Expression of the amino acid operons in Escherichia coli strains with an altered transcription and translation apparatus. IV. The effect of mutations disturbing the coupling of the transcription and translation processes on ilv-operon expression in cells carrying the mutation in the spoT gene

The rate of adaptation of Escherichia coli K-12 NF930 spoT1 cells with elevated intracellular level of ppGpp to various minimal media was studied. It has been found that the rate of adaptation of spoT cells, like that of parent and rel strains, depends mainly on the rate of derepression of the ilv operon. The maximal rate of the ilv operon derepression was observed when an optimal concentration of ppGpp was maintained in cells. Derepression of the ilv operon is sharply delayed when the level of ppGpp is elevated or reduced. Mutations altering the translation system do not change the rate of adaptation of spoT cells. Rifampicin resistance mutations which altered the structure of RNA polymerase change the rate of adaptation of spoT cells to minimal media, especially to those containing serine at high concentrations. The possible role of serine in the regulation of ppGpp degradation system is discussed.     

Functioning of amino acid operons in Escherichia coli strains with an altered transcription and translation apparatus. I. The effect of mutations in gene rpsL coding ribosomal protein S12 on the functioning of the ilv operon

Derepression of the ilv operon in rel strains of Escherichia coli is delayed when cells are transferred from rich to minimal medium and is completely blocked when the mixture of amino acids--serine, methionine and glycine is present in the minimal medium. It is shown that alterations in translation machinery caused by streptomycine resistance mutation can also lead to the delay of the ilv operon derepression in rel+ strains or to its complete inhibition in rel strains of E. coli. The possible mechanisms of high sensitivity of the ilv operon to different alterations in E. coli are discussed.     

Functioning of amino acid operons in Escherichia coli strains with an altered transcription and translation apparatus. II. The effect of mutations in genes coding ribosomal protein S5 and translation elongation factor G on the functioning of the ilv operon

It has been shown in our previous study that mutations in genes relA, relC and rpsL result in the delay in Escherichia coli ilv operon derepression; the complete inhibition of derepression of the ilv operon is observed in the double mutants having alterations in rpsL and relA or relC genes. At present, some mutations occurring in the fus gene and altering the structure of the translational elongation G factor have been also found to delay derepression of E. coli ilv operon and complete inhibition in fusr and rel double mutants. Phenotypical ile and val auxotrophy is also detected in the double E. coli mutants with spectinomycin resistance mutation in rpsE gene coding for the structure of ribosomal S5 protein and mutations in relA or relC genes. The suggestion of participation of the ilv operon in regulation of other E. coli amino acid operons expression is discussed.     

RifR mutations in the beginning of the Escherichia coli rpoB gene

In Escherichia coli, mutations conferring rifampicin (Rif) resistance map to the rpoB gene, which encodes the 1342-amino acid β subunit of RNA polymerase. Almost all sequenced RifR mutations occur within the Rif region, encompassing rpoB codons 500–575. A strong Rif^R mutation lying outside the Rif region, which changed Val¹⁴⁶ to Phe was previously reported, but was not recovered in subsequent studies. Here, we used site-directed mutagenesis followed by selection on Rif to search for Rif^R mutations in the evolutionarily conserved segment of rpoB around codon 146. Strong Rif^R mutations were obtained when Val¹⁴⁶ was mutated, and several weak Rif^R mutations were also isolated near position 146. The results define a new, N-terminal cluster of Rif^R mutations, in addition to the classical central Rif region.     

Mu-induced rifamycin-resistant mutations not located in the rpoB gene of Escherichia coli

Summary A new class of rifamicin-resistant mutants of Escherichia coli was obtained by lysogenic insertions of bacteriophage Mu Amp DNA. Rifamycin resistance is closely linked to the ampicillin resistance conferred by the prophage. Mapping by conjugation with auxotrophic markers revealed that the rifamycin-resistant mutations are located between 28 and 37 min on the E. coli chromosome standard map, some distance from the rpoB gene at 89.5 min. The DNA-dependent RNA polymerase of these mutants is highly sensitive to rifampicin.     

Modulation of acid-induced amino acid decarboxylase gene expression by hns in Escherichia coli.

