3',5'-cyclic adenosine monophosphate-requiring mutants of Escherichia coli

Expression of srnB gene of F plasmid by altered RNA polymerase in Escherichia coli

Degradation of otherwise stable rRNA and tRNA takes place in the presence of rifampin, dependent on the F plasmid srnB gene. We have reported that a protein newly synthesized in the presence of rifampin might be a product of the srnB gene required for stable RNA degradation (Ito, R. and Ohnishi, Y. (1983) Biochim. Biophys. Acta 739, 27-34). Here we have further studied the mechanism of srnB expression. Among eighteen mutants with altered RNA polymerase, two (TJ2470 (rpoC4) and TJ302 (rpoC56)) showed RNA degradation at high temperature (42 degrees C) when the srnB gene was present. Labeling proteins at 42 degrees C in strain TJ2470 indicated that a protein of molecular weight 12 000 was a product of the srnB gene, and that expression of the srnB gene provoked RNA degradation. Using plasmid pTK4, in which the srnB gene is inserted downstream of the promoter of lacZ, lac promoter-dependent expression of the srnB gene, with production of the putative protein product, also induced RNA degradation at 42 degrees C, with no requirement for added rifampin or altered RNA polymerase. RNA degradation in these conditions was quite similar to that in the case of the addition of rifampin; e.g., it showed some responses to Mg2+, temperature and RNAase I content of the cells. Expression of the srnB gene dependent on lac promoter was also observed in minicells. Thus, it is inferred that the srnB gene is probably repressed under normal conditions with its own promoter; its expression initiates RNA turnover.

Altered hexose transport and salt sensitivity in cyclic adenosine 3',5'-monophosphate-deficient Escherichia coli

A cyclic adenosine 3',5'-monophosphate (cAMP)-deficient mutant strain of Escherichia coli K-12 was studied to determine the effect this cyclic nucleotide has on the overall growth and metabolism of this organism. Deficient cells were found to be more susceptible to growth inhibition by salts than were their cAMP-sufficient counterparts. The deficient cells transported alpha-methylglucoside by passive diffusion, whereas the parental cells or mutant cells grown in the presence of exogenous cAMP were able to take up alpha-methylglucoside by the normal active transport process. When viewed together with earlier studies conducted on cAMP-deficient cells, these findings support the view that cAMP plays a key role in regulating the construction and operation of the E. coli membrane system.

Genetic analysis of an Escherichia coli mutant with a lesion in stable RNA turnover

A mutant that rapidly degrades more than 80% of its rRNA and tRNA under defined conditions was genetically analyzed. Two genes, srnA and srnB, are separately located, and the mutated alleles of both are required for degradation of stable RNA in cultures treated with rifampicin at 42 degrees . srnA is closely linked to tsx by matings and transduction tests; by P1 transduction, the gene order is lac (9 min) proC (9.55 min) tsx (9.8 min) srnA (about 10 min) purE (12 min) rnsA (14.4 min). srnB is not yet completely mapped, but is outside the lac-rnsA region, probably in the region between 75 and 90 min.-The product of the rnsA gene, RNase I, is a potent endonuclease of E. coli, and the only one known that can attack ribosomes and tRNA. However, not only are the srn lesions genetically separate from rnsA, but also, derivatives of an srn strain were prepared lacking RNase I, and they retain the Srn(-) phenotype. Thus, no correlation of rapid RNA turnover and RNase I activity has been found.

Cyclic adenosine 3',5'-monophosphate in Escherichia coli

The concentration of cyclic adenosine 3',5'-monophosphate (c-AMP) in Escherichia coli growing on different sources of carbon was studied. Cultures utilizing a source of carbon that supported growth relatively poorly had consistently higher concentrations of c-AMP than did cultures utilizing sugars that supported rapid growth. This relationship was also observed in strains defective in c-AMP phosphodiesterase and simultaneously resistant to catabolite repression; in such strains the c-AMP concentration was slightly higher for several sources of carbon tested. Cultures continued to synthesize c-AMP and secreted it into the medium, under conditions that brought about an inhibition of the intracellular accumulation of the cyclic nucleotide. Transient repression of the synthesis of beta-galactosidase was not associated with an abrupt decrease in the cellular concentration of c-AMP.