The first crystal structure of L-threonine dehydrogenase

L-threonine dehydrogenase (TDH) is an enzyme that catalyzes the oxidation of L-threonine to 2-amino-3-ketobutyrate. We solved the first crystal structure of a medium chain L-threonine dehydrogenase from a hyperthermophilic archaeon, Pyrococcus horikoshii (PhTDH), by the single wavelength anomalous diffraction method using a selenomethionine-substituted enzyme. This recombinant PhTDH is a homo-tetramer in solution. Three monomers of PhTDHs were located in the crystallographic asymmetric unit, however, the crystal structure exhibits a homo-tetramer structure with crystallographic and non-crystallographic 222 symmetry in the cell. Despite the low level of sequence identity to a medium-chain NAD(H)-dependent alcohol dehydrogenase (ADH) and the different substrate specificity, the overall folds of the PhTDH monomer and tetramer are similar to those of the other ADH. Each subunit is composed of two domains: a nicotinamide cofactor (NAD(H))-binding domain and a catalytic domain. The NAD(H)-binding domain contains the alpha/beta Rossmann fold motif, characteristic of the NAD(H)-binding protein. One molecule of PhTDH contains one zinc ion playing a structural role. This metal ion exhibits coordination with four cysteine ligands and some of the ligands are conserved throughout the structural zinc-containing ADHs and TDHs. However, the catalytic zinc ion that is coordinated at the bottom of the cleft in the case of ADH was not observed in the crystal of PhTDH. There is a significant difference in the orientation of the catalytic domain relative to the coenzyme-binding domain that results in a larger interdomain cleft.     

The primary structure of L-asparaginase from Escherichia coli

The carboxymethylated L-asparaginase from Escherichia coli A-1--3 was fragmented with cyanogen bromide and the resulting peptides were isolated by using gel filtration on Sephadex G-50 and column chromatography on DE-52. The amino acid sequences of the 7 cyanogen bromide peptides thus obtained were established completely or partially by further fragmentation with trypsin, chymotrypsin and pepsin, and the Dansyl Edman method. Based on the above results and the complete sequences of the tryptic peptides from the carboxymethylated L-asparaginase reported in the previous paper, the whole sequence of the enzyme was established. The reported sequence consists of 321 amino acid residues and its calculated molecular weight is 34 080.     

L-threonine dehydrogenase from Escherichia coli K-12: thiol-dependent activation by Mn2+

Addition of 1 mM Mn2+ to all solutions in the final chromatographic step used to purify L-threonine dehydrogenase (L-threonine:NAD+ oxidoreductase, EC 1.1.1.103) from extracts of Escherichia coli K-12 routinely provides 30-40 mg of pure enzyme per 100 g wet weight of cells with specific activity = 20-30 units/mg. Enzyme dialyzed exhaustively against buffers containing Chelex-100 resin has a specific activity = 8 units/mg and contains 0.003 or 0.02 mol of Mn2+/mol of enzyme as determined by radiolabeling studies with 54Mn2+ or by atomic absorption spectroscopy, respectively. Dehydrogenase activity is completely abolished by low concentrations of either Hg2+ or Ag+; of a large spectrum of other metal ions tested, only Mn2+ and Cd2+ have an activating effect. Activation of threonine dehydrogenase by Mn2+ is thiol-dependent and is saturable with an activation Kd = 9.0 microM and a Vmax = 105 units/mg. Stoichiometry of Mn2+ binding was found to be 0.86 mol of Mn2+/mol of enzyme subunit with a dissociation constant (Kd) = 8.5 microM. Mn2+ appears to interact directly with threonine dehydrogenase; gel filtration studies with the dehydrogenase plus 54Mn2+ in the presence of either NAD+, NADH, L-threonine, or combinations thereof show that only Mn2+ coelutes with the enzyme whereas all other ligands elute in the salt front and the stoichiometry of the dehydrogenase-Mn2+ interaction is not affected in any instance. A theoretical curve fit to data for the pH-activity profile of Mn2+-saturated enzyme has a pKa = 7.95 for one proton ionization. The data establish L-threonine dehydrogenase of E. coli to be a metal ion activated enzyme.     

Role of L-threonine dehydrogenase in the catabolism of threonine and synthesis of glycine by Escherichia coli.

The enzyme L-threonine dehydrogenase was demonstrated in extracts of Escherichia coli K-12, and was shown to be the first enzyme of the pathway converting threonine to glycine. The enzyme was induced by L-leucine, but not by its substrate, L-threonine. The metabolic significance of leucine as a catabolic signal for amino acid degradation is considered.     

