Interaction of substrates and inhibitors with the homoserine dehydrogenase of kinase-inactivated aspartokinase I.

The aspartokinase activity of the aspartokinase-homoserine dehydrogenase complex of Escherichia coli was affinity labeled with substrates ATP, aspartate, and feedback inhibitor threonine. Exchange-inert ternary adducts of Co(III)-aspartokinase and either ATP, aspartate or threonine were formed by oxidation of corresponding Co(II) ternary complexes with H2O2. The ternary enzyme-Co(III)-threonine adduct (I) had 3.8 threonine binding sites per tetramer, one-half that of the native enzyme. The binding of threonine to I was still cooperative as determined by equilibrium dialysis (nH = 2.2) or by studying inhibition of residual dehydrogenase activity (nH = 2.7). Threonine still protected the SH groups of I against 5,5'-dithiobis(2-nitrobenzoate) (DTNB) reaction but the number of SH groups reacting with thiol reagents (DTNB) was reduced by 1-2 per subunit in the absence of threonine. This suggests either that Co(III) is bound to the enzyme via sulfhydryl groups or that 1-2SH groups are buried or rendered inaccessible in I. The binding of threonine to sites not blocked by the affinity labeling produced changes in the circular dichroism of the complex comparable to changes produced by threonine binding to native enzyme and also protected against proteolytic digestion. The major conformational changes produced by threonine are thus ascribable to binding at this one class of regulatory sites. The interactions of kinase substrates with various aspartokinase-Co(III) complexes containing ATP, aspartate, or threonine and a threonine-insensitive homoserine dehydrogenase produced by mild proteolysis were studied. The inhibition of homoserine dehydrogenase by kinase substrates is not due to binding of these inhibitors at the kinase active site but was shown to be due to binding to sites within the dehydrogenase domain of the enzyme. L-alpha-Aminobutyrate, a presumed threonine analogue, also inhibits the dehydrogenase by binding at the same or similar sites in the dehydrogenase domain and not at threonine regulatory site.     

Why Threonine Is an Essential Amino Acid in Mammals and Birds: Studies at the Enzyme Level

The only pathway for the synthesis of essential amino acids in vertebrates is reversible transamination of their keto analogs with glutamic acid. At the same time, it is commonly accepted that such essential amino acids as lysine and threonine are not involved in transamination and, therefore, cannot be synthesized from their keto analogs. However, using radio-labeled isotopes, synthesis of threonine was demonstrated in rat liver and in a reaction mixture containing chicken liver threonine dehydrogenase. In the review, we discuss why threonine is an essential amino acid in mammals and birds based on the pathways of threonine biosynthesis in these two classes of vertebrates.     

L-threonine aldolase is not a genuine enzyme in rat liver.

Activity of L-threonine aldolase in rat liver cytosolic extract was not affected by the omission of alcohol dehydrogenase in a previously established NADPH-linked alcohol dehydrogenase-coupled assay. The liver extract was able to catalyse the dehydrogenation of NADPH with either acetaldehyde (a product of L-threonine aldolase action) or 2-oxobutyrate (a product of L-threonine dehydratase action). When the liver extract was chromatographed on a Sephacryl S-200 column, no threonine aldolase activity was detected in the eluate. However, activity of threonine aldolase re-appeared when the fractions with highest activity of lactate dehydrogenase and threonine dehydratase were mixed. Activity of threonine aldolase could also be abolished by removing threonine dehydratase from the liver extract with a specific antibody. Hence L-threonine aldolase should not be a genuine enzyme in the rat liver, and the apparent enzyme activity may result from a combined effect of threonine dehydratase and lactate dehydrogenase (or an oxo acid-linked NADPH dehydrogenase) in the liver cytosolic extract.     

Localisation and characterisation of homoserine dehydrogenase isolated from barley and pea leaves

Two forms of homoserine dehydrogenase exist in the leaves of both barley and pea; one has a large molecular weight and is inhibited by threonine, the other is of smaller molecular weight and insensitive to threonine but inhibited by cysteine. The subcellular localisation of these enzymes has been examined. Both plants have 60–65% of the total homoserine dehydrogenase activity present in the chloroplast and this activity is inhibited by threonine. The low molecular weight, threonine-insensitive form is present in the cytoplasm. Total homoserine dehydrogenase activity from barley leaves showed progressive desensitisation towards threonine with age in a similar manner to that previously described for maize. It was shown that the effect was due to desensitisation of the chloroplast enzyme, and not to an increase in the insensitive cytoplasm enzyme. No corresponding desensitisation to threonine was detected in pea leaves. The different forms of homoserine dehydrogenase could be separated from pea leaves by chromatography on Blue Sepharose; the threonine-sensitive enzyme passed straight through and the threonine insensitive form was bound. A similar separation of the barley leaf isoenzymes was obtained using Matrex Gel Red A affinity columns; in this case however, the threonine-sensitive isoenzyme was bound. In both plants, the threonine insensitive isoenzyme was subject to greater inhibition by cysteine than was the threonine-sensitive isoenzyme.Abbreviation HSDH homoserine dehydrogenase     

