Catabolite inactivation of biodegradative threonine dehydratase of Escherichia coli.

Incubation of Escherichia coli cells with glucose, pyruvate, and certain other metabolites led to rapid inactivation of inducible biodegradative threonine dehydratase. Analysis with several mutant strains showed that pyruvate, and not a metabolite derived from pyruvate, was capable of inactivating enzyme, and that glucose acted indirectly after being converted to pyruvate. Some other alpha-keto acids such as oxaloacetate and alpha-ketobutyrate (but not alpha-ketoglutarate) were also effective. Inactivation of threonine dehydratase by pyruvate was also observed with purified enzyme preparations. The rates of enzyme inactivation increased with increased concentrations of pyruvate and decreased with increased levels of AMP. Increasing protein concentrations lowered the rates of enzyme inactivation. Dithiothreitol had a large effect on the maximum extent of inactivation of the enzyme by pyruvate; high concentrations of AMP and DTT almost completely counteracted the effect of pyruvate. Gel filtration data showed that pyruvate influenced the oligomeric state of the enzyme by altering the association-dissociation equilibrium in favor of dissociation; the Stokes' radius of the pyruvate-inactivated enzyme was 32 A as compared to 42 A for the untreated enzyme. Reassociation of the dissociated form of the enzyme was achieved by removal of excess free pyruvate by dialysis against buffer supplemented with AMP and DTT. Incubation of threonine dehydratase with [14-C]pyruvate revealed apparent covalent attachment of pyruvate to the enzyme. Strong protein denaturants such as guanidine, urea, and sodium dodecyl sulfate failed to release bound radioactive pyruvate; the molar ratio of firmly bound pyruvate was approximately 1 mol/150,000 g of protein. Pretreatment of the enzyme with p-chloromercuribenzoate and 5,5'-dithiobis(2-nitrobenzoate) (Nbs2) did not reduce the binding of [14-C]pyruvate suggesting no active site SH was involved in the pyruvate-enzyme linkage. Titration of active and pyruvate-inactivated enzyme with Nbs2 indicated that the loss in enzyme activity was not due to oxidation of essential sulfhydryl groups on the enzyme. Based on these data we propose that the mechanism of enzyme inactivation by pyruvate involves covalent attachment of pyruvate to the active oligomeric form of the enzyme followed by dissociation of the oligomer to yield inactive enzyme.     

Requirements for induction of the biodegradative threonine dehydratase in Escherichia coli.

Synthesis of the biodegradative L-threonine dehydratase in Escherichia coli, Crookes strain, was prevented by dissolved oxygen concentrations of 6 micrometer or greater. This effect was shown to be exerted solely on synthesis, rather than being the result of enzyme inactivation in vivo. In addition to an anaerobic environment, maximum enzyme synthesis was dependent upon the presence of a complete complement of amino acids, with omission of L-threonine, L-valine, or L-leucine producing the largest decreases in enzyme formation. L-Threonine, the most essential of the amino acid requirements, could be partially replaced by DL-allothreonine or alpha-ketobutyrate. Half-maximal stimulation of enzyme synthesis occurred with 0.4 mM threonine in the medium. The roles of anaerobiosis and amino acids are interpreted as being in accord with the concept that threonine dehydratase functions in anaerobic energy production under conditions of amino acid sufficiency.     

Increased expression of biodegradative threonine dehydratase of Escherichia coli by DNA gyrase inhibitors

The synthesis of inducible biodegradative threonine dehydratase of Escherichia coli increased several-fold in the presence of the DNA gyrase inhibitors, nalidixic acid and coumermycin. Temperature-sensitive gyrB mutants expressed higher levels of dehydratase as compared to an isogenic gyrB+ strain. Immunoblotting experiments showed increased synthesis of the dehydratase protein in the presence of gyrase inhibitors; addition of rifampicin and chloramphenicol to cells actively synthesizing enzyme preventing new enzyme production. Increased expression of dehydratase by gyrase inhibitors was accompanied by relaxation of supercoiled DNA.     

Escherichia coli K-12 mutation that inactivates biodegradative threonine dehydratase by transposon Tn5 insertion.