L-threonine dehydrogenase from Escherichia coli. Identification of an active site cysteine residue and metal ion studies

Pure L-threonine dehydrogenase from Escherichia coli is a tetrameric protein (Mr = 148,000) with 6 half-cystine residues/subunit; its catalytic activity as isolated is stimulated 5-10-fold by added Mn2+ or Cd2+. The peptide containing the 1 cysteine/subunit which reacts selectively with iodoacetate, causing complete loss of enzymatic activity, has been isolated and sequenced; this cysteine residue occupies position 38. Neutron activation and atomic absorption analyses of threonine dehydrogenase as isolated in homogeneous form now show that it contains 1 mol of Zn2+/mol of enzyme subunit. Removal of the Zn2+ with 1,10-phenanthroline demonstrates a good correlation between the remaining enzymatic activity and the zinc content. Complete removal of the Zn2+ yields an unstable protein, but the native metal ion can be exchanged by either 65Zn2+, Co2+, or Cd2+ with no change in specific catalytic activity. Mn2+ added to and incubated with the native enzyme, the 65Zn2(+)-, the Co2(+)-, or the Cd2(+)- substituted form of the enzyme stimulates dehydrogenase activity to the same extent. These studies along with previously observed structural homologies further establish threonine dehydrogenase of E. coli as a member of the zinc-containing long chain alcohol/polyol dehydrogenases; it is unique among these enzymes in that its activity is stimulated by Mn2+ or Cd2+.     

Inactivation of Escherichia coli L-threonine dehydrogenase by 2,3-butanedione. Evidence for a catalytically essential arginine residue

Incubation of homogeneous preparations of L-threonine dehydrogenase from Escherichia coli with 2,3-butanedione, 2,3-pentanedione, phenylglyoxal, or 1,2-cyclohexanedione causes a time- and concentration-dependent loss of enzymatic activity; plots of log percent activity remaining versus time are linear to greater than 90% inactivation, indicative of pseudo-first order inactivation kinetics. The reaction order with respect to the concentration of modifying reagent is approximately 1.0 in each case suggesting that the loss of catalytic activity is due to one molecule of modifier reacting with each active unit of enzyme. Controls establish that this inactivation is not due to modifier-induced dissociation or photoinduced nonspecific alteration of the dehydrogenase. Essentially the same Km but decreased Vmax values are obtained when partially inactivated enzyme is compared with native. NADH (25 mM) and NAD+ (70 mM) give full protection against inactivation whereas much higher concentrations (i.e. 150 mM) of L-threonine or L-threonine amide provide a maximum of 80-85% protection. Amino acid analyses coupled with quantitative sulfhydryl group determinations show that enzyme inactivated 95% by 2,3-butanedione loses 7.5 arginine residues (out of 16 total)/enzyme subunit with no significant change in other amino acid residues. In contrast, only 2.4 arginine residues/subunit are modified in the presence of 80 mM NAD+. Analysis of the course of modification and inactivation by the statistical method of Tsou (Tsou, C.-L. (1962) Sci. Sin. 11, 1535-1558) demonstrates that inactivation of threonine dehydrogenase correlates with the loss of 1 "essential" arginine residue/subunit which quite likely is located in the NAD+/NADH binding site.     

The sulfhydryl content of L-threonine dehydrogenase from Escherichia coli K-12: relation to catalytic activity and Mn2+ activation

When oxidized to cysteic acid by performic acid or converted to carboxymethylcysteine by alkylation of the reduced enzyme with iodoacetate, a total of six half-cystine residues/subunit are found in L-threonine dehydrogenase (L-threonine: NAD+ oxidoreductase, EC 1.1.1.103; L-threonine + NAD(+)----2-amino-3-oxobutyrate + NADH) from Escherichia coli K-12. Of this total, two exist in disulfide linkage, whereas four are titratable under denaturing conditions by dithiodipyridine, 5,5'-dithiobis(2-nitrobenzoic acid), or p-mercuribenzoate. The kinetics of enzyme inactivation and of modification by the latter two reagents indicate that threonine dehydrogenase has no free thiols that selectively react with bulky compounds. While incubation of the enzyme with a large excess of iodoacetamide causes less than 10% loss of activity, the native dehydrogenase is uniquely reactive with and completely inactivated by iodoacetate. The rate of carboxymethylation by iodoacetate of one -SH group/subunit is identical with the rate of inactivation and the carboxymethylated enzyme is no longer able to bind Mn2+. NADH (0.5 mM) provides 40% protection against this inactivation; 60 to 70% protection is seen in the presence of saturating levels of NADH plus L-threonine. Such results coupled with an analysis of the kinetics of inactivation caused by iodoacetate are interpreted as indicating the inhibitor first forms a reversible complex with a positively charged moiety in or near the microenvironment of a reactive -SH group in the enzyme before irreversible alkylation occurs. Specific alkylation of one -SH group/enzyme subunit apparently causes protein conformational changes that entail a loss of catalytic activity and the ability to bind Mn2+.     

