Roles of glutamate synthase, gltBD, and gltF in nitrogen metabolism of Escherichia coli and Klebsiella aerogenes.

Mutants of Escherichia coli and Klebsiella aerogenes that are deficient in glutamate synthase (glutamate-oxoglutarate amidotransferase [GOGAT]) activity have difficulty growing with nitrogen sources other than ammonia. Two models have been proposed to account for this inability to grow. One model postulated an imbalance between glutamine synthesis and glutamine degradation that led to a repression of the Ntr system and the subsequent failure to activate transcription of genes required for the use of alternative nitrogen sources. The other model postulated that mutations in gltB or gltD (which encode the subunits of GOGAT) were polar on a downstream gene, gltF, which is necessary for proper activation of gene expression by the Ntr system. The data reported here show that the gltF model is incorrect for three reasons: first, a nonpolar gltB and a polar gltD mutation of K. aerogenes both show the same phenotype; second, K. aerogenes and several other enteric bacteria lack a gene homologous to gltF; and third, mutants of E. coli whose gltF gene has been deleted show no defect in nitrogen metabolism. The argument that accumulated glutamine represses the Ntr system in gltB or gltD mutants is also incorrect, because these mutants can derepress the Ntr system normally so long as sufficient glutamate is supplied. Thus, we conclude that gltB or gltD mutants grow slowly on many poor nitrogen sources because they are starved for glutamate. Much of the glutamate formed by catabolism of alternative nitrogen sources is converted to glutamine, which cannot be efficiently converted to glutamate in the absence of GOGAT activity. Finally, GOGAT-deficient E. coli cells growing with glutamine as the sole nitrogen source increase their synthesis of the other glutamate-forming enzyme, glutamate dehydrogenase, severalfold, but this is still insufficient to allow rapid growth under these conditions.

Growth inhibition caused by overexpression of the structural gene for glutamate dehydrogenase (gdhA) from Klebsiella aerogenes.

Two linked mutations affecting glutamate dehydrogenase (GDH) formation (gdh-1 and rev-2) had been isolated at a locus near the trp cluster in Klebsiella aerogenes. The properties of these two mutations were consistent with those of a locus containing either a regulatory gene or a structural gene. The gdhA gene from K. aerogenes was cloned and sequenced, and an insertion mutation was generated and shown to be linked to trp. A region of gdhA from a strain bearing gdh-1 was sequenced and shown to have a single-base-pair change, confirming that the locus defined by gdh-1 is the structural gene for GDH. Mutants with the same phenotype as rev-2 were isolated, and their sequences showed that the mutations were located in the promoter region of the gdhA gene. The linkage of gdhA to trp in K. aerogenes was explained by postulating an inversion of the genetic map relative to other enteric bacteria. Strains that bore high-copy-number clones of gdhA displayed an auxotrophy that was interpreted as a limitation for alpha-ketoglutarate and consequently for succinyl-coenzyme A (CoA). Three lines of evidence supported this interpretation: high-copy-number clones of the enzymatically inactive gdhA1 allele showed no auxotrophy, repression of GDH expression by the nitrogen assimilation control protein (NAC) relieved the auxotrophy, and addition of compounds that could increase the alpha-ketoglutarate supply or reduce the succinyl-CoA requirement relieved the auxotrophy.

Genetic analysis, using P22 challenge phage, of the nitrogen activator protein DNA-binding site in the Klebsiella aerogenes put operon.

The nac gene product is a LysR regulatory protein required for nitrogen regulation of several operons from Klebsiella aerogenes and Escherichia coli. We used P22 challenge phage carrying the put control region from K. aerogenes to identify the nucleotide residues important for nitrogen assimilation control protein (NAC) binding in vivo. Mutations in an asymmetric 30-bp region prevented DNA binding by NAC. Gel retardation experiments confirmed that NAC specifically binds to this sequence in vitro, but NAC does not bind to the corresponding region from the put operon of Salmonella typhimurium, which is not regulated by NAC.

Activation of transcription initiation from the nac promoter of Klebsiella aerogenes.

