Allosteric regulation of Bacillus subtilis threonine deaminase, a biosynthetic threonine deaminase with a single regulatory domain

The enzyme threonine deaminase (TD) is a key regulatory enzyme in the pathway for the biosynthesis of isoleucine. TD is inhibited by its end product, isoleucine, and this effect is countered by valine, the product of a competing biosynthetic pathway. Sequence and structure analyses have revealed that the protomers of many TDs have C-terminal regulatory domains, composed of two ACT-like subdomains, which bind isoleucine and valine, while others have regulatory domains of approximately half the length, composed of only a single ACT-like domain. The regulatory responses of TDs from both long and short sequence varieties appear to have many similarities, but there are significant differences. We describe here the allosteric properties of Bacillus subtilis TD ( bsTD), which belongs to the short variety of TD sequences. We also examine the effects of several mutations in the regulatory domain on the kinetics of the enzyme and its response to effectors. The behavior of bsTD can be analyzed and rationalized using a modified Monod-Wyman-Changeux model. This analysis suggests that isoleucine is a negative effector, and valine is a very weak positive effector, but that at high concentrations valine inhibits activity by competing with threonine for binding to the active site. The behavior of bsTD is contrasted with the allosteric behavior reported for TDs from Escherichia coli and Arabidopsis thaliana, TDs with two subdomains. We suggest a possible evolutionary pathway to the more complex regulatory effects of valine on the activity of TDs of the long sequence variety, e.g., E. coli TD.     

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.     

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.     

Regulation of the formation of isoleucyl-tRNA-synthetase and the level of isoleucine biosynthetic enzymes in E. coli K12

Summary During derepression of threonine deaminase and acetolactate synthetase due to valine deficiency—initiated by -aminobutyric acid limited growth of E. coli K12 or by limited valine supply to an ilv/leu auxotroph of E. coli K12—no alteration of the specific activity of isoleucyl-tRNA-synthetase occurs. Leucine limited growth of the auxotroph, leading to an even higher derepression of the isoleucine biosynthetic enzymes, also does not affect the specific activity of isoleucyl-tRNA-synthetase. However, under growth conditions where the same degree of derepression of threonine deaminase is due to isoleucine deficiency, as in E. coli K12B or two valine resistant mutants thereof grown in the presence of valine, or in the auxotroph during growth-limiting isoleucine supply, a specific two- to three-fold derepression of the isoleucyl-tRNA-synthetase takes place. But there is no strict correlation between the degree of derepression of threonine deaminase due to isoleucine deficiency and the degree of derepression of isoleucyl-tRNA-synthetase, as especially shown in case of the valine resistant mutant Val R4 and Val R5 grown in the presence of valine.These results demonstrate that the rate of formation of isoleucyl-tRNA-synthetase and of threonine deaminase are not regulated by the same molecular devices and that a certain degree of isoleucine deficiency is a prerequisite for a derepression of isoleucyl-tRNA-synthetase.     

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.     

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.     

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.     

Subunit–subunit interactions are weakened in mutant forms of acetohydroxy acid synthase insensitive to valine inhibition

In acetohydroxy acid synthase from Streptomyces cinnamonensis mutants affected in valine regulation, the impact of mutations on interactions between the catalytic and the regulatory subunits was examined using yeast two-hybrid system. Mutations in the catalytic and the regulatory subunits were projected into homology models of the respective proteins. Two changes in the catalytic subunit, E139A (α domain) and ΔQ217 (β domain), both located on the surface of the catalytic subunit dimer, lowered the interaction with the regulatory subunit. Three consecutive changes in the N-terminal part of the regulatory subunit were examined. Changes G16D and V17D in a loop and adjacent α-helix of ACT domain affected the interaction considerably, indicating that this region might be in contact with the catalytic subunit during allosteric regulation. In contrast, the adjacent mutation L18F did not influence the interaction at all. Thus, L18 might participate in valine binding or conformational change transfer within the regulatory subunits. Shortening of the regulatory subunit to 107 residues reduced the interaction essentially, suggesting that the C-terminal part of the regulatory subunit is also important for the catalytic subunit binding.     