Interaction between L-threonine dehydrogenase and aminoacetone synthetase and mechanism of aminoacetone production

A mixture of threonine dehydrogenase and aminoacetone synthetase will catalyze the conversion of L-threonine to glycine. The overall reaction likely involves the conversion of L-threonine, NAD+, and CoA to glycine, NADH, and acetyl-CoA. Physical separation of L-threonine dehydrogenase from aminoacetone synthetase results in the formation of aminoacetone and CO2 from their substrates. A physical interaction between threonine dehydrogenase and aminoacetone synthetase has been demonstrated by gel permeation chromatography and fluorescence polarization. Polarization of fluorescence measurements of threonine dehydrogenase and aminoacetone synthetase labeled with fluorescein isothiocyanate indicated the formation of a soluble active complex, with an apparent dissociation constant (Kd) of 5-10 nM and an apparent stoichiometry of 2 aminoacetone synthetase dimers/1 threonine dehydrogenase tetramer. Chemical experiments have identified aminoacetone as the enzymatic product of L-threonine dehydrogenase acting on L-threonine. These experiments involved trapping pyrrole derivatives, [3H]NaBH4 reduction, and coupling with plasma amine oxidase. Kinetic experiments also showed NADH, CO2, and aminoacetone to inhibit threonine dehydrogenase in a manner consistent with an ordered Bi-Ter kinetic mechanism. NAD+ is the lead substrate followed by threonine, and the products are released in the order: CO2, aminoacetone, and NADH.     

Use of Feedback-Resistant Threonine Dehydratases of Corynebacterium glutamicum To Increase Carbon Flux towards l-Isoleucine

The biosynthesis of l-isoleucine proceeds via a highly regulated reaction sequence connected with l-lysine and l-threonine synthesis. Using defined genetic Corynebacterium glutamicum strains characterized by different fluxes through the homoserine dehydrogenase reaction, we analyzed the influence of four different ilvA alleles (encoding threonine dehydratase) in vectors with two different copy numbers on the total flux towards l-isoleucine. For this purpose, 18 different strains were constructed and analyzed. The result was that unlike ilvA in vectors with low copy numbers, ilvA in high-copy-number vectors increased the final l-isoleucine yield by about 20%. An additional 40% increase in l-isoleucine yield was obtained by the use of ilvA alleles encoding feedback-resistant threonine dehydratases. The strain with the highest yield was characterized by three hom(Fbr) copies encoding feedback-resistant homoserine dehydrogenase and ilvA(Fbr) encoding feedback-resistant threonine dehydratase on a multicopy plasmid. It accumulated 96 mM l-isoleucine, without any l-threonine as a by-product. The highest specific productivity was 0.052 g of l-isoleucine per g of biomass per h. This comparative flux analysis of isogenic strains showed that high levels of l-isoleucine formation from glucose can be achieved by the appropriate balance of homoserine dehydrogenase and threonine dehydratase activities in a strain background with feedback-resistant aspartate kinase. However, still-unknown limitations are present within the entire reaction sequence.     

Threonine degradation by Serratia marcescens.

The wild strain of Serratia marcescens rapidly degraded threonine and formed aminoacetone in a medium containing glucose and urea. Extracts of this strain showed high threonine dehydrogenase and "biosynthetic" threonine deaminase activities, but no threonine aldolase activity. Threonine dehydrogenase-deficient strain Mu-910 was selected among mutants unable to grow on threonine as the carbon source. This strain did not form aminoacetone from threonine, but it slowly degraded threonine. Strain D-60, deficient in both threonine dehydrogenase and threonine deaminase, was derived from strain Mu-910 and barely degraded threonine. A glycine-requiring strain derived from the wild strain grew in minimal medium containing threonine as the glycine source, whereas a glycine-requiring strain derived from strain Mu-910 did not grow. This indicates that threonine dehydrogenase participates in glycine formation from threonine (via alpha-amino-beta-ketobutyrate) as well as in threonine degradation to aminoacetone.     