The nac gene of Klebsiella aerogenes encodes a bifunctional transcription factor that activates or represses the expression of several operons under conditions of nitrogen limitation. In experiments with purified components, transcription from the nac promoter was initiated by sigma 54 RNA polymerase and was activated by the phosphorylated form of nitrogen regulator I (NRI) (NtrC). The activation of the nac promoter required a higher concentration of NRI approximately P than did the activation of the Escherichia coli glnAp2 promoter, and both the promoter and upstream enhancer element contributed to this difference. The nac promoter had a lower affinity for sigma 54 RNA polymerase than did glnAp2, and uninitiated competitor-resistant transcription complexes formed at the nac promoter decayed to competitor-sensitive complexes at a greater rate than did similar complexes formed at the glnAp2 promoter. The nac enhancer, consisting of a single high-affinity NRI-binding site and an adjacent site with low affinity for NRI, was less efficient in stimulating transcription than was the glnA enhancer, which consists of two adjacent high-affinity NRI-binding sites. When these binding sites were exchanged, transcription from the nac promoter was increased and transcription from the glnAp2 promoter was decreased at low concentrations of NRI approximately P. Another indication of the difference in the efficiency of these enhancers is that although activation of a nac promoter construct containing the glnA enhancer was relatively insensitive to subtle alterations in the position of these sites relative to the position of the promoter, activation of the natural nac promoter or a nac promoter construct containing only a single high-affinity NRI approximately P binding site was strongly affected by subtle alterations in the position of the NRI approximately P binding site(s), indicating a face-of-the-helix dependency for activation.

Repression of the Klebsiella aerogenes nac promoter.

Transcription of the nitrogen-regulated nac promoter of Klebsiella aerogenes requires sigma54 RNA polymerase, is activated by the phosphorylated form of the transcription factor nitrogen regulator I (NRI) (NtrC), and is repressed by the product of the nac gene, Nac. Nac protects a large portion of the nac control region, extending from positions -130 to -70, from digestion by DNase I. This site(s) lies immediately upstream from the site at which sigma 54 RNA polymerase binds, is downstream of a high-affinity binding site for the transcriptional activator NRI approximately P, and partially overlaps a low-affinity NRI approximately P-binding site. Binding of Nac to the DNA resulted in bending of the DNA but did not interfere with the binding of sigma 54 RNA polymerase to the promoter or with the binding of NRI approximately P to either the high-affinity site or low-affinity site. Furthermore, transcription assays with various wild-type and mutant templates suggested that Nac did not exclude NRI approximately P from either the low- or high-affinity sites, nor did Nac interfere with the ability of the polymerase to form the open complex when the binding sites for NRI approximately P were moved to different locations upstream from the promoter. Rather, Nac seemed to repress by an antiactivation mechanism in which the interaction of the NRI approximately P, bound at its normal sites, with sigma 54 RNA polymerase, bound to the promoter, was prevented.

The nitrogen assimilation control protein, NAC, is a DNA binding transcription activator in Klebsiella aerogenes.

A 32-kDa polypeptide corresponding to NAC, the product of the Klebsiella aerogenes nac gene, was overexpressed from a plasmid carrying a tac'-'nac operon fusion and purified to near homogeneity by taking advantage of its unusual solubility properties. NAC was able to shift the electrophoretic migration of DNA fragments carrying the NAC-sensitive promoters hutUp, putPp1, and ureDp. The interaction between NAC and hutUp was localized to a 26-bp region centered approximately 64 bp upstream of the hutUp transcription initiation site. Moreover, NAC protected this region from DNase I digestion. Mobility shift and DNase I protection studies utilizing the putP and ureD promoter regions identified NAC-binding regions of sizes and locations similar to those found in hutUp. Comparison of the DNA sequences which were protected from DNase I digestion by NAC suggests a minimal NAC-binding consensus sequence: 5'-ATA-N9-TAT-3'. In vitro transcription assays demonstrated that NAC was capable of activating the transcription of hutUp by sigma 70-RNA polymerase holoenzyme when this promoter was presented as either a linear or supercoiled DNA molecule. Thus, NAC displays the in vitro DNA-binding and transcription activation properties which have been predicted for the product of the nac gene.

Cloning, characterization, and complementation of lesions causing acid sensitivity in Tn5-induced mutants of Rhizobium meliloti WSM419.

Four Tn5-induced mutants of Rhizobium meliloti WSM419 were unable to grow or maintain intracellular pH at an external pH of 5.6. Restriction analysis of DNA fragments carrying Tn5 and flanking sequences cloned from these mutants indicated that all four cloned mutations are unique and that the two strains (TG1-6 and TG1-11) carry Tn5 insertions which are within 4.4 kilobases of each other on a single EcoRI fragment. Southern analysis of total mutant DNA indicated a single copy of Tn5 in each mutant. A limited cosmid gene bank of wild-type WSM419 DNA was probed for homology to mutant DNA cloned from the acid-sensitive mutants. Dot hybridization experiments identified one cosmid element within this bank carrying wild-type DNA sequences corresponding to DNA implicated in acid tolerance. This cosmid was able to complement defects in growth and intracellular pH maintenance in TG1-11 but not TG1-6.