Biodegradative arginine decarboxylase and lysine decarboxylase, encoded by adi and cadA, respectively, are induced to maximal levels when Escherichia coli is grown anaerobically in rich medium at acidic pH. Mutants formed by transposon mutagenesis, namely, GNB725, GNB729, GNB88, GNB824, and GNB837, exhibited considerably elevated expression at pH 8.0 compared with the corresponding parental strain. Southern hybridization and chromosome mapping showed that the above mutants contained a transposon within the hns gene. Several plasmids from an E. coli library able to complement these mutants by restoring normal pH induction were independently isolated and were found to contain the hns gene. These results suggest a role for the DNA-binding protein H-NS in affecting the activation of these acid-induced genes.     

Mapping and sequencing of mutations in the Escherichia coli rpoB gene that lead to rifampicin resistance

Rifampicin is an antibiotic that inhibits the function of RNA polymerase in eubacteria. Mutations affecting the beta subunit of RNA polymerase can confer resistance to rifampicin. A large number of rifampicin-resistant (hereafter called Rifr) mutants have been isolated in Escherichia coli to probe the involvement of RNA polymerase in a variety of physiological processes. We have undertaken a comprehensive analysis of Rifr mutations to identify their structural and functional effects on RNA polymerase. Forty-two Rifr isolates with a variety of phenotypes were mapped to defined intervals within the rpoB gene using a set of deletions of the rpoB gene. The mutations were sequenced. Seventeen mutational alterations affecting 14 amino acid residues were identified. These alleles are located in three distinct clusters in the center of the rpoB gene. We discuss the implications of our results with regards to the structure of the rifampicin binding site.     

Gene relA function in the expression of amino acid operons. I. Effect of the allelic state of gene relA on phenotypic manifestations of auxotrophic threonine and isoleucine mutations in Escherichia coli K-12]

The substitution of the relA gene mutant allele with wild type allele of this gene in strictly auxotrophic strain of Escherichia coli K-12 GT25, carrying thr B1007 mitation, results in the appearance of the partial dependence of the bacterial growth upon threonine. On the other hand, the introduction of relA mutation into genome of incomplete threonine auxotroph, which was isolated as pseudorevertant from the strict threonine auxotroph CP78, recovered the strict dependency of the growth on the presence of threonine in the medium. The introduction of relA mutation into genome of partial isoleucine auxotroph, carrying a mutation in ilvA gene, reduces the residual activity of threonine deaminase under the conditions of derepression and results in the appearance of strict dependency of bacterial growth on the presence of isoleucine. These data indicate that operons, which control the biosynthesis of threonine and isoleucine, are positively regulated by the product of relA gene. The possibility of using leaky mutations, which lead to incomplete block of these amino acids synthesis, for testing allelic state of relA gene is discussed.     

Further examination of seventeen mutations in Escherichia coli F1-ATPase beta-subunit.

Seventeen mutations in beta-subunit of Escherichia coli F1-ATPase which had previously been characterized in strain AN1272 (Mu-induced mutant) were expressed in strain JP17 (beta-subunit gene deletion). Six showed unchanged behavior, namely: C137Y; G142D; G146S; G207D; Y297F; and Y354F. Five failed to assemble F1F0 correctly, namely: G149I; G154I; G149I,G154I; G223D; and P403S,G415D. Six assembled F1F0 correctly, but with membrane ATPase lower than in AN1272, namely: K155Q; K155E; E181Q; E192Q; D242N; and D242V. AN1272 was shown to unexpectedly produce a small amount of wild-type beta-subunit; F1-ATPase activities reported previously in AN1272 were referable to hybrid enzymes containing both mutant and wild-type beta-subunits. Purified F1 was obtained from K155Q; K155E; E181Q; E192Q; and D242N mutants in JP17. Vmax ATPase values were lower, and unisite catalysis rate and equilibrium constants were perturbed to greater extent, than in AN1272. However, general patterns of perturbation revealed by difference energy diagrams were similar to those seen previously, and the new data correlated well in linear free energy relationships for reaction steps of unisite catalysis. Correlation between multisite and unisite ATPase activity was seen in the new enzymes. Overall, the data give strong support to previously proposed mechanisms of unisite catalysis, steady-state catalysis, and energy coupling in F1-ATPases (Al-Shawi, M. K., Parsonage, D. and Senior, A. E. (1990) J. Biol. Chem. 265, 4402-4410). The K155Q, K155E, D242N, and E181Q mutations caused 5000-fold, 4000-fold, 1800-fold, and 700-fold decrease, respectively, in Vmax ATPase, implying possibly direct roles for these residues in catalysis. Experiments with the D242N mutant suggested a role for residue beta D242 in catalytic site Mg2+ binding.