Mobilization of the Proteus morganii chromosome by R plasmids

Mutants of Pseudomonas aeruginosa PAC1 which could grow on L-threonine were isolated. These mutants, like the parent strain, synthesized a biosynthetic threonine deaminase, but its apparent Km value for threonine was higher than that of the enzyme from strain PAC1. These mutants also synthesized an inducible NAD-dependent threonine dehydrogenase, which was not present in the parent strain. No threonine aldolase activity could be detected. The results suggest that the threonine deaminase with lowered affinity for L-threonine, together with L-threonine dehydrogenase, enabled these mutants to utilize L-threonine as the sole source of carbon for growth.     

Nutrition of Threonine

The threonine content in blood and urine increased and threonine decomposition ability in liver decreased by feeding lower level of lysine, whereas threonine content in blood and urine decreased and the ability of liver increased gradually with increasing lysine content in diet. These phenomena were owing to the increase of threonine dehydratase activity of liver, which was measured from produced α-ketobutyric acid amount, by excess administration of lysine. The phenomena that threonine content in urine decreased and threonine decomposition ability of liver increased with increasing threonine content in diet when adequate amount of lysine was fed, were also ascribed to the increase of the dehydratase activity.

One m mole of threonine was incubated with liver homogenate in presence of PALP*** at pH 8.2 for 20 and 30 min and α-ketobutyric acid produced was introduced to its 2,4-dinitrophenylhydrazone, which was chromatographed on silica-gel thin-layer plate and determined spectrophotometrically at 395 mμ under N,N-dimethylformamide.

Other enzyme systems relating to threonine catabolism were also investigated, including threonine aldolase, threonine dehydrogenase and ornithine transaminase, showing no significant changes in activities by excess administration of lysine and/or threonine.     

Role of threonine dehydrogenase in Escherichia coli threonine degradation.

Threonine was used as nitrogen source by Escherichia coli K-12 through a pathway beginning with the enzyme threonine dehydrogenase. The 2-amino-3-ketobutyrate formed was converted to glycine, and the glycine was converted to serine, which acted as the actual nitrogen donor. The enzyme formed under anaerobic conditions and known as threonine deaminase (biodegradative) is less widespread than threonine dehydrogenase and may be involved in energy metabolism rather than in threonine degradation per se.     

Fluorescence studies of threonine-promoted conformational transitions in aspartokinase I using the substrate analogue 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate

The trinitrophenyl derivative of ATP, 2'(3')-O-(2,4,6-trinitrophenyl) adenosine 5'-triphosphate, has been used as a spectroscopic probe to investigate threonine-promoted conformational changes in the aspartokinase region of aspartokinase-homoserine dehydrogenase I in an attempt to relate the structural effects of threonine binding to inhibition of enzymatic activity. Binding of this analogue substrate to the enzyme is characterized by a 9-fold enhancement in probe fluorescence. Saturating levels of the feedback inhibitor, threonine, produce a 77% increase in fluorescence enhancement, indicating an increase in the rigidity or hydrophobicity of the nucleotide-binding site in the inhibited form of the enzyme. Threonine titration studies indicate that the two inhibitor-binding sites found on each subunit do not contribute equally to the fluorescence-detected conformational change. Comparison of the spectral change with the inhibition of dehydrogenase activity has revealed the exclusive involvement of the non-kinase threonine sites. No transition can be detected as a consequence of inhibitor binding at the kinase subsites. The results of the 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate study have provided further evidence for a concerted kinase-dehydrogenase conformational change which is induced by threonine interaction with the high affinity binding sites and which provides maximal inhibition of homoserine dehydrogenase and the majority of aspartokinase inhibition. The failure to observe a distinct enzyme form produced by threonine occupation of the low affinity kinase sites suggests that no large structural reorganization of the kinase active site is produced as a result of this binding event. The conformational change, suggested by the cooperativity of threonine binding, must instead involve only a subtle or highly localized alteration which does not perturb the environment of the ATP-binding cleft.     

Growth, enzyme levels, and some metabolic properties of an Escherichia coli mutant grown on L-threonine as the sole carbon source.

A mutant of Escherichia coli (designated E. coli SBD-76) that utilizes L-threonine as the sole carbon source was isolated. In contrast with levels in extracts of wild-type cells, the levels of threonine dehydrogenase in extracts of this mutant were 100-fold higher than levels of threonine aldolase or degradative threonine dehydratase. Catabolite repression of threonine dehydrogenase was manifested in wild-type, but not SBD-76, cells. For purposes of isolating enzymes, large quantities of SBD-76 cells with the elevated threonine dehydrogenase level could be grown in a fermentor in modified Fraser medium containing 1% glycerol, rather than in the 0.2% L-threonine minimal medium used to isolate the mutant. SBD-76 cells grown on L-threonine excreted glycine and aminoacetone into the medium, and extracts of the mutant strain catalyzed a quantitative conversion of L-threonine to glycine and aminoacetone.     