Enzymes of the Isoleucine-Valine Pathway in Acinetobacter

Regulation of four of the enzymes required for isoleucine and valine biosynthesis in Acinetobacter was studied. A three- to fourfold derepression of acetohydroxyacid synthetase was routinely observed in two different wild-type strains when grown in minimal medium relative to cells grown in minimal medium supplemented with leucine, valine, and isoleucine. A similar degree of synthetase derepression was observed in appropriately grown isoleucine or leucine auxotrophs. No significant derepression of threonine deaminase or transaminase B occurred in either wild-type or mutant cells grown under a variety of conditions. Three amino acid analogues were tested with wild-type cells; except for a two- to threefold derepression of dihydroxyacid dehydrase when high concentrations of aminobutyric acid were added to the medium, essentially the same results were obtained. Experiments showed that threonine deaminase is subject to feedback inhibition by isoleucine and that valine reverses this inhibition. Cooperative effects in threonine deaminase were demonstrated with crude extracts. The data indicate that the synthesis of isoleucine and valine in Acinetobacter is regulated by repression control of acetohydroxyacid synthetase and feedback inhibition of threonine deaminase and acetohydroxyacid synthetase.     

Mutations Affecting the Different Transport Systems for Isoleucine, Leucine, and Valine in Escherichia coli K-12

Uptake of isoleucine, leucine, and valine in Escherichia coli K-12 is due to several transport processes for which kinetic evidence has been reported elsewhere. A very-high-affinity transport process, a high-affinity transport process, and three different low-affinity transport processes were described. In this paper the existence of these transport processes is confirmed by the isolation and preliminary characterization of mutants altered in one or more of them. The very-high-affinity transport process is missing either in strains carrying the brnR6(am) mutation or in strains carrying the brn-8 mutation. This appears to be a pleiotropic effect since other transport systems are also missing. Mutant analysis shows that more than one transport system with high affinity is present. One of them, high-affinity 1, which needs the activity of a protein produced by the brnQ gene, transports isoleucine, leucine, and valine and is unaffected by threonine. The other, high-affinity 2, which needs the activity of a protein produced by the brnS gene, transports isoleucine, leucine, and valine; this uptake is inhibited by threonine which probably is a substrate. Another protein, produced by the brnR gene, is required for uptake through both high-affinity 1 and high-affinity 2 transport systems. The two systems therefore appear to work in parallel, brnR being a branching point. The brnQ gene is located close to phoA at 9.5 min on the chromosome of E. coli, the brnR gene is located close to lac at 9.0 min, and the brnS gene is close to pdxA at 1 min. A mutant lacking the low-affinity transport system for isoleucine was isolated from a strain in which the high-affinity system was missing because of a brnR mutation. This strain also required isoleucine for growth because of an ilvA mutation. The mutant lacking the low-affinity transport system was unable to grow on isoleucine but could grow on glycylisoleucine. This mutant had lost the low-affinity transport for isoleucine, whereas those for leucine and valine were unaffected. A pleiotropic consequence of this mutation (brn-8) was a complete absence of the very-high-affinity transport system due either to the alteration of a common gene product or to any kind of secondary interference which inhibits it. Mutants altered in isoleucine-leucine-valine transport were isolated by taking advantage of the inhibition that valine exerts on the K-12 strain of E. coli. Mutants resistant both to valine inhibition (Val(r)) and to glycylvaline inhibition are regulatory mutants. Val(r) mutants that are sensitive to glycylvaline inhibition are transport mutants. When the very-high-affinity transport process is repressed (for example by methionine) the frequency of transport mutants among Val(r) mutants is higher, and it is even higher if the high-affinity transport process is partially inhibited by leucine.     

Isoleucine and Valine Metabolism in Escherichia coli XXII. A Pleiotropic Mutation Affecting Induction of Isomeroreductase Activity

The ilvC gene product, acetohydroxy acid isomeroreductase, an enzyme essential for isoleucine and valine formation, is subject to substrate induction in Escherichia coli. We have isolated a mutant of E. coli K-12 with a mutation that renders the ilvC gene product noninducible by its substrates, the acetohydroxy acids. This mutation, ilvY466, has been shown to be in a previously undiscovered locus that lies between ilvC and ilvO. The ilvY product, upsilon, is thought to be a regulatory element involved in the induction of ilvC. We postulate the recognition site, ilvQ, or upsilon and suggest that it lies between ilvC and ilvB. A possible model, involving upsilon, in the positive control of isomeroreductase is presented. Pleiotropic effects of the ilvY466 mutation have been recognized from changes in the end-product inhibition of threonine deaminase and of acetohydroxy acid synthetase. In addition, pleiotropic effects of this lesion on the regulation of threonine deaminase and the physical properties of threonine deaminase and acetohydroxy acid synthetase have been observed.     

