Biosynthesis of RNA polymerase in Escherichia coli

Summary Effect of temperature-sensitive, assembly-defective mutations in Escherichia coli RNA polymerase (rpoB) or subunit gene (rpoC) was investigated on the expression of wild-type rpoB ⁺C⁺operon, which was introduced by infection of a lambda transducing phage drif ⁺ (rpoB ⁺)-6 after UV-irradiation of the mutant cells. In rpoB2·rpoB7 strain which accumulates assembly-intermediates, free , ₂ complex and premature core, the expression of rpoB ⁺C⁺operon measured by the rate of subunit synthesis was considerably inhibited whereas that of EF(translation elongation factor)-Tu, ribosomal proteins L1 and L7/L12, and some -coded proteins remained unaffected. On the other hand, the expression was enhanced specifically for only rpoB ⁺C⁺operon in either rpoC4 or rpoC1 mutants, which are defective in the association of ₂ complex and subunit or the activation of premature core enzyme, respectively. Upon preincubation of the mutant cells at 42° C prior to phage infection, during which assembly intermediates degraded rapidly, the rate of subunit synthesis relative to other phage-corded proteins increased remarkably in rpoB2·rpoB7 mutant as well as in rpoC4 and rpoC1 mutants. These observations strongly suggested the autogenous regulation for at least (rpoB ⁺C⁺) operon by some trans-active diffusible protein complexes built of RNA polymerase subunits. Nature of the regulatory molecules is discussed.Paper VI in this series is Saitoh and Ishihama (1977)     

Biosynthesis of RNA polymerase in Escherichia coli

Summary In spite of the generally well-coordinated synthesis of RNA polymerase core enzyme subunits (, and ) in Escherichia coli, a situation was found during the growth transition from exponential to stationary phase in which this coordination was broken (the order of differential repression being ; Kawakami et al. (1979)). The present study indicates that, during a certain period of the growth transition, twice as much subunit is synthesized as subunit and the overproduced subunit accumulates as the assembly intermediate ₂ complex, which is rapidly and preferentially degraded.Two independent factors, i.e., carbon source down-shift and oxygen depletion, were examined separately for their influence on the coordinated regulation of the synthesis of RNA polymerase subunits. The depletion of glucose added as a sole carbon source was accompanied by repression of the synthesis of all core enzyme subunits, while under the same conditions the differential rate of subunit synthesis increased. In contrast, the sudden ending of the oxygen supply resulted in specific repression of the synthesis of only and subunits but not of and subunits. The latter result may be explained by the autogenous repression of the rpoBC genes by a temporal increase in the amount of unused cytoplasmic RNA polymerase.Paper XI in this series is Kawakami and Ishihama (1980)     

The influence of mutations upon the synthesis of RNA polymerase subunits in Escherichia coli cells

Summary The influence of mutations in structural genes of and subunits of RNA polymerase upon the synthesis of these subunits in E. coli cells have been investigated. An amber-mutation ts22 in the subunit gene decreases the intracellular concentration of this subunit and the rate of its synthesis. At the same time the concentration and the rate of subunit synthesis is increased. These suggest the compensatory activation of the RNA polymerase operon that takes place under the conditions of shortage of one of the subunits. Reversions, as well as more effective supression of ts22 amber mutation, achieved by streptomycin addition, substitution of su2 by su1, or by specific mutations, result in a rise of and drop of subunit concentration and synthesis in ts22 mutant. TsX missense-mutation in the subunit gene alters the properties of the enzyme increasing, at the same time, the concentration and the rate of synthesis of both and subunits, particularly at a nonpermissive temperature. This points to an inversely proportional relationship between the rate of synthesis of RNA polymerase subunits and the total intracellular activity of the enzyme. Extra subunits are rapidly degraded in ts22 and tsX mutants.The whole complex of our data and those of others suggest that the regulation of the synthesis of RNA polymerase subunits is accomplished by interaction of a negative and a positive mechanisms of regulation which include not only activators and repressors but the enzyme itself as well.     

On the role of the Escherichia coli RNA polymerase sigma factor in T4 phage development

Summary The rpoD800 mutation causing the temperature sensitivity of Escherichia coli RNA polymerase sigma factor has been used to demonstrate that the bacterial sigma factor is necessary throughout T4 phage development. In T4-infected RpoD800 mutant cells RNA synthesis is equally depressed at restrictive temperature at early and late stages of infection. The results show the bacterial sigma factor to be necessary for the synthesis of all RNA types in infected cells.     

Phage T4 infection restricts rRNA synthesis byE. coli RNA polymerase

Summary Complementation for the maintenance of lysogeny was studied by superinfecting cIts lysogens at 34° C, and then heating to 43° C. With certain exceptions,ts mutants with defects in the left half of the repressor complementedts mutants with defects in the right half to produce a less heat-labile repressor (Fig. 3). AllcIamber mutants failed to complementcIts mutants. ThecI mutantc50 complements allts mutants. Mutations in Pre (cy) or genescII andcIII do not significantly affect the expression ofcI by a superinfecting genome in an immune lysogen. Mutants with very heat-labile repressors failed to complement cy42 for the establishment of lysogeny at elevated temperatures, while those with less heatsensitive repressors apparently did complementcy.According to a suggested model, the left side of thecI product is concerned primarily with subunit aggregation, while operator binding is the function of the right side of the oligomer.     

