Genetic composition of the Bacillus subtilis SOS system

Complete and SOS-mediated response of Staphylococcus aureus to the antibiotic ciprofloxacin

Staphylococcus aureus infections can be difficult to treat due to both multidrug resistance and the organism's remarkable ability to persist in the host. Persistence and the evolution of resistance may be related to several complex regulatory networks, such as the SOS response, which modifies transcription in response to environmental stress. To understand how S. aureus persists during antibiotic therapy and eventually emerges resistant, we characterized its global transcriptional response to ciprofloxacin. We found that ciprofloxacin induces prophage mobilization as well as significant alterations in metabolism, most notably the up-regulation of the tricarboxylic acid cycle. In addition, we found that ciprofloxacin induces the SOS response, which we show, by comparison of a wild-type strain and a non-SOS-inducible lexA mutant strain, includes the derepression of 16 genes. While the SOS response of S. aureus is much more limited than those of Escherichia coli and Bacillus subtilis, it is similar to that of Pseudomonas aeruginosa and includes RecA, LexA, several hypothetical proteins, and a likely error-prone Y family polymerase whose homologs in other bacteria are required for induced mutation. We also examined induced mutation and found that either the inability to derepress the SOS response or the lack of the LexA-regulated polymerase renders S. aureus unable to evolve antibiotic resistance in vitro in response to UV damage. The data suggest that up-regulation of the tricarboxylic acid cycle and induced mutation facilitate S. aureus persistence and evolution of resistance during antibiotic therapy.

Characterization of the global transcriptional responses to different types of DNA damage and disruption of replication in Bacillus subtilis

DNA damage and perturbations in DNA replication can induce global transcriptional responses that can help organisms repair the damage and survive. RecA is known to mediate transcriptional responses to DNA damage in several bacterial species by inactivating the repressor LexA and phage repressors. To gain insight into how Bacillus subtilis responds to various types of DNA damage, we measured the effects of DNA damage and perturbations in replication on mRNA levels by using DNA microarrays. We perturbed replication either directly with p-hydroxyphenylazo-uracil (HPUra), an inhibitor of DNA polymerase, or indirectly with the DNA-damaging reagents mitomycin C (MMC) and UV irradiation. Our results indicate that the transcriptional responses to HPUra, MMC, and UV are only partially overlapping. recA is the major transcriptional regulator under all of the tested conditions, and LexA appears to directly repress the expression of 63 genes in 26 operons, including the 18 operons previously identified as LexA targets. MMC and HPUra treatments caused induction of an integrative and conjugative element (ICEBs1) and resident prophages (PBSX and SPbeta), which affected the expression of many host genes. Consistent with previous results, the induction of these mobile elements required recA. Induction of the phage appeared to require inactivation of LexA. Unrepaired UV damage and treatment with MMC also affected the expression of some of the genes that are controlled by DnaA. Furthermore, MMC treatment caused an increase in origin-proximal gene dosage. Our results indicate that different types of DNA damage have different effects on replication and on the global transcriptional profile.

Proteolysis of the replication checkpoint protein Sda is necessary for the efficient initiation of sporulation after transient replication stress in Bacillus subtilis

Cells of Bacillus subtilis actively co-ordinate the initiation of sporulation with DNA replication and repair. Conditions that perturb replication initiation or replication elongation induce expression of a small protein, Sda, that specifically inhibits the histidine kinases required to initiate spore development. Previously, the role of Sda has been studied during chronic blocks to DNA replication. Here we show that induction of Sda is required to delay the initiation of sporulation when replication elongation is transiently blocked or after UV irradiation. During the recovery phase, cells efficiently sporulated, but this required the proteolysis of Sda. The rapid proteolysis of Sda required the ClpXP protease and the uncharged C-terminal sequence of Sda. Replacing the last two residues of Sda, both serines, with aspartic acids markedly stabilized Sda. Strains expressing sdaDD from the endogenous sda locus were unable to efficiently initiate sporulation after transient replication stress. We conclude that the Sda replication checkpoint is required to delay the initiation of sporulation when DNA replication is transiently perturbed, and that the intrinsic instability of Sda contributes to shutting off the pathway. The Sda checkpoint thus co-ordinates early events of spore development, including the polar cell division, with successful completion of chromosome replication.

Bacterial cell division: the mechanism and its precison

The recent development of cell biology techniques for bacteria to allow visualization of fundamental processes in time and space, and their use in synchronous populations of cells, has resulted in a dramatic increase in our understanding of cell division and its regulation in these tiny cells. The first stage of cell division is the formation of a Z ring, composed of a polymerized tubulin-like protein, FtsZ, at the division site precisely at midcell. Several membrane-associated division proteins are then recruited to this ring to form a complex, the divisome, which causes invagination of the cell envelope layers to form a division septum. The Z ring marks the future division site, and the timing of assembly and positioning of this structure are important in determining where and when division will take place in the cell. Z ring assembly is controlled by many factors including negative regulatory mechanisms such as Min and nucleoid occlusion that influence Z ring positioning and FtsZ accessory proteins that bind to FtsZ directly and modulate its polymerization behavior. The replication status of the cell also influences the positioning of the Z ring, which may allow the tight coordination between DNA replication and cell division required to produce two identical newborn cells.