Regulation and mode of action of the second small RNA activator of RpoS translation,RprA

Translation of the stationary phase sigma factor RpoS is stimulated by at least two small RNAs, DsrA and RprA. DsrA disrupts an inhibitory secondary structure in the rpoS leader mRNA by pairing with the upstream RNA. Mutations in rprA and compensating mutations in the rpoS leader demonstrate that RprA interacts with the same region of the RpoS leader as DsrA. This is the first example of two different small RNAs regulating a common target. Regulation of these RNAs differs. DsrA synthesis is increased at low temperature. We find that RprA synthesis is regulated by the RcsC/RcsB phosphorelay system, previously found to regulate capsule synthesis and promoters of ftsZ and osmC. An rcsB null mutation abolishes the basal level, whereas mutations in rcsC that activate capsule synthesis also activate expression of the rprA promoter. An essential site with similarity to other RcsB-regulated promoters was defined in the rprA promoter. Activation of the RcsC/RcsB system leads to increased RpoS synthesis, in an RprA-dependent fashion. This work suggests a new signal for RpoS translation and extends the global regulation effected by the RcsC/RcsB system to coregulation of RpoS with capsule and FtsZ.     

Sequential activation of dual promoters by different Sigma factors maintains spoVJ expression during successive developmental stages of Bacillus subtilis

The spoVJ gene of Bacillus subtilis encodes a 36 kDa protein and is expressed only in the mother cell. spoVJ has an interesting pattern of regulation during sporulation because it is expressed from sequentially activated promoters. These promoters, designated P1 and P2, are under the control of different sigma factors, sigma E and sigma K, which become active at separate times during sporulation. Removal of promoter P1, leaving promoter P2 active, resulted in about a 30-minute delay in the formation of heat-resistant spores and demonstrated that the expression of spoVJ from both promoters is essential for normal sporulation. A comparison is made between the sequences of the spoVJ promoters and the promoters of other genes dependent upon sigma E and sigma K.     

Two functions encoded by adenovirus early region 1A are responsible for the activation and repression of the DNA-binding protein gene.

Human adenovirus early region 1A (E1A) gene products differentially regulate the expression of early region 2A (E2A) encoding the DNA-binding protein (DBP). In a microinjection system, plasmids containing the DBP gene associated with both its early (map coordinate 75) and late (coordinate 72) promoters, or only with the early promoter, are inefficiently expressed, and the presence of E1A DNA is required for full expression. In contrast, the E2A plasmid in which the DBP gene is associated solely with its late promoter, efficiently produces DBP, the synthesis of which is significantly inhibited by an E1A gene product. To identify which of the E1A products is responsible for either activation or repression of DBP gene expression, two E1A mutants (Ad5hr1 and Ad2/5pm975) have been tested in the microinjection system in the presence of different DBP plasmids containing either one or both promoters. The results obtained indicate that the product encoded by the E1A 13S mRNA is responsible for the stimulation of DBP produced from the early promoter and that the 12S mRNA codes for the product which represses the synthesis of DBP from the late promoter. These results were confirmed using clones in which the E2A early or late promoter was associated to the chloramphenicol acetyltransferase (CAT) gene and assayed for CAT activity after cell transfection in the absence or in the presence of wild-type or mutant E1A plasmids, and we have also shown that this promoter-dependent regulation is reflected in the relative amount of specific DBP mRNA.     

The RcsCDB signaling system and swarming motility in Salmonella enterica serovar typhimurium: dual regulation of flagellar and SPI-2 virulence genes

The Rcs phosphorelay is a multicomponent signaling system that positively regulates colanic acid synthesis and negatively regulates motility and virulence. We have exploited a spontaneously isolated mutant, IgaA(T191P), that is nearly maximally activated for the Rcs system to identify a vast set of genes that respond to the stimulation, and we report new regulatory properties of this signaling system in Salmonella enterica serovar Typhimurium. Microarray data show that the Rcs system normally functions as a positive regulator of SPI-2 and other genes important for the growth of Salmonella in macrophages, although when highly activated the system completely represses the SPI-1/SPI-2 virulence, flagellar, and fimbrial biogenesis pathways. The auxiliary protein RcsA, which works with RcsB to positively regulate colanic acid and other target genes, not only stimulates but also antagonizes the positive regulation of many genes in the igaA mutant. We show that RcsB represses motility through the RcsB box in the promoter region of the master operon flhDC and that RcsA is not required for this regulation. Curiously, RcsB selectively stimulates expression of the flagellar type 3 secretion genes fliPQR; an RcsAB box located downstream of fliR influences this regulation. We show that excess colanic acid impairs swimming and inhibits swarming motility, consistent with the inverse regulation of the two pathways by the Rcs system.