A conformationally mobile cysteine residue (Cys-561) modulates Na+ and H+ activation of human CNT3

In humans, the SLC28 concentrative nucleoside transporter (CNT) protein family is represented by three Na(+)-coupled members; human CNT1 (hCNT1) and hCNT2 are pyrimidine and purine nucleoside-selective, respectively, whereas hCNT3 transports both purine and pyrimidine nucleosides and nucleoside drugs. Belonging to a phylogenetic CNT subfamily distinct from hCNT1/2, hCNT3 also mediates H(+)/nucleoside cotransport. Using heterologous expression in Xenopus oocytes, we have characterized a cysteineless version of hCNT3 (hCNT3C-). Processed normally to the cell surface, hCNT3C-exhibited hCNT3-like transport properties, but displayed a decrease in apparent affinity specific for Na(+) and not H(+). Site-directed mutagenesis experiments in wild-type and hCNT3C-backgrounds identified intramembranous Cys-561 as the residue responsible for this altered Na(+)-binding phenotype. Alanine at this position restored Na(+) binding affinity, whereas substitution with larger neutral amino acids (threonine, valine, and isoleucine) abolished hCNT3 H(+)-dependent nucleoside transport activity. Independent of these findings, we have established that Cys-561 is located in a mobile region of the hCNT3 translocation pore adjacent to the nucleoside binding pocket and that access of p-chloromercuribenzene sulfonate to this residue reports a specific H(+)-induced conformational state of the protein ( Slugoski, M. D., Ng, A. M. L., Yao, S. Y. M., Smith, K. M., Lin, C. C., Zhang, J., Karpinski, E., Cass, C. E., Baldwin, S. A., and Young, J. D. (2008) J. Biol. Chem. 283, 8496-8507 ). The present investigation validates hCNT3C- as a template for substituted cysteine accessibility method studies of CNTs and reveals a pivotal functional role for Cys-561 in Na(+)- as well as H(+)-coupled modes of hCNT3 nucleoside transport.     

Threonine deaminase from a nonsense mutant of Escherichia coli requiring isoleucine or pyridoxine: evidence for half-of-the-sites reactivity.

The mutant IP7 of Escherichia coli B requires isoleucine or pyridoxine for growth as a consequence of a mutation in the gene coding for biosynthetic threonine deaminase. The mutation of IP7 was shown to be of the nonsense type by the following data: (1) reversion to isoleucine prototrophy involves the formation of external suppression at a high frequency, as shown by transduction experiments; and (ii) the isoleucine requirement is suppressed by lysogenization with a phage carrying the amber suppressor su-3. Cell extracts of the mutant strain contain a low activity of threonine deaminase. The possibility that this activity is biodegradative was ruled out by kinetic experiments. The mutant threonine deaminase was purified to homogeneity by conventional procedures. The enzyme is a dimer of identical subunits of an approximate molecular weight of 43,000 (Grimminger and Feldner, 1974), whereas the wild-type enzyme is a tetramer of 50,000-dalton subunits (Calhoun et al., 1973; Grimminger et al., 1973). The mutant enzyme is not inhibited by isoleucine and does not bind isoleucine, as shown by equilibrium dialysis experiments. Pyridoxal phosphate enhances the maximum catalytic activity of the mutant enzyme by a factor of five, whereas the wild-type enzyme is not affected. In wild-type and mutant threonine deaminase the ratio of protein subunits and bound pyridoxal phosphate is 2:1. The activation of threonine deaminase from strain IP7 is due to a second coenzyme binding site, as shown by (i) spectrophotometric titration of the enzyme with pyridoxal phosphate and by (ii) measurement the pyridoxal phosphate content of the enzyme after sodium borohydride reduction of the protein. The observation of one pyridoxal phosphate binding site per peptide dimer in the wild-type enzyme and of two binding sites per dimer in the mutant strongly suggests that one of the potential sites in the wild-type enzyme is masked by allosteric effects. The factors responsible for the half-of-the-sites reactivity of the coenzyme sites appear to be nonoperative in the mutant protein.     

Homocysteine toxicity in Escherichia coli is caused by a perturbation of branched-chain amino acid biosynthesis

In Escherichia coli the sulfur-containing amino acid homocysteine (Hcy) is the last intermediate on the methionine biosynthetic pathway. Supplementation of a glucose-based minimal medium with Hcy at concentrations greater than 0.2 mM causes the growth of E. coli Frag1 to be inhibited. Supplementation of Hcy-treated cultures with combinations of branched-chain amino acids containing isoleucine or with isoleucine alone reversed the inhibitory effects of Hcy on growth. The last intermediate of the isoleucine biosynthetic pathway, alpha-keto-beta-methylvalerate, could also alleviate the growth inhibition caused by Hcy. Analysis of amino acid pools in Hcy-treated cells revealed that alanine, valine, and glutamate levels are depleted. Isoleucine could reverse the effects of Hcy on the cytoplasmic pools of valine and alanine. Supplementation of the culture medium with alanine gave partial relief from the inhibitory effects of Hcy. Enzyme assays revealed that the first step of the isoleucine biosynthetic pathway, catalyzed by threonine deaminase, was sensitive to inhibition by Hcy. The gene encoding threonine deaminase, ilvA, was found to be transcribed at higher levels in the presence of Hcy. Overexpression of the ilvA gene from a plasmid could overcome Hcy-mediated growth inhibition. Together, these data indicate that in E. coli Hcy toxicity is caused by a perturbation of branched-chain amino acid biosynthesis that is caused, at least in part, by the inhibition of threonine deaminase.     