Structural and functional analysis of a cloned segment of Escherichia coli DNA that specifies proteins of a C4 pathway of serine biosynthesis.

The plasmid pDR121 is a pBR322 derivative that contains a 3.7-kilobase-pair EcoRI fragment of DNA from the 81.2-min region of the Escherichia coli chromosome. The genomic insert encodes threonine dehydrogenase and at least one other protein. Several physical and kinetic properties of threonine dehydrogenase, overproduced in cells harboring pDR121, are identical to those of pure threonine dehydrogenase from a haploid mutant of E. coli K-12 that produces this enzyme constitutively. Tester strains with serB or glyA mutations harboring pDR121 are prototrophs. The ability to confer prototrophy on such tester strains is associated with elevated levels of threonine dehydrogenase. The functional roles of various segments of the 3.7-kilobase-pair insert of pDR121 were analyzed by constructing specific deletions and insertions. Certain subclones retained the ability to specify threonine dehydrogenase without conferring prototrophy on tester strains. This suggests that at least one other protein encoded within pDR121 plays an essential role in the conversion of threonine to serine.     

Biosynthesis of amino acids in Clostridium pasteurianum

1. Clostridium pasteurianum was grown on a synthetic medium with the following carbon sources: (a) (14)C-labelled glucose, alone or with unlabelled aspartate or glutamate, or (b) unlabelled glucose plus (14)C-labelled aspartate, glutamate, threonine, serine or glycine. The incorporation of (14)C into the amino acids of the cell protein was examined. 2. In both series of experiments carbon from exogenous glutamate was incorporated into proline and arginine; carbon from aspartate was incorporated into glutamate, proline, arginine, lysine, methionine, threonine, isoleucine, glycine and serine. Incorporations from the other exogenous amino acids indicated the metabolic sequence: aspartate --> threonine --> glycine right harpoon over left harpoon serine. 3. The following activities were demonstrated in cell-free extracts of the organism: (a) the formation of aspartate by carboxylation of phosphoenolpyruvate or pyruvate, followed by transamination; (b) the individual reactions of the tricarboxylic acid route to 2-oxoglutarate from oxaloacetate; glutamate dehydrogenase was not detected; (c) the conversion of aspartate into threonine via homoserine; (d) the conversion of threonine into glycine by a constitutive threonine aldolase; (e) serine transaminase, phosphoserine transaminase, glycerate dehydrogenase and phosphoglycerate dehydrogenase. This last activity was abnormally high. 4. The combined evidence indicates that in C. pasteurianum the biosynthetic role of aspartate and glutamate is generally similar to that in aerobic and facultatively aerobic organisms, but that glycine is synthesized from glucose via aspartate and threonine.     

Minor threonine dehydratase encoded within the threonine synthetic region of Bacillus subtilis

Challenging auxotrophs on metabolites that are precursors of a biosynthetic step involving a mutated enzyme has revealed a new class of suppressor mutations which act by derepressing a minor enzyme activity not normally detected in the wild-type strain. These indirect, partial suppressor mutations which allow isoleucine auxotrophs to grow on homoserine or threonine have been analyzed to determine their effect on enzymes involved in the biosynthesis of these amino acids. It has been found that one class of these suppressor mutations (sprA) leads to the derepression of homoserine kinase, homoserine dehydrogenase, and a minor threonine dehydratase that is not sufficiently active to be detected in the wild-type strain. The gene encoding this second threonine dehydratase activity has been found to be located between the structural genes for homoserine kinase and homoserine dehydrogenase. The results of these experiments indicate that plating of auxotrophs on precursors of a biosynthetic step involving mutated enzymes could prove to be a valuable method for the detection of regulatory mutants as well as a possible tool in studying the evolution of biochemical pathways.     

