Douglas F. Browning

The regulation of bacterial transcription initiation

Bacteria use their genetic material with great effectiveness to make the right products in the correct amounts at the appropriate time. Studying bacterial transcription initiation in Escherichia coli has served as a model for understanding transcriptional control throughout all kingdoms of life. Every step in the pathway between gene and function is exploited to exercise this control, but for reasons of economy, it is plain that the key step to regulate is the initiation of RNA-transcript formation.

Modulation of Shigella virulence in response to available oxygen in vivo

Bacteria coordinate expression of virulence determinants in response to localized microenvironments in their hosts. Here we show that Shigella flexneri, which causes dysentery, encounters varying oxygen concentrations in the gastrointestinal tract, which govern activity of its type three secretion system (T3SS). The T3SS is essential for cell invasion and virulence. In anaerobic environments (for example, the gastrointestinal tract lumen), Shigella is primed for invasion and expresses extended T3SS needles while reducing Ipa (invasion plasmid antigen) effector secretion. This is mediated by FNR (fumarate and nitrate reduction), a regulator of anaerobic metabolism that represses transcription of spa32 and spa33, virulence genes that regulate secretion through the T3SS. We demonstrate there is a zone of relative oxygenation adjacent to the gastrointestinal tract mucosa, caused by diffusion from the capillary network at the tips of villi. This would reverse the anaerobic block of Ipa secretion, allowing T3SS activation at its precise site of action, enhancing invasion and virulence.

Effects of nucleoid-associated proteins on bacterial chromosome structure and gene expression

Bacterial nucleoid-associated proteins play a key role in the organisation, replication, segregation, repair and expression of bacterial chromosomes. Here, we review some recent progress in our understanding of the effects of these proteins on DNA and their biological role, focussing mainly on Escherichia coli and its chromosome. Certain nucleoid-associated proteins also regulate transcription initiation at specific promoters, and work in concert with dedicated transcription factors to regulate gene expression in response to growth phase and environmental change. Some specific examples, involving the E. coli IHF and Fis proteins, that illustrate new principles, are described in detail.

Regulation of Acetyl Coenzyme A Synthetase in Escherichia coli

Cells of Escherichia coli growing on sugars that result in catabolite repression or amino acids that feed into glycolysis undergo a metabolic switch associated with the production and utilization of acetate. As they divide exponentially, these cells excrete acetate via the phosphotransacetylase-acetate kinase pathway. As they begin the transition to stationary phase, they instead resorb acetate, activate it to acetyl coenzyme A (acetyl-CoA) by means of the enzyme acetyl-CoA synthetase (Acs) and utilize it to generate energy and biosynthetic components via the tricarboxylic acid cycle and the glyoxylate shunt, respectively. Here, we present evidence that this switch occurs primarily through the induction of acs and that the timing and magnitude of this induction depend, in part, on the direct action of the carbon regulator cyclic AMP receptor protein (CRP) and the oxygen regulator FNR. It also depends, probably indirectly, upon the glyoxylate shunt repressor IclR, its activator FadR, and many enzymes involved in acetate metabolism. On the basis of these results, we propose that cells induce acs, and thus their ability to assimilate acetate, in response to rising cyclic AMP levels, falling oxygen partial pressure, and the flux of carbon through acetate-associated pathways.

Transcription factor distribution in Escherichia coli: studies with FNR protein

Using chromatin immunoprecipitation (ChIP) and high-density microarrays, we have measured the distribution of the global transcription regulator protein, FNR, across the entire Escherichia coli chromosome in exponentially growing cells. Sixty-three binding targets, each located at the 5′ end of a gene, were identified. Some targets are adjacent to poorly transcribed genes where FNR has little impact on transcription. In stationary phase, the distribution of FNR was largely unchanged. Control experiments showed that, like FNR, the distribution of the nucleoid-associated protein, IHF, is little altered when cells enter stationary phase, whilst RNA polymerase undergoes a complete redistribution.

The NsrR Regulon of Escherichia coli K-12 Includes Genes Encoding the Hybrid Cluster Protein and the Periplasmic, Respiratory Nitrite Reductase

Successful pathogens must be able to protect themselves against reactive nitrogen species generated either as part of host defense mechanisms or as products of their own metabolism. The regulatory protein NsrR (a member of the Rrf2 family of transcription factors) plays key roles in this stress response. Microarray analysis revealed that NsrR represses nine operons encoding 20 genes in Escherichia coli MG1655, including the hmpA, ytfE, and ygbA genes that were previously shown to be regulated by NsrR. Novel NsrR targets revealed by this study include hcp-hcr (which were predicted in a recent bioinformatic study to be NsrR regulated) and the well-studied nrfA promoter that directs the expression of the periplasmic respiratory nitrite reductase. Conversely, transcription from the ydbC promoter is strongly activated by NsrR. Regulation of the nrf operon by NsrR is consistent with the ability of the periplasmic nitrite reductase to reduce nitric oxide and hence protect against reactive nitrogen species. Gel retardation assays were used to show that both FNR and NarL bind to the hcp promoter. The expression of hcp and the contiguous gene hcr is not induced by hydroxylamine. As hmpA and ytfE encode a nitric oxide reductase and a mechanism to repair iron-sulfur centers damaged by nitric oxide, the demonstration that hcp-hcr, hmpA, and ytfE are the three transcripts most tightly regulated by NsrR highlights the possibility that the hybrid cluster protein, HCP, might also be part of a defense mechanism against reactive nitrogen stress.

Structure and function of BamE within the outer membrane and the β‐barrel assembly machine

Insertion of folded proteins into the outer membrane of Gram‐negative bacteria is mediated by the essential β‐barrel assembly machine (Bam). Here, we report the native structure and mechanism of a core component of this complex, BamE, and show that it is exclusively monomeric in its native environment of the periplasm, but is able to adopt a distinct dimeric conformation in the cytoplasm. BamE is shown to bind specifically to phosphatidylglycerol, and comprehensive mutagenesis and interaction studies have mapped key determinants for complex binding, outer membrane integrity and cell viