Holoenzyme switching and stochastic release of sigma factors from RNA polymerase in vivo.

We investigated the binding of E. coli RNA polymerase holoenzymes bearing sigma70, sigma(S), sigma32, or sigma54 to the ribosomal RNA operons (rrn) in vivo. At the rrn promoter, we observed "holoenzyme switching" from Esigma70 to Esigma(S) or Esigma32 in response to environmental cues. We also examined if sigma factors are retained by core polymerase during transcript elongation. At the rrn operons, sigma70 translocates briefly with the elongating polymerase and is released stochastically from the core polymerase with an estimated half-life of approximately 4-7 s. Similarly, at gadA and htpG, operons that are targeted by Esigma(S) and Esigma32, respectively, we find that sigma(S) and sigma32 also dissociate stochastically, albeit more rapidly than sigma70, from the elongating core polymerase. Up to approximately 70% of Esigma70 (the major vegetative holoenzyme) in rapidly growing cells is engaged in transcribing the rrn operons. Thus, our results suggest that at least approximately 70% of cellular holoenzymes release sigma70 during transcript elongation. Release of sigma factors during each round of transcription provides a simple mechanism for rapidly reprogramming polymerase with the relevant sigma factor and is consistent with the occurrence of a "sigma cycle" in vivo.

Immobilization of Escherichia coli RNA polymerase and location of binding sites by use of chromatin immunoprecipitation and microarrays.

The genome-wide location of RNA polymerase binding sites was determined in Escherichia coli using chromatin immunoprecipitation and microarrays (chIP-chip). Cross-linked chromatin was isolated in triplicate from rifampin-treated cells, and DNA bound to RNA polymerase was precipitated with an antibody specific for the beta' subunit. The DNA was amplified and hybridized to "tiled" oligonucleotide microarrays representing the whole genome at 25-bp resolution. A total of 1,139 binding sites were detected and evaluated by comparison to gene expression data from identical conditions and to 961 promoters previously identified by established methods. Of the detected binding sites, 418 were located within 1,000 bp of a known promoter, leaving 721 previously unknown RNA polymerase binding sites. Within 200 bp, we were able to detect 51% (189/368) of the known sigma70-specific promoters occurring upstream of an expressed open reading frame and 74% (273/368) within 1,000 bp. Conversely, many known promoters were not detected by chIP-chip, leading to an estimated 26% negative-detection rate. Most of the detected binding sites could be associated with expressed transcription units, but 299 binding sites occurred near inactive transcription units. This map of RNA polymerase binding sites represents a foundation for studies of transcription factors in E. coli and an important evaluation of the chIP-chip technique.

Temperature-sensitive protein-DNA dimerizers.

Programmable DNA-binding polyamides coupled to short peptides have led to the creation of synthetic artificial transcription factors. A hairpin polyamide-YPWM tetrapeptide conjugate facilitates the binding of a natural transcription factor Exd to an adjacent DNA site. Such small molecules function as protein-DNA dimerizers that stabilize complexes at composite DNA binding sites. Here we investigate the role of the linker that connects the polyamide to the peptide. We find that a substantial degree of variability in the linker length is tolerated at lower temperatures. At physiological temperatures, the longest linker tested confers a "switch"-like property on the protein-DNA dimerizer, in that it abolishes the ability of the YPWM moiety to recruit the natural transcription factor to DNA. These observations provide design principles for future artificial transcription factors that can be externally regulated and can function in concert with the cellular regulatory circuitry.