteria.     

Cysteine and growth inhibition of Escherichia coli: threonine deaminase as the target enzyme.

Cysteine has been shown to inhibit growth in Escherichia coli strains C6 and HfrH 72, but not M108A. Growth inhibition was overcome by inclusion of isoleucine, leucine, and valine in the medium. Isoleucine biosynthesis was apparently affected, since addition of this amino acid alone could alter the inhibitory effects of cysteine. Homocysteine, mercaptoethylamine, and mercaptoethanol inhibited growth to varying degrees in some strains, these effects also being prevented by addition of branched-chain amino acids. Cysteine, mercaptoethylamine, and homocysteine were inhibitors of threonine deaminase but not transaminase B, two enzymes of the ilvEDA operon. Cysteine inhibition of threonine deaminase was reversed by threonine, although the pattern of inhibition was mixed. These results suggest a relationship between the growth-inhibitory effects of cysteine and other sulfur compounds and the inhibition of isoleucine synthesis at the level of threonine deaminase.     

Biosynthesis of Branched-Chain Amino Acids in Schizosaccharomyces pombe: Properties of Acetohydroxy Acid Synthetase1

The regulatory properties of acetohydroxy acid synthetase (AHAS), the first enzyme in the biosynthetic pathway to valine and the second in the isoleucine pathway, were investigated in the fission yeast Schizosaccharomyces pombe. The enzyme was partially purified from crude extracts by protamine sulfate treatment, ammonium sulfate fractionation, and gel filtration through Sephadex G-25. AHAS from S. pombe is unique in that its activity shows a single peak around pH 6.5; high sensitivity to feedback inhibition by valine at this pH (K(i) = 0.1 mM) indicates that the enzyme is involved in valine biosynthesis. Pyruvate saturation kinetics of AHAS extracted from cells grown on glycerol as sole carbon and energy source were normal and hyperbolic. In contrast, the enzyme from glucose-grown cells exhibited sigmoidal saturation kinetics, an effect which disappeared when the synthetase from such cells was partially purified. This phenomenon was shown to be due to competition for pyruvate between AHAS and pyruvate decarboxylase; the latter enzyme is present in large amounts in cells fermenting glucose. Valine inhibition is noncompetitive in nature, and this effector exhibits homotropic cooperative effects; isoleucine is a less-potent inhibitor of AHAS activity. Mercurial treatment reversibly desensitized the enzyme to valine inhibition. On the basis of these data, the S. pombe AHAS appears to be an allosteric regulatory enzyme with the properties of a negative V system.     

Serine 948 and threonine 1042 are crucial residues for allosteric regulation of Escherichia coli carbamoylphosphate synthetase and illustrate coupling effects of activation and inhibition pathways

Escherichia coli carbamoylphosphate synthetase (CPSase) is a key enzyme in the pyrimidine nucleotides and arginine biosynthetic pathways. The enzyme harbors a complex regulation, being activated by ornithine and inosine 5'-monophosphate (IMP), and inhibited by UMP. CPSase mutants obtained by in vivo mutagenesis and selected on the basis of particular phenotypes have been characterized kinetically. Two residues, serine 948 and threonine 1042, appear crucial for allosteric regulation of CPSase. When threonine 1042 is replaced by an isoleucine residue, the enzyme displays a greatly reduced activation by ornithine. The T1042I mutated enzyme is still sensitive to UMP and IMP, although the effects of both regulators are reduced. When serine 948 is replaced by phenylalanine, the enzyme becomes insensitive to UMP and IMP, but is still activated by ornithine, although to a reduced extent. When correlating these observations to the structural data recently reported, it becomes clear that both mutations, which are located in spatially distinct regions corresponding respectively to the ornithine and the UMP/IMP binding sites, have coupled effects on the enzyme regulation. These results provide an illustration that coupling of regulatory pathways occurs within the allosteric subunit of E. coli CPSase.In addition, other mutants have been characterized, which display altered affinities for the different CPSase substrates and also slightly modified properties towards the allosteric effectors: P165S, P170L, A182V, P360L, S743N, T800F and G824D. Kinetic properties of these modified enzymes are also presented here and correlated to the crystal structure of E. coli CPSase and to the phenotype of the mutants.     