From a collection of kanamycin-resistant mutants of Escherichia coli K-12 isolated by transposon Tn5 mutagenesis, we have identified a mutant that lacks functional biodegradative threonine dehydratase (EC 4.2.1.16) by direct enzyme assay and by the loss of cross-reacting material with affinity-purified antibodies against the purified enzyme. Aerobic and anaerobic growth of this strain on various carbon sources failed to reveal a phenotype. Evidence for the insertional inactivation of threonine dehydratase by Tn5 was obtained by cloning the DNA segments flanking the Tn5 insertion site into pBR322 and hybridizing the cloned DNA to a synthetic oligodeoxynucleotide probe complementary to the DNA segment coding for a unique hexapeptide at the amino terminus end of the enzyme; the region of homology to the synthetic cDNA sequence appears to be located within about 500 nucleotides from one end of Tn5. Genetic analysis with the transposon element that caused insertional inactivation located the tdc gene at min 67 on the E. coli chromosome.     

Photoaffinity labeling of the allosteric AMP site of biodegradative threonine dehydratase of Escherichia coli with 8-azido-AMP

The photoreactive AMP analog, 8-azido-AMP, stimulated the activity of biodegradative threonine dehydratase of Escherichia coli in a reversible manner and, like AMP, decreased the Km for threonine. The concentrations required for half-maximal stimulation by AMP and 8-azido-AMP were 40 microM and 1.5 microM, respectively, and the maximum stimulation by 8-azido-AMP was 25% of that seen with AMP. Gel-filtration experiments revealed that 8-azido-AMP stabilized a dimeric form of the enzyme, whereas AMP promoted a tetrameric species. When present together, AMP and 8-azido-AMP showed mutual competition in influencing catalytic activity as well as the conformational state of the protein. Photolabeling of AMP-free dehydratase with 8-azido-[2-3H]AMP resulted in a time and concentration-dependent enzyme inactivation and concomitant incorporation of 8-azido-AMP into protein. At low 8-azido-AMP concentrations, incorporation of about 1 mol 8-azido-AMP/mol dehydratase tetramer was correlated with almost complete inactivation of the enzyme. The presence of AMP in the photolabeling reaction greatly reduced the extent of enzyme inactivation and 8-azido-AMP binding. Ultraviolet irradiation with 20 microM 3H-labeled 8-azido-AMP revealed one tryptic peptide, Thr230-Thr-Gly-Thr-Leu-Ala-Asp-Gly-Cys-Asp-Val-Ser-Arg242, with bound radioactivity. This peptide, labeled at low concentration of 8-azido-AMP, most likely represents the AMP-binding region on the dehydratase molecule.     

Cloning and overproduction of biodegradative threonine deaminase from Escherichia coli W strain.

We have cloned the structural gene (tdcB) of biodegradative threonine deaminase from Escherichia coli W strain by utilizing the polymerase chain reaction. The JM109/pUCTDA strain, which was obtained by transforming E. coli JM109 with a vector plasmid (pUCTDA) containing the cloned tdcB gene, produced a large amount of the enzyme corresponding to more than 5% of the total soluble protein. Amino acid sequence analysis of this recombinant enzyme showed that the amino acid sequence is identical to the nucleotide-deduced sequence of biodegradative threonine deaminase from E. coli K-12.     

Synthesis of biodegradative threonine dehydratase in Escherichia coli: role of amino acids, electron acceptors, and certain intermediary metabolites

The specific activity of inducible biodegradative threonine dehydratase (EC 4.2.1.16) in Escherichia coli K-12 increased significantly when the standard tryptone-yeast extract medium or a synthetic mixture of 18 L-amino acids was supplemented with 10 mM KNO3 or 50 mM fumarate and with 4 mM cyclic AMP. In absolute terms, almost four times as much enzyme was produced in the amino acid medium as in the tryptone-yeast extract medium. Enzyme induction in the amino acid medium was sensitive to catabolite repression by glucose, gluconate, glycerol, and pyruvate. An analysis of amino acid requirements for enzyme induction showed that a combination of only four amino acids, threonine, serine, valine, and isoleucine, produced high levels of threonine dehydratase provided that both fumarate and cyclic AMP were present. Immunochemical data revealed that the enzyme synthesized in the presence of these four amino acids was indistinguishable from that produced in the tryptone-yeast extract or the medium with 18 amino acids. We interpret these results to mean that not the amino acids themselves but some metabolites derived anaerobically in reactions involving an electron acceptor may function as putative regulatory molecule(s) in the anaerobic induction of this enzyme.     

