Both prokaryotes and eukaryotes respond to a decrease in temperature with the expression of a speci®c subset of proteins. Although a large body of information concerning cold shock-induced genes has been gathered, studies on temperature regulation have not clearly identi®ed the key regulatory factor(s) responsible for thermosensing and signal transduction at low temperatures. Here we identi®ed a twocomponent signal transduction system composed of a sensor kinase, DesK, and a response regulator, DesR, responsible for cold induction of the des gene coding for the D5-lipid desaturase from Bacillus subtilis. We found that DesR binds to a DNA sequence extending from position ±28 to ±77 relative to the start site of the temperature-regulated des gene. We show further that unsaturated fatty acids (UFAs), the products of the D5-desaturase, act as negative signalling molecules of des transcription. Thus, a regulatory loop composed of the DesK±DesR two-component signal transduction system and UFAs provides a novel mechanism for the control of gene expression at low temperatures.
The parD operon of Escherichia coli plasmid R1 encodes a toxin–antitoxin system, which is involved in plasmid stabilization. The toxin Kid inhibits cell growth by RNA degradation and its action is neutralized by the formation of a tight complex with the antitoxin Kis. A fascinating but poorly understood aspect of the kid–kis system is its autoregulation at the transcriptional level. Using macromolecular (tandem) mass spectrometry and DNA binding assays, we here demonstrate that Kis pilots the interaction of the Kid–Kis complex in the parD regulatory region and that two discrete Kis-binding regions are present on parD. The data clearly show that only when the Kis concentration equals or exceeds the Kid concentration a strong cooperative effect exists between strong DNA binding and Kid2–Kis2–Kid2–Kis2 complex formation. We propose a model in which transcriptional repression of the parD operon is tuned by the relative molar ratio of the antitoxin and toxin proteins in solution. When the concentration of the toxin exceeds that of the antitoxin tight Kid2–Kis2–Kid2 complexes are formed, which only neutralize the lethal activity of Kid. Upon increasing the Kis concentration, (Kid2–Kis2)n complexes repress the kid–kis operon.
Replication of the promiscuous plasmid pMV158 requires expression of the initiator repB gene, which is controlled by the repressor CopG. Genes repB and copG are co-transcribed from promoter Pcr. We have studied the interactions between RNA polymerase, CopG and the promoter to elucidate the mechanism of repression by CopG. Complexes formed at 0°C and at 37°C between RNA polymerase and Pcr differed from each other in stability and in the extent of the DNA contacted. The 37°C complex was very stable (half-life of about 3 h), and shared features with typical open complexes generated at a variety of promoters. CopG protein repressed transcription from Pcr at two different stages in the process leading to the initiation complex. First, CopG hindered binding of RNA polymerase to the promoter. Second, CopG was able to displace RNA polymerase once the enzyme has formed a stable complex with Pcr. A model for the CopG-mediated disassembly of the stable RNA polymerase–Pcr promoter complex is presented.
Toxin–antitoxin systems, as found in bacterial plasmids and their host chromosomes, play a role in the maintenance of genetic information, as well as in the response to stress. We describe the basic biology of the parD/kiskid toxin–antitoxin system of Escherichia coli plasmid R1, with an emphasis on regulation, toxin activity, potential applications in biotechnology and its relationships with related toxin–antitoxin systems. Special reference is given to the ccd toxin–antitoxin system of plasmid F because its toxin shares structural homology with the toxin of the parD system. Inter‐relations with related toxin–antitoxin systems present in the E. coli chromosome, such as the parD homologues chpA/mazEF and chpB and the relBE system, are also reviewed. The combined structural and functional information that is now available on all these systems, as well as the ongoing controversy regarding the role of the chromosomal toxin–antitoxin loci, have made this review especially timely.
Toxin-antitoxin (TA) systems are small genetic modules formed by a stable toxin and an unstable antitoxin that are widely present in plasmids and in chromosomes of Bacteria and Archaea. Toxins can interfere with cell growth or viability, targeting a variety of key processes. Antitoxin inhibits expression of the toxin, interacts with it, and neutralizes its effect. In a plasmid context, toxins are kept silent by the continuous synthesis of the unstable antitoxins; in plasmid-free cells (segregants), toxins can be activated owing to the faster decay of the antitoxin, and this results in the elimination of these cells from the population (postsegregational killing [PSK]) and in an increase of plasmid-containing cells in a growing culture. Chromosomal TA systems can also be activated in particular circumstances, and the interference with cell growth and viability that ensues contributes in different ways to the physiology of the cell. In this article, we review the conditional activation of TAs in selected plasmidic and chromosomal TA pairs and the implications of this activation. On the whole, the analysis underscores TA interactions involved in PSK and points to the effective contribution of TA systems to the physiology of the cell.
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