Expression of the Escherichia coli catabolic threonine dehydratase in Corynebacterium glutamicum and its effect on isoleucine production.

The catabolic or biodegradative threonine dehydratase (E.C. 4.2.1. 16) of Escherichia coli is an isoleucine feedback-resistant enzyme that catalyzes the degradation of threonine to alpha-ketobutyrate, the first reaction of the isoleucine pathway. We cloned and expressed this enzyme in Corynebacterium glutamicum. We found that while the native threonine dehydratase of C. glutamicum was totally inhibited by 15 mM isoleucine, the heterologous catabolic threonine dehydratase expressed in the same strain was much less sensitive to isoleucine; i.e., it retained 60% of its original activity even in the presence of 200 mM isoleucine. To determine whether expressing the catabolic threonine dehydratase (encoded by the tdcB gene) provided any benefit for isoleucine production compared to the native enzyme (encoded by the ilvA gene), fermentations were performed with the wild-type strain, an ilvA-overexpressing strain, and a tdcB-expressing strain. By expressing the heterologous catabolic threonine dehydratase in C. glutamicum, we were able to increase the production of isoleucine 50-fold, whereas overexpression of the native threonine dehydratase resulted in only a fourfold increase in isoleucine production. Carbon balance data showed that when just one enzyme, the catabolic threonine dehydratase, was overexpressed, 70% of the carbon available for the lysine pathway was redirected into the isoleucine pathway.     

Identification of the regulatory subunit of Arabidopsis thaliana acetohydroxyacid synthase and reconstitution with its catalytic subunit

Acetohydroxyacid synthase (EC 4.1.3.18; AHAS) catalyzes the initial step in the formation of the branched-chain amino acids. The enzyme from most bacteria is composed of a catalytic subunit, and a smaller regulatory subunit that is required for full activity and for sensitivity to feedback regulation by valine. A similar arrangement was demonstrated recently for yeast AHAS, and a putative regulatory subunit of tobacco AHAS has also been reported. In this latter case, the enzyme reconstituted from its purified subunits remained insensitive to feedback inhibition, unlike the enzyme extracted from native plant sources. Here we have cloned, expressed in Escherichia coli, and purified the AHAS regulatory subunit of Arabidopsis thaliana. Combining the protein with the purified A. thaliana catalytic subunit results in an activity stimulation that is sensitive to inhibition by valine, leucine, and isoleucine. Moreover, there is a strong synergy between the effects of leucine and valine, which closely mimics the properties of the native enzyme. The regulatory subunit contains a sequence repeat of approximately 180 residues, and we suggest that one repeat binds leucine while the second binds valine or isoleucine. This proposal is supported by reconstitution studies of the individual repeats, which were also cloned, expressed, and purified. The structure and properties of the regulatory subunit are reminiscent of the regulatory domain of threonine deaminase (EC 4.2.1.16), and it is suggested that the two proteins are evolutionarily related.     

Crystal structure of threonine synthase from Arabidopsis thaliana

Threonine synthase (TS) is a PLP-dependent enzyme that catalyzes the last reaction in the synthesis of threonine from aspartate. In plants, the methionine pathway shares the same substrate, O-phospho-L-homoserine (OPH), and TS is activated by S-adenosyl-methionine (SAM), a downstream product of methionine synthesis. This positive allosteric effect triggered by the product of another pathway is specific to plants. The crystal structure of Arabidopsis thaliana apo threonine synthase was solved at 2.25 A resolution from triclinic crystals using MAD data from the selenomethionated protein. The structure reveals a four-domain dimer with a two-stranded beta-sheet arm protruding from one monomer onto the other. This domain swap could form a lever through which the allosteric effect is transmitted. The N-terminal domain (domain 1) has a unique fold and is partially disordered, whereas the structural core (domains 2 and 3) shares the functional domain of PLP enzymes of the same family. It also has similarities with SAM-dependent methyltransferases. Structure comparisons allowed us to propose potential sites for pyridoxal-phosphate and SAM binding on TS; they are close to regions that are disordered in the absence of these molecules.