Effects of growth conditions and mutations in RNA polymerase on translational activity in vitro in Escherichia coli

Summary The translational capacity in vitro in Escherichia coli, using RNA from phage R17 or Q as messenger, is several times higher if the extracts are prepared from cells harvested in early exponential phase or grown under conditions of good aeration compared to if extracts are prepared from cells harvested in a later growth phase or grown under semi-aerobic conditions. In low activity extracts the production of phage replicase protein is preferentially affected. Growth of a wild type strain under semiaerobic conditions has a less pronounced effect on translational capacity in vitro using crude mRNA from normal or T4 infected cells or with poly(U).Mutants were fortuitously found which did not show a lowered translational activity in vitro as a result of entering late phase of growth. Two of these were changed in RNA polymerase.Two different translational inhibitors can be demonstrated in the ribosomal wash fraction obtained from semi-aerobically grown wild type cells, whereas only one was found in the case of aerobically grown cells. The low translational activity of semi-aerobically grown cells in vitro is implied to be dependent on the induction or activation of a translational inhibitor. It behaves like a protein but is not likely to be a protease or RNAse.     

Cell division in Escherichia coli septation during synchronous growth

Summary The capacity of E. coli B/r to support recombination and complementation between T4am phages during its life cycle has been analyzed in order to get information on the mechanism of cell division. It was found that a decrease in recombinants and complementation events, which is expected at the time of cell compartmentalization coincides with physical cell separation. Therefore, we conclude that the two halves of a dividing cell remain connected until a very late stage of the division period, thus allowing exchange of DNA and protein molecules.When a synchronized culture of E. coli B/r is infected at different cell age with phage T4, the number of surviving cells increases 10 min prior to cell division. At this time the cells are separated into two independent targets for killing by the phage, although there is still free exchange of DNA and proteins within the whole cell. The localized action of murein metabolizing enzymes at the site of subsequent cell division is likely to create a barriere within the cell envelope that prevents the propagation of the phage killing signal.     

Control of ribosomal RNA synthesis in Escherichia coli

Summary The ribosomal RNA synthesis in a cell-free system containing the nucleoids and the cytoplasmic fraction prepared from Escherichia coli cells has been investigated. The addition of the 4S fraction from the cytoplasm to the isolated nucleoids induces RNA synthesis by a new chain initiation. In this system a preferential initiation of rRNA chains occurs. The experimental results suggest that the 4S fraction contains at least two activities, one for releasing RNA-polymerases from the nucleoids, and another for the frequent initiation of rRNA chains. No restriction of the rRNA synthesis has been observed in the nucleoids and the 4S fraction from the amino acidstarved rel ⁺ cells. The rRNA synthesized in the above system is detected at about 23S and 16S rRNA regions.     

Escherichia coli merodiploids with altered ratios of episomal to chromosomal RNA polymerase activity

Summary Starting with an E. coli merodiploid strain (rpoB ⁺ (rifS)/rpoB^- (rifR)) containing equal amounts of rifampicin-sensitive and resistant RNA polymerase activities, mutants were isolated that had a disproportionately high ratio of the rifampicin-resistant enzyme activity. With one strain it is shown that the mutation responsible for this phenotype is closely linked to the rifR (rpoB^-) allele.     

Functioning of the F-plasmid origin of replication in an Escherichia coli K12 Hfr strain during exponential growth

The pattern of chromosome replication in the Escherichia coli K12 Hfr strain KL99 was investigated during exponential growth by DNA-DNA hybridization. The levels of chromosomal markers close to the point of insertion of F (near pyrC) were raised in relation to other markers by comparison with the situation in an isogenic F- strain. The data are shown to be consistent with the proposal that the integrated F plasmid was regulating its copy number by a mass-titration mechanism.     

Amber mutations in the structural gene for RNA polymerase sigma factor of Escherichia coli

Summary Amber mutants of Escherichia coli K-12 affected in the structural gene (rpoD) for th subunit of RNA polymerase have been obtained from a strain harboring a temperature-sensitive amber suppressor (supF-Ts6) which is active only at low temperatures. These mutants grow normally at low temperature (30°C) but do not grow at high temperature (42°C) due to the inability to synthesize factor. In one mutant studied in detail (rpoD40), the rate of -factor synthesis at 30°C is about half that of the wild type and is decreased to 10%–15% within 1 h of incubation at 42°C. The synthesis of core polymerase subunits or bulk protein is virtually unaffected at least for 2 h. The defect of the mutant in synthesis and growth at high temperature can be suppressed by any of the amber suppressors tested (supD, supE or supF). RNA-polymerase holoenzymes prepared from the mutant cells carrying each of the suppressors (grown at 42°C) exhibit different thermostabilities attributable to alterations in the factor. The reduced synthesis in the mutant is accompanied by the synthesis of polypeptide tentatively identified as amber fragment. These results as well as the genetic mapping data indicate that the amber mutation (rpoD40) resides within the structural gene for the factor and directly affects synthesis upon inactivation of the suppressor at high temperature.