The primary structure of Escherichia coli K12 aspartokinase I-homoserine dehydrogenase I. Site of limited proteolytic cleavage by subtilisin.

The sequence of the first 25 residues of the homoserine dehydrogenase fragment, produced by limited proteolysis of aspartokinase I-homoserine dehydrogenase I with substilisin, has been determined. The sequence of a cyanogen bromide peptide (CB5, 59 residues), isolated from the entire protein, is also presented. Residues 1 to 18 of the subtilisin homoserine dehydrogenase fragment match the sequence 42 to 59 of peptide CB5.     

Aspartokinase I-homoserine dehydrogenase I of Escherichia coli K12. Concentration-dependent dissociation to dimers in the presence of L-threonine.

The concentration-dependent association-dissociation equilibrium of the bifunctional enzyme aspartokinase I-homoserine dehydrogenase I of Escherichia coli K12 has been investigated at pH 7.6 in the presence of 10 mM L-threonine and 0.1 M KCl by equilibrium gel permeation monitored by a single-photon counting spectrophotometer. The results obtained are consistent with the existence of a dimer-tetramer equilibrium with the association constant of 2.6 X 10(7) M-1 (deltaG0 = -9.9 kcal/mol of dimer). The limiting partition cross-sections estimated by a three-parameter least squares minimization procedure indicate that the molecular radii of the dimer and tetramer are 53.8 A and 70 A, respectively. Both the dimeric and tetrameric forms of the enzyme possess dehydrogenase activity. Treatment of the enzyme with the chaotropic salts, potassium thiocyanate or potassium trichloroacetate, generates a monomeric form that is devoid of dehydrogenase activity. The catalytically inactive monomeric form of the enzyme has a molecular radius between 43 and 45.5 A and a molecular weight of approximately 80,000 as determined by small zone gel chromatography and sedimentation equilibrium studies.     

Escherichia coli alpha-ketoglutarate dehydrogenase complex

The alpha-ketoglutarate dehydrogenase complex from Escherichia coli catalyzes the hydrolysis of S-succinyl-CoA to succinate and CoASH. The reaction rate is dependent upon the presence of thiamin pyrophosphate and NADH, as well as the functional integrity of the alpha-lipoyl groups associated with the enzyme. The Km value for S-succinyl-CoA is 9.3 X 10(-5) M, and the maximum velocity is 0.02 mumol X min-1 X mg of protein-1 at pH 7 and 25 degrees C. This hydrolysis can be rationalized on the basis that succinyl thiamin pyrophosphate is generated under reductive succinylation conditions. Occasional diversion of succinyl thiamin pyrophosphate to hydrolysis produces succinate.     

Stability of Escherichia coli strains harboring recombinant plasmids for L-threonine production

Escherichia coli recombinant strains bearing the thr operon have been previously selected for threonine production and phenotypically classified according to antibiotic resistance properties (Nudel et al. 1987).Further analysis of those strains permitted the isolation and restriction mapping of two different plasmids of 13 kb and 18.6 kb. The smaller one, which expressed tetracycline resistance gave better results on threonine accumulation but it was rather unstable when grown without antibiotic pressure. Therefore, other hosts were transformed with those plasmids to improve stability.A threonine-auxotrophic strain was a better host for plasmid maintenance and expression of thr operon. Host influence in plasmid-mediated threonine production was studied in terms of specific yields (the ratios of threonine accumulated to biomass values) and of plasmid maintenance (percent of Ap^rTc^r clones after cultivation in non selective media).We also determined that semisynthetic media of defined composition were better than rich media for threonine expression, due to feed-back controls exerted by undesired catabolites accumulated in complex media.     

Metabolic engineering of a reduced-genome strain of Escherichia coli for L-threonine production

Background  

Deletion of large blocks of nonessential genes that are not needed for metabolic pathways of interest can reduce the production of unwanted by-products, increase genome stability, and streamline metabolism without physiological compromise. Researchers have recently constructed a reduced-genome Escherichia coli strain MDS42 that lacks 14.3% of its chromosome.