Molecular characterization of the tdc operon of Escherichia coli K-12.

The nucleotide sequence of a 2-kilobase DNA fragment of the tdc region of Escherichia coli K-12, previously cloned in this laboratory, revealed two open reading frames, tdcC and ORFX, downstream from the tdcB gene (formerly designated tdc) encoding biodegradative threonine dehydratase. A 24-base-pair sequence separated tdcC from the dehydratase coding region, and an untranslated region of 60 nucleotides, which contains a recognizable -10 consensus sequence, was found between tdcC and ORFX. The deduced amino acid sequence of tdcC showed it to be a large hydrophobic polypeptide of 431 amino acid residues, whereas ORFX coded for a small 135-residue polypeptide lacking glutamine and tryptophan. A computer-assisted sequence analysis revealed no similarity among the tdcB, tdcC, and ORFX polypeptides, and a search of the GenBank database failed to detect similarity with any other known proteins. The tdc genes and ORFX showed similar codon usage and, in analogy with other bacterial genes, showed codon usage typical for genes expressed at an intermediate level. Transcriptional analysis with S1 nuclease indicated two distinct transcription start sites upstream of the tdcB gene in regions previously identified as promoterlike elements P1 and P2. Interestingly, expression of tdcB and tdcC, but not ORFX, was contingent upon the presence of P1. These results taken together tend to suggest that the biodegradative threonine dehydratase is the second gene in a polycistronic transcription unit constituting a novel operon (tdcABC) in E. coli implicated in anaerobic threonine metabolism.

Covalent structure of biodegradative threonine dehydratase of Escherichia coli: homology with other dehydratases.

The 987-base-pair coding region of the tdc gene of Escherichia coli K-12 encoding biodegradative threonine dehydratase [Tdc; L-threonine hydro-lyase (deaminating), EC 4.2.1.16], previously cloned in this laboratory, was sequenced. The deduced polypeptide consists of 329 amino acid residues with a calculated Mr of 35,238. Although the purified enzyme was shown to contain tryptophan, no tryptophan codon was found in the tdc reading frame. Incubation of purified Tdc with [14C]tryptophan revealed apparent "covalent" binding of tryptophan, indicating posttranslational modification of the enzyme. A heptapeptide, 54Thr-55Gly-56Ser-57Phe-58Lys-59Ile- 60Arg, was found to contain Lys-58, which binds pyridoxal phosphate coenzyme. A comparison of amino acid sequences between the Tdc polypeptide and the biosynthetic threonine dehydratases of yeast (encoded by ILV1) and E. coli (encoded by ilvA) and the E. coli D-serine dehydratase (DsdA, encoded by dsdA) revealed various extents of homology: five domains of the Tdc polypeptide were 63-93% homologous with the yeast enzyme, and three of these same regions were 80% homologous with the biosynthetic E. coli dehydratase; two different domains showed 67% and 83% homology with DsdA. In addition, two other sequences were highly conserved in all four proteins, one of which was shown to contain the conserved lysine residue that binds pyridoxal phosphate in the Tdc and DsdA polypeptides. These observations suggest that, despite their diverse origin and metabolic significance, these enzymes may have evolved from a common ancestral protein.

Molecular cloning and expression of the biodegradative threonine dehydratase gene (tdc) of Escherichia coli K12.

The biodegradative threonine dehydratase gene (tdc) of Escherichia coli was cloned by isolating a dehydratase negative mutant after Tn5 mutagenesis, cloning the tdc::Tn5 DNA into pBR322 and then replacing the Tn5 element on the plasmid in vivo. Subcloning and nucleotide sequence data revealed two distinct procaryotic promoter-like elements each containing a potential CAP-binding site and AT-rich regions, and a Shine-Dalgarno sequence. One of these putative promoters, P2, was located immediately upstream from the tdc coding region, and a second, P1, was approximately 1 kilobase upstream from P2. Deletion of the potential CAP-binding site from P1 prevented tdc gene expression. However, removal of P2 and a large segment of the upstream DNA had no discernible effect on dehydratase synthesis. A 936-base pair open reading frame was found between P1 and the tdc coding region, which produced a polypeptide of about 32 kilodaltons. The data suggest that P1, and not P2, is necessary for tdc gene expression, and that the DNA sequences coding for the 32 KD polypeptide and threonine dehydratase are part of a single transcriptional unit.

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.