O-Methylthreonine Inhibition of Growth and of Threonine Deaminase in Escherichia coli

O-methylthreonine (OMT), an isosteric analogue of isoleucine, markedly inhibited growth of Escherichia coli 15. This inhibition was overcome most effectively by addition of isoleucine, valine, or leucine to the medium and less effectively by addition of threonine. The dipeptide, valylleucine, also relieved the OMT-induced inhibition but only after a lag period, suggesting that valine and leucine, liberated by dipeptidase action, compete with OMT for entry into the cell. OMT was activated and transferred to transfer ribonucleic acid (RNA) by isoleucyl-RNA synthetase in vitro. The rate of OMT incorporation into protein of intact cells was comparable to that of isoleucine. In contrast to isoleucine, very high concentrations of OMT were required to inhibit threonine deaminase, and the inhibition was strictly competitive with threonine. In addition, OMT inhibited a threonine deaminase preparation desensitized to isoleucine inhibition.     

Mutant species of EF-Tu, altered at position 375, exhibit a reduced affinity for aminoacylated transfer-RNAs

The interaction between EF-Tu X GTP and aminoacyl-tRNA is shown to be influenced by mutations at site 375 of this three-domain protein. Site 375 is located in domain II near the interface with domain I [(1984) EMBO J. 3, 113-120]. Replacement of the alanine at this site by a threonine or valine residue results in lower binding constants with Phe-tRNA and Tyr-tRNA, as was evaluated by the hydrolysis protection technique. The data are discussed in the light of what is known about the three-dimensional structure of the protein and its interaction sites with aminoacyl-tRNA.     

Multivalent regulation of isoleucine-valine transaminase in an Escherichia coli K-12 ilvA deletion strain.

In a strain of Escherichia coli K-12 lacking threonine deaminase, the enzyme converting alpha-ketoisovalerate and alpha-keto-beta-methylvalerate to valine and isoleucine, respectively, was multivalently repressed by valine, isoleucine, and leucine. This activity was due to transaminase B, specified by the ilvE structural gene.     

Molecular interactions of the Gbeta binding domain of the Ste20p/PAK family of protein kinases. An isolated but fully functional Gbeta binding domain from Ste20p is only partially folded as shown by heteronuclear NMR spectroscopy

The transmission of the mating signal of the budding yeast Saccharomyces cerevisiae requires Ste20p, a member of the serine/threonine protein kinases of the Ste20p/PAK family, to link the Gbeta subunit of the heterotrimeric G protein to the mitogen-activated protein kinase cascades. The binding site of Ste20p to the Gbeta subunit was mapped to a consensus sequence of SSLphiPLI/VXphiphibeta (X for any residue; phi for A, I, L, S or T; beta for basic residues), which was shown to be a novel Gbeta binding (GBB) motif present only in the noncatalytic C-terminal domains of the Ste20p/PAK family of protein kinases (Leeuw, T., Wu, C., Schrag, J. D., Whiteway, M., Thomas, D. Y., and Leberer, E. (1998) Nature 391, 191-195; Leberer, E., Dignard, D., Thomas, D. Y., and Leeuw, T. (2000) Biol. Chem. 381, 427-431). Here, we report the results of an NMR study on two GBB motif peptides and the entire C-terminal domain derived from Ste20p. The NMR data show that the two peptide fragments are not uniquely structured in aqueous solution, but in the presence of 40% trifluoroethanol, the longer 37-residue peptide exhibited two well defined, but flexibly linked helical structure elements. Heteronuclear NMR data indicate that the fully functional 86-residue C-terminal domain of Ste20p is again unfolded in aqueous solution but has helical secondary structure preferences similar to those of the two peptide fragments. The NMR results on the two GBB peptides and the entire GBB domain all indicate that the two important binding residues, Ser(879) and Ser(880), are located at the junction between two helical segments. These experimental observations with the prototype GBB domain of a novel family of Gbeta-controlled effectors may have important implications in understanding the molecular mechanisms of the signal transduction from the heterotrimeric G protein to the mitogen-activated protein kinase cascade.