Sequence-dependent upstream DNA-RNA polymerase interactions in the open complex with lambdaPR and lambdaPRM promoters and implications for the mechanism of promoter interference.

Upstream interactions of Escherichia coli RNA polymerase (RNAP) in an open promoter complex (RPo) formed at the P(R) and P(RM) promoters of bacteriophage lambda have been studied by atomic force microscopy. We demonstrate that the previously described 30-nm DNA compaction observed upon RPo formation at P(R) [Rivetti, C., Guthold, M. & Bustamante, C. (1999). Wrapping of DNA around the E. coli RNA polymerase open promoter complex. EMBO J., 18, 4464-4475.] is a consequence of the specific interaction of the RNAP with two AT-rich sequence determinants positioned from -36 to -59 and from -80 to -100. Likewise, RPos formed at P(RM) showed a specific contact between RNAP and the upstream DNA sequence. We further demonstrate that this interaction, which results in DNA wrapping against the polymerase surface, is mediated by the C-terminal domains of alpha-subunits (carboxy-terminal domain). Substitution of these AT-rich sequences with heterologous DNA reduces DNA wrapping but has only a small effect on the activity of the P(R) promoter. We find, however, that the frequency of DNA templates with both P(R) and P(RM) occupied by an RNAP significantly increases upon loss of DNA wrapping. These results suggest that alpha carboxy-terminal domain interactions with upstream DNA can also play a role in regulating the expression of closely spaced promoters. Finally, a model for a possible mechanism of promoter interference between P(R) and P(RM) is proposed.

Specificity of the TraA-DNA interaction in the regulation of the pPD1-encoded sex pheromone response in Enterococcus faecalis.

The Enterococcus faecalis conjugative plasmid pPD1 encodes proteins responsible for the mating response to the sex pheromone cPD1 secreted by a recipient cell. This response involves the respectively negative and positive determinants traA and traE, the pheromone-inhibitor determinant ipd and structural genes participating in the conjugation process. TraA is capable of binding to key sites within the regulatory gene cluster. The binding of TraA to cognate sites is modulated by the pheromone (cPD1) and the pheromone-inhibitor (iPD1) peptides. Using atomic force microscopy and classic biochemical techniques, we mapped and characterized the TraA-DNA interactions within the pPD1 regulatory gene cluster and the role of TraA in the transcription regulation of the sex pheromone response. A previous report showed that TraA binds to three adjacent sites (tab1, tab2 and tab3) located upstream of the ipd promoter region. Here, we provide direct evidence for such interactions and show that TraA alone or in the presence of iPD1 inhibits ipd transcription by preferentially binding to tab1, whereas in the presence of saturating cPD1, the overall binding to the tab sites decreases, TraA preferentially binds to tab3 and the ipd repression is relieved. Moreover, TraA alone or in the presence of iPD1 binds to two non-adjacent sites within the ipd terminators T1 and T2, an interaction that is also relieved in the presence of cPD1. The binding of TraA to the termination region of ipd may play an important role in controlling traE and traF expression via a transcriptional read-through mechanism already postulated for the pAD1 plasmid. TraA may also regulate its own expression by binding to a site in the proximity of the traA promoter, which has been relocated 200 bp downstream of the ipd gene. A model for the TraA-mediated regulation of the pPD1-encoded sex pheromone response is presented.

Patterned gallium surfaces as molecular mirrors.

An entirely new means of printing molecular information on a planar film, involving casting nanoscale impressions of the template protein molecules in molten gallium, is presented here for the first time. The metallic imprints not only replicate the shape and size of the proteins used as template. They also show specific binding for the template species. Such a simple approach to the creation of antibody-like properties in metallic mirrors can lead to applications in separations, microfluidic devices, and the development of new optical and electronic sensors, and will be of interest to chemists, materials scientists, analytical specialists, and electronic engineers.

The neutrophil-activating Dps protein of Helicobacter pylori, HP-NAP, adopts a mechanism different from Escherichia coli Dps to bind and condense DNA.

The Helicobacter pylori neutrophil-activating protein (HP-NAP), a member of the Dps family, is a fundamental virulence factor involved in H.pylori-associated disease. Dps proteins protect bacterial DNA from oxidizing radicals generated by the Fenton reaction and also from various other damaging agents. DNA protection has a chemical component based on the highly conserved ferroxidase activity of Dps proteins, and a physical one based on the capacity of those Dps proteins that contain a positively charged N-terminus to bind and condense DNA. HP-NAP does not possess a positively charged N-terminus but, unlike the other members of the family, is characterized by a positively charged protein surface. To establish whether this distinctive property could be exploited to bind DNA, gel shift, fluorescence quenching and atomic force microscopy (AFM) experiments were performed over the pH range 6.5-8.5. HP-NAP does not self-aggregate in contrast to Escherichia coli Dps, but is able to bind and even condense DNA at slightly acid pH values. The DNA condensation capacity acts in concert with the ferritin-like activity and could be used to advantage by H.pylori to survive during host-infection and other stress challenges. A model for DNA binding/condensation is proposed that accounts for all the experimental observations.

Upstream promoter sequences and alphaCTD mediate stable DNA wrapping within the RNA polymerase-promoter open complex.

We show that the extent of stable DNA wrapping by Escherichia coli RNA polymerase (RNAP) in the RNAP-promoter open complex depends on the sequence of the promoter and, in particular, on the sequence of the upstream region of the promoter. We further show that the extent of stable DNA wrapping depends on the presence of the RNAP alpha-subunit carboxy-terminal domain and on the presence and length of the RNAP alpha-subunit interdomain linker. Our results indicate that the extensive stable DNA wrapping observed previously in the RNAP-promoter open complex at the lambda P(R) promoter is not a general feature of RNAP-promoter open complexes.