Amino acid sequence of a peptide containing an essential cysteine residue of Escherichia coli GMP synthetase.

The amino acid sequence of a 51-residue tryptic peptide of citraconylated [1-14C]carboxamidomethyl-labeled Escherichia coli GMP synthetase was determined by sequenator analyses of the intact peptide and fragments obtained by cleavage of the peptide with cyanogen bromide, trypsin, and Staphylcoccus aureus strain V8 protease. The cysteine residue of this peptide fragment is essential for glutamine-dependent GMP synthesis activity and is implicated in formation of a hypothetical covalent glutamyl-enzyme intermediate. There is essentially cysteine-containing regions of two other glutamine amidotransferases, Pseudomonas putida anthranilate synthetase Component II and chicken liver formylglycinamide ribonucleotide amidotransferase. There is, however, a cluster of amino acids with "antipathy" for helix formation and a "nonessential" cysteine of anthranilate synthetase Component II.     

Amino acid sequence of the ribosomal protein L21 of Escherichia coli.

The primary structure of protein L21 from the 50S subunit of Escherichia coli ribosomes has been completely determined by sequencing the peptides obtained by digestion of L21 with trypsin before and after modification of the arginine residues with 1,2-cyclohexanedione, Staphylococcus aureus protease, thermolysin, and pepsin. Automated Edman degradation using a liquid-phase sequenator was carried out on the intact protein as well as on a fragment arising from cleavage with cyanogen bromide. Protein L21 consists of a single polypeptide chain of 103 amino acids of molecular weight 11 565. An estimation of the secondary structure of protein L21 and a comparison with other E. coli ribosomal protein sequences are presented.     

Amino acid sequence of the L-arabinose-binding protein from Escherichia coli B/r.

The amino acid sequence of the L-arabinose-binding protein of Escherichia coli B/r was determined by sequenator analyses of reduced and S-pyridylethylated L-arabinose-binding protein and fragments derived by chemical and enzymatic cleavage of the native protein. The fragments were the products of cleavage by cyanogen bromide. BNPS-skatole, hydroxylamine, mild acid hydrolysis, limited trypsin digestion, chymotrypsin subdigestion, and subdigestion with Staphylococcus aureus protease V8. The COOH-terminal sequence was determined using bovine carboxypeptidases A and B and amino acid analyses. The L-arabinose-binding protein was determined to contain 306 amino acid residues, the sequence of which is presented below.     

Amino acid sequence of Escherichia coli glutamine synthetase deduced from the DNA nucleotide sequence

Glutamine synthetase is encoded by the glnA gene of Escherichia coli and catalyzes the formation of glutamine from ATP, glutamate, and ammonia. A 1922-base pair fragment from a cDNA containing the glnA structural gene for E. coli glutamine synthetase has been sequenced. An open reading frame of 1404 base pairs encodes a protein of 468 amino acid residues with a calculated molecular weight of 51,814. With few exceptions, the amino acid sequence deduced from the DNA sequence agreed very well with the amino acid sequences of several peptides reported previously. The secondary structure predicted for the E. coli enzyme has approximately 36% of the residues in alpha-helices which is in agreement with calculations of approximately 39% based on optical rotatory dispersion data. Comparison of the amino acid sequences of glutamine synthetase from E. coli (468 amino acids) and Anabaena (473 amino acids) (Turner, N. E., Robinson, S. T., and Haselkorn, R. (1983) Nature 306, 337-342) indicates that 260 amino acids are identical and 80 are of the same type (polar or nonpolar) when aligned for maximum homology. Several homologous regions of these two enzymes exist, including the sites of adenylylation and oxidative modification, but the regulation of each enzyme is different.     

Amino acid sequence around lipoic acid residues in the pyruvate dehydrogenase multienzyme complex of Escherichia coli.

Amino-acid sequences around two lipoic acid residues in the lipoate acetyltransferase component of the pyruvate dehydrogenase complex of Escherichia coli were investigated. A single amino acid sequence of 13 residues was found. A repeated amino acid sequence in the lipoate acetyltransferase chain might explain this result.