Regulation of the Escherichia coli rrnB P2 promoter

The seven rRNA operons in Escherichia coli each contain two promoters, rrn P1 and rrn P2. Most previous studies have focused on the rrn P1 promoters. Here we report a systematic analysis of the activity and regulation of the rrnB P2 promoter in order to define the intrinsic properties of rrn P2 promoters and to understand better their contributions to rRNA synthesis when they are in their natural setting downstream of rrn P1 promoters. In contrast to the conclusions reached in some previous studies, we find that rrnB P2 is regulated: it displays clear responses to amino acid availability (stringent control), rRNA gene dose (feedback control), and changes in growth rate (growth rate-dependent control). Stringent control of rrnB P2 requires the alarmone ppGpp, but growth rate-dependent control of rrnB P2 does not require ppGpp. The rrnB P2 core promoter sequence (-37 to +7) is sufficient to serve as the target for growth rate-dependent regulation.     

Influence of the GCGC discriminator motif introduced into the ribosomal RNA P2- and tac promoter on growth-rate control and stringent sensitivity.

The synthesis of stable RNA in bacteria is known to be regulated by a stringent control mechanism. Characteristic of stringent-regulated promoters, all ribosomal RNA promoters P1, but not P2, contain a GC-rich discriminator sequence assumed to be important for such a control. Using site-directed mutagenesis we have altered both the rrnB P2 and the synthetic tac promoter to the consensus GCGC discriminator motif. The modified promoters were placed upstream of the structural gene encoding the chloramphenicol acetyltransferase. The response of the modified promoters to amino acid starvation, changes in the growth rate or differences in the basal level of guanosine tetraphosphate (ppGpp) were determined in vivo. The results clearly show, that the discriminator motif is sufficient to convert the ribosomal RNA promoter P2 to a stringent, as well as growth-rate regulated, promoter. By contrast, the same discriminator sequence linked to the synthetic tac promoter does not convert this promoter to either stringency or growth-rate regulation. Finally, the results presented in this study reinforce the view that stringent and growth-rate regulation utilize the same mechanism, with ppGpp being the common mediator.     

Physical mapping of stable RNA genes in Bacillus subtilis using polymerase chain reaction amplification from a yeast artificial chromosome library.

A new approach for mapping genes which utilizes yeast artificial chromosome clones carrying parts of the Bacillus subtilis genome and the polymerase chain reaction technique is described. This approach was used to physically map stable RNA genes of B. subtilis. Results from over 400 polymerase chain reactions carried out with the yeast artificial chromosome clone library, using primers specific for the genes of interest and designed from published sequences, were collected. The locations of 10 known rRNA gene regions (rrnO, rrnA, rrnE, rrnD, rrnB, rrnJ-rrnW, and rrnI-rrnH-rrnG) have been determined by this method, and these results correlate with those observed by standard genetic mapping. All rRNA operons, except rrnB, are found between 0 and 90 degrees, while rrnB has been placed in the area of 270 degrees on the chromosome map. Also localized were the tRNA gene clusters associated with the following ribosomal operons: rrnB (21 tRNAs), rrnJ (9 tRNAs), rrnD (16 tRNAs), and rrnO and rrnA (2 internal tRNAs). A previously unmapped four-tRNA gene cluster, trnY, a tRNA gene region that is not associated with a ribosomal operon, was found near the origin of replication. The P-RNA gene, important for processing of tRNAs, was found between map locations 197 and 204 degrees.     

Stringent and growth control of rRNA synthesis in Escherichia coli are both mediated by ppGpp

Weak stringent or relaxed responses were induced in Escherichia coli (relA+), using mild amino acid starvation or treatment with chloramphenicol at low concentrations, respectively, such that the growth rate was barely reduced. In this manner, the intracellular concentration of the nucleotide guanosine tetraphosphate, ppGpp, could be varied in any desired range between 0 and 1000 pmol of ppGpp per OD460 unit of culture mass. At the same time, the rate of synthesis of stable RNA (rs; rRNA and tRNA) was measured, relative to the total instantaneous rate of RNA synthesis (rt). The correlation between the cytoplasmic concentration of ppGpp and stable RNA gene activity (rs/rt) was the same as that observed previously with relA+ and relA strains growing exponentially at different rates in different media. This suggests that the distinction between growth control and stringent control of stable RNA synthesis is arbitrary, and that both kinds of control reflect the same ppGpp-dependent phenomenon. By increasing the stable RNA gene dosage, using high copy number plasmids carrying an rrn gene, we have tested the idea that ppGpp partitions the bacterial RNA polymerase into two forms with different probabilities to initiate at stable RNA and mRNA promoters. The relaxed response was not significantly altered, but the extent of the stringent response was reduced by the presence of extra rrn genes. The results agree with quantitative predictions derived from the RNA polymerase partitioning hypothesis.     

The organization of two rRNA (rrn) operons of the slow-growing pathogen Mycobacterium celatum provides key insights into mycobacterial evolution

The slow-growing Mycobacterium celatum is known to have two different 16S rRNA gene sequences. This study confirms the presence of two rrn operons and describes their organization. One operon (rrnA) was found to be located downstream from murA and the other (rrnB) was found downstream from tyrS. The promoter regions were sequenced, and also the intergenic transcribed spacer (ITS1 and ITS2) regions separating the 16S rRNA, 23S rRNA and 5S rRNA gene coding regions. Analysis of the RNA fraction revealed that rrnA is regulated by two (P1 and PCL1) promoters and rrnB is regulated by one (P1). These data show that the two rrn operons of M. celatum are organized in the same way as the two rrn operons of classical fast-growing mycobacteria. This information was incorporated into a phylogenetic analysis of the genus based on both 16S rRNA gene sequences and (where possible) the number of rrn operons per genome. The results suggest that the ancestral Mycobacterium possessed two (rrnA and rrnB) operons per genome and that subsequently, on two separate occasions, an operon (rrnB) was lost, leading to two clusters of species having a single operon (rrnA); one cluster includes the classical pathogens and the other includes Mycobacterium abscessus and Mycobacterium chelonae.     

Escherichia coli ppGpp synthetase II activity requires spoT

Escherichia coli has two enzymes catalyzing the synthesis of guanosine tetraphosphate (ppGpp), designated ppGpp synthetase I (PSI = RelA) and II (PSII), whose activities are regulated differently. Until now, the gene for PSII had not been identified. Here, an E. coli relA1 strain that expresses lacZ from an rrnB P1 promoter was used to screen mutants with increased beta-galactosidase activity on 5-bromo-4-chloro-3-indoyl beta-D-galactoside indicator plates at 30 degrees C. About 15% of the mutants obtained in this manner had reduced levels of ppGpp at 30 degrees C and no detectable ppGpp at 43 degrees C. These mutants did not form colonies at 42 degrees C on minimal medium plates and had elevated ribosome concentrations and higher growth rates at 30 degrees C. Genetic mapping by phage P1 transduction and complementation analyses showed that the mutations were located in spoT and that they were recessive. Specific inhibition of SpoT-dependent ppGpp degradation activity with picolinic acid showed that two of the mutants tested were deficient in ppGpp synthesis activity. These results indicate that spoT is required for PSII activity, suggesting that spoT encodes both ppGpp degradation and synthesis activities and that these two functions can be affected independently by mutation.