gltF, a member of the gltBDF operon of Escherichia coli, is involved in nitrogen-regulated gene expression

We report here the construction and analysis of insertional mutations in each of the three genes of the gltBDF operon and the nucleotide sequence of the region downstream from gltD. Two open reading frames were identified, the first of which corresponds to gltF. The gltB and gltD genes code for the large and small subunits, respectively, of the enzyme glutamate synthase (GOGAT). gltF codes for a protein, with a molecular mass of 26,350 Da, which is required for Ntr induction. Histidase synthesis was determined as a measure of Ntr function. First, insertions in gltB, gltD or gltF all prevent Ntr induction. Second, complementation analysis indicates that high-level expression of both the gltD and gltF genes is required for the induction of the Ntr enzymes under nitrogen-limiting conditions, indicating that the phenotype of the gltB insertion probably results from polarity on gltD and gltF. Third, glutamate-dependent repression of the glt operon appears to be mediated by the product of the gltF gene. Thus, the gltBDF operon of Escherichia coli is involved in induction of the so-called Ntr enzymes in response to nitrogen deprivation, as well as in glutamate biosynthesis.     

Detecting non-neutral heterogeneity across a region of DNA sequence in the ratio of polymorphism to divergence

Natural selection, in the form of balancing selection or selective sweeps, can result in a decoupling of the amounts of molecular polymorphism and divergence. Thus natural selection can cause some areas of DNA sequence to have greater silent polymorphism, relative to divergence between species, than other areas. It would be useful to have a statistical test for heterogeneity in the polymorphism to divergence ratio across a region of DNA sequence, one that could identify heterogeneity greater than that expected from the neutral processes of mutation, drift, and recombination. The only currently available test requires that a region be arbitrarily divided into sections that are compared with each other, and the subjectivity of this division could be problematic. Here a test is proposed in which runs of polymorphic and fixed sites are counted, where a "run" is a set of one or more sites of one type preceded and followed by the other type. The number of runs is smaller than otherwise expected if polymorphisms are clumped together. By simulating neutral evolution and comparing the observed number of runs to the simulations, a statistical test is possible which does not require any a priori decisions about subdivision.      

ColE1 hybrid plasmids containing Escherichia coli genes involved in the biosynthesis of glutamate and glutamine

The Clarke-Carbon bank of Escherichia coli strains carrying ColE1 hybrid plasmids was screened for complementation of gdh, gltB, and glnA mutations affecting nitrogen metabolism in E. coli. Plasmids which complemented each one of these mutations were isolated. In every case, the plasmids conferred to otherwise mutant cells the capacity to synthesize the corresponding wild-type enzymes: glutamate dehydrogenase, glutamate synthase, and glutamine synthetase (GS), respectively. For three representative plasmids, endonuclease restriction maps were constructed. One of the plasmids, pACR1, which complemented glnA mutations, including the glnA21::Tn5 insertion, was deemed to carry the glnA⁺ allele. GS synthesis by pACR1 $\text{glnA}{}^{\mathrm{+}}\text{glnA20}$ heterozygous merodiploids was subjected to repression by growth on 15 mm NH₄⁺ and had a twofold high derepressed level than wild-type (glnA⁺) haploid cells when grown on 0.5 mm NH₄⁺ or on glutamate as only nitrogen sources. The presence of glutamine as sole nitrogen source promoted repressed GS synthesis in the $\text{glnA}{}^{\mathrm{+}}\text{glnA20}$ merodiploids. By contrast, glutamine allowed almost fully derepressed synthesis of GS in glnA⁺ haploid cells.     

Tight linkage of genes that encode the two glutamate synthase subunits of Escherichia coli K-12.

A hybrid deoxyribonucleic acid molecule, plasmid pRSP20, which was isolated from the Clarke and Carbon Escherichia coli gene bank, was shown to complement the gltB31 mutation, which affects the synthesis of glutamate synthase in E. coli strain PA340. We present evidence which demonstrates that plasmid pRSP20 carries an 8-megadalton E. coli chromosomal fragment, including the genes encoding the two unequal glutamate synthase subunits. Polypeptides with molecular weights of about 135,000 and 53,000, which comigrated with purified E. coli glutamate synthase subunit polypeptides and immunoprecipitated with antibodies to E. coli glutamate synthase, were synthesized by minicells carrying the pRSP20 plasmid.     

Biochemical and genetic characterization of a carbamyl phosphate synthetase mutant of Escherichia coli K12.

An unusual Escherichia coli K12 mutant for carbamyl phosphate synthetase is described. The mutation was generated by bacteriophage MUI insertion and left a 5% residual activity of the enzyme using either ammonia or glutamine as donors. The mutation is recessive to the wild-type allele and maps at or near the pyrA gene, but the mutant requires only arginine and not uracil for growth. By a second block in the pyrB gene it was possible to shift the accumulated carbamyl phosphate to arginine biosynthesis. The Km values and the levels of ornithine activation and inhibition by UMP were normal in the mutant enzyme.