Purification and Interconversion of Homoserine Dehydrogenase from Daucus carota Cell Suspension Cultures

Homoserine dehydrogenase from cell suspension cultures of carrot (Daucus carota L.) has been purified to apparent homogeneity by a combination of selective heat denaturation, ion exchange and gel filtration chromatographies, and preparative gel electrophoresis. Carrot homoserine dehydrogenase is composed of subunits of equal molecular weight (85,000 ± 5,000). During purification, the enzyme exists predominantly in two molecular weight forms, 180,000 and 240,000. The enzyme can be reversibly converted from one form to the other, and each has different regulatory properties. When the enzyme is dialyzed in the presence of 5 millimolar threonine, the purified enzyme is converted into its trimeric form (240,000), which is completely inhibited by 5 millimolar threonine and is stimulated 2.6-fold by K⁺. When the enzyme is dialyzed in the presence of K⁺ and absence of threonine, the purified enzyme is converted into a dimer (180,000), which is not inhibited by threonine and is only stimulated 1.5-fold by K⁺. The enzyme also can polymerize under certain conditions to form higher molecular weight aggregates ranging in size up to 720,000, which also are catalytically active. This interconversion of homoserine dehydrogenase conformations may reflect the daily stream of events occurring in vivo. When light stimulates protein synthesis, the threonine pool decreases in the chloroplast, while K⁺ concentrations increase. The change in threonine and K⁺ concentrations shift the homoserine dehydrogenase from the threonine-sensitive to the threonine-insensitive conformation resulting in increased production of threonine, which would meet the demands of protein synthesis. The reverse process would occur in the dark.     

Regulation of a metabolic system in vitro: synthesis of threonine from aspartic acid.

Six enzymes involved in the conversion of aspartate to threonine have been extracted from Escherichia coli and separated from each other. Two of these enzymes, aspartokinase and homoserine dehydrogenase, have also been partially purified from Rhodopseudomonas spheroides. In an attempt to determine whether small changes in the kinetic properties of individual enzymes are important to the regulation of metabolic flux through a coupled reaction system, the partially purified enzymes were recombined in a variety of ways under reaction conditions designed to resemble the in vivo situation. These conditions include: use of an entire metabolic system rather than a single reaction; high enzyme concentrations at the same relative concentrations as found in the cell; and low, steady-state concentrations of substrates and products. Metabolic flux was followed spectrophotometrically and the concentrations of aspartic semialdehyde, hemoserine, O-phosphohomoserine, and threonine were measured. The results indicate that the threonine concentration is of major importance in regulating metabolic flux by inhibiting aspartokinase, the first reaction in threonine in the pathway. When threonine-insensitive aspartokinases were used, concentrations reached higher levels and the rate of NADPH oxidation remained higher. The fact that neither aspartic semialdehyde nor homoserine accumulated as the threonine concentration increased and the lack of correlation between changes in metabolic flux and ADP/ATP or NADPH/NADP ratios indicate that more subtle forms of metabolic regulation, such as "reverse cascade", secondary feedback sites, or "energy charge", are of little regulatory importance in this isolated, metabolic system. The results also emphasize the need for caution in projecting in vivo control mechanisms from in vitro experiments.     

Isoleucine and Valine Metabolism of Escherichia coli XVI. Pattern of Multivalent Repression in Strain K-12

The levels of the five enzymes required for isoleucine and valine synthesis were examined under several growth conditions in strain K-12 of Escherichia coli and mutants derived from it. In strains with wild type repressibility, the same pattern of derepression was found on limiting isoleucine as is found to be constitutive in strain Tir-8, which has an altered isoleucine-activating enzyme. Homoserine dehydrogenase, which is essential for the biosynthesis of threonine and is normally derepressed on limiting isoleucine or threonine, is also derepressed in strain Tir-8. Threonine deaminase and homoserine dehydrogenase were partially repressed in strain Tir-8 by very high levels of isoleucine, but were not further derepressed over levels in minimal medium by limiting isoleucine.     

Threonine metabolism byPseudomonas aeruginosa

83 strains ofPseudomonas aeruginosa were unable to utilizel-threonine as carbon-energy source, although this compound served as sole nitrogen source. Auxotrophs ofP. aeruginosa 9-D2 that requiredl-serine or glycine for growth could grow in the presence ofl-threonine. Extracts ofP. aeruginosa 9-D2 grown in the presence ofl-threonine contained threonine dehydrogenase and alpha-amino beta-ketobutyrate: CoA ligase activities; threonine aldolase was not detectable. Cells grown in the absence ofl-threonine produced no detectable threonine dehydrogenase.l-Leucine neither stimulated nor repressed threonine dehydrogenase levels. Glycine, and to a lesser extentl-serine, repressedl-threonine-mediated threonine dehydrogenase synthesis. A mutant of strain 9-D2 was isolated that could utilizel-threonine as sole carbon-energy source. This strain produced elevated levels of threonine dehydrogenase, but only slightly higher levels of alpha-amino beta-ketobutyrate: CoA ligase activities.