LexA cleavage is required for CTX prophage induction

The physiologic conditions and molecular interactions that control phage production have been studied in few temperate phages. We investigated the mechanisms that regulate production of CTXphi, a temperate filamentous phage that infects Vibrio cholerae and encodes cholera toxin. In CTXphi lysogens, the activity of P(rstA), the only CTXphi promoter required for CTX prophage development, is repressed by RstR, the CTXvphi repressor. We found that the V. cholerae SOS response regulates CTXvphi production. The molecular mechanism by which this cellular response to DNA damage controls CTXphi production differs from that by which the E. coli SOS response controls induction of many prophages. UV-stimulated CTXphi production required RecA-dependent autocleavage of LexA, a repressor that controls expression of numerous host DNA repair genes. LexA and RstR both bind to and repress P(rstA). Thus, CTXphi production is controlled by a cellular repressor whose activity is regulated by the cell's response to DNA damage.     

Functional interaction between RNA polymerase alpha subunit C-terminal domain and sigma70 in UP-element- and activator-dependent transcription

We show that the Escherichia coli RNA polymerase (RNAP) alpha subunit C-terminal domain (alphaCTD) functionally interacts with sigma(70) at a subset of UP-element- and activator-dependent promoters, we define the determinants of alphaCTD and sigma(70) required for the interaction, and we present a structural model for the interaction. The alphaCTD-sigma(70) interaction spans the upstream promoter and core promoter, thereby linking recognition of UP-elements and activators in the upstream promoter with recognition of the -35 element in the core promoter. We propose that the alphaCTD-sigma(70) interaction permits UP-elements and activators not only to "recruit" RNAP through direct interaction with alphaCTD, but also to "remodel" RNAP-core-promoter interaction through indirect, alphaCTD-bridged interactions with sigma(70).     

The CTXphi repressor RstR binds DNA cooperatively to form tetrameric repressor-operator complexes

CTX is a filamentous bacteriophage that encodes cholera toxin and integrates into the Vibrio cholerae genome to form stable lysogens. In CTX lysogens, gene expression originating from the rstA phage promoter is repressed by the phage-encoded repressor RstR. The N-terminal region of RstR contains a helix-turn-helix DNA-binding element similar to the helix-turn-helix of the cI/Cro family of phage repressors, whereas the short C-terminal region is unrelated to the oligomerization domain of cI repressor. Purified His-tagged RstR bound to three extended 50-bp operator sites in the rstA promoter region. Each of the RstR footprints exhibited a characteristic staggered pattern of DNase I-accessible regions that suggested RstR binds DNA as a dimer-of-dimers. In gel permeation chromatography and cross-linking experiments, RstR oligomerized to form dimers and tetramers. RstR was shown to be tetrameric when bound to operator DNA by performing mobility shift experiments with mixtures of RstR and a lengthened active variant of RstR. Binding of RstR to the high affinity O1 site could be fit to a cooperative model of operator binding in which two RstR dimers associate to form tetrameric RstR-operator complexes. The binding of RstR dimers to the left or right halves of O1 operator DNA was not observed in mobility shift assays. These observations support a model in which protein-protein contacts between neighboring RstR dimers contribute to strong operator binding.     

Relevance of UP elements for three strong Bacillus subtilis phage phi29 promoters

Various Escherichia coli promoters contain, in addition to the classical -35 and -10 hexamers, a third recognition element, named the UP element. Located upstream of the -35 box, UP elements stimulate promoter activity by forming a docking site for the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). Accumulating genetic, biochemical and structural information has provided a detailed picture on the molecular mechanism underlying UP element-dependent promoter stimulation in E.coli. However, far less is known about functional UP elements of Bacillus subtilis promoters. Here we analyse the strong early sigma(A)-RNA polymerase-dependent promoters C2, A2c and A2b of the lytic B.subtilis phage phi29. We demonstrate that the phage promoters contain functional UP elements although their contribution to promoter strength is very different. Moreover, we show that the UP element of the A2b promoter, being critical for its activity, is located further upstream of the -35 box than most E.coli UP elements. The importance of the UP elements for the phage promoters and how they relate to other UP elements are discussed.