Transcription initiation-defective forms of sigma(54) that differ in ability To function with a heteroduplex DNA template

Helicobacter pylori FlgR is an enhancer-independent activator of sigma54-RNA polymerase holoenzyme

Helicobacter pylori FlgR activates transcription with sigma54-RNA polymerase holoenzyme (sigma54-holoenzyme) from at least five flagellar operons. Activators of sigma54-holoenzyme generally bind enhancer sequences located >70 bp upstream of the promoter and contact sigma54-holoenzyme bound at the promoter through DNA looping to activate transcription. H. pylori FlgR lacks the carboxy-terminal DNA-binding domain present in most sigma54-dependent activators. As little as 42 bp of DNA upstream of the flaB promoter and 26 bp of DNA sequence downstream of the transcriptional start site were sufficient for efficient FlgR-mediated expression from a flaB'-'xylE reporter gene in H. pylori, indicating that FlgR does not use an enhancer to activate transcription. Other examples of sigma54-dependent activators that lack a DNA-binding domain include Chlamydia trachomatis CtcC and activators from the other Chlamydia spp. whose genomes have been sequenced. FlgR from Helicobacter hepaticus and Campylobacter jejuni, which are closely related to H. pylori, appear to have carboxy-terminal DNA-binding domains, suggesting that the loss of the DNA-binding domain from H. pylori FlgR occurred after the divergence of these bacterial species. Removal of the amino-terminal regulatory domain of FlgR resulted in a constitutively active form of the protein that activated transcription from sigma54-dependent genes in Escherichia coli. The truncated FlgR protein also activated transcription with E. coli sigma54-holoenzyme in an in vitro transcription assay.

Purification and characterization of the AAA+ domain of Sinorhizobium meliloti DctD, a sigma54-dependent transcriptional activator

Activators of sigma54-RNA polymerase holoenzyme couple ATP hydrolysis to formation of an open complex between the promoter and RNA polymerase. These activators are modular, consisting of an N-terminal regulatory domain, a C-terminal DNA-binding domain, and a central activation domain belonging to the AAA+ superfamily of ATPases. The AAA+ domain of Sinorhizobium meliloti C4-dicarboxylic acid transport protein D (DctD) is sufficient to activate transcription. Deletion analysis of the 3' end of dctD identified the minimal functional C-terminal boundary of the AAA+ domain of DctD as being located between Gly-381 and Ala-384. Histidine-tagged versions of the DctD AAA+ domain were purified and characterized. The DctD AAA+ domain was significantly more soluble than DctD(Delta(1-142)), a truncated DctD protein consisting of the AAA+ and DNA-binding domains. In addition, the DctD AAA+ domain was more homogeneous than DctD(Delta(1-142)) when analyzed by native gel electrophoresis, migrating predominantly as a single high-molecular-weight species, while DctD(Delta(1-142)) displayed multiple species. The DctD AAA+ domain, but not DctD(Delta(1-142)), formed a stable complex with sigma54 in the presence of the ATP transition state analogue ADP-aluminum fluoride. The DctD AAA+ domain activated transcription in vitro, but many of the transcripts appeared to terminate prematurely, suggesting that the DctD AAA+ domain interfered with transcription elongation. Thus, the DNA-binding domain of DctD appears to have roles in controlling the oligomerization of the AAA+ domain and modulating interactions with sigma54 in addition to its role in recognition of upstream activation sequences.

Binding of transcriptional activators to sigma 54 in the presence of the transition state analog ADP-aluminum fluoride: insights into activator mechanochemical action

Conformational changes in sigma 54 (sigma(54)) and sigma(54)-holoenzyme depend on nucleotide hydrolysis by an activator. We now show that sigma(54) and its holoenzyme bind to the central ATP-hydrolyzing domains of the transcriptional activators PspF and NifA in the presence of ADP-aluminum fluoride, an analog of ATP in the transition state for hydrolysis. Direct binding of sigma(54) Region I to activator in the presence of ADP-aluminum fluoride was shown and inferred from in vivo suppression genetics. Energy transduction appears to occur through activator contacts to sigma(54) Region I. ADP-aluminum fluoride-dependent interactions and consideration of other AAA+ proteins provide insight into activator mechanochemical action.

Regulatory sequences in sigma 54 localise near the start of DNA melting

Transcription initiation by the enhancer-dependent sigma(54) RNA polymerase holoenzyme is positively regulated after promoter binding. The promoter DNA melting process is subject to activation by an enhancer-bound activator protein with nucleoside triphosphate hydrolysis activity. Tethered iron chelate probes attached to amino and carboxyl-terminal domains of sigma(54) were used to map sigma(54)-DNA interaction sites. The two domains localise to form a centre over the -12 promoter region. The use of deletion mutants of sigma(54) suggests that amino-terminal and carboxyl-terminal sequences are both needed for the centre to function. Upon activation, the relationship between the centre and promoter DNA changes. We suggest that the activator re-organises the centre to favour stable open complex formation through adjustments in sigma(54)-DNA contact and sigma(54) conformation. The centre is close to the active site of the RNA polymerase and includes sigma(54) regulatory sequences needed for DNA melting upon activation. This contrasts systems where activators recruit RNA polymerase to promoter DNA, and the protein and DNA determinants required for activation localise away from promoter sequences closely associated with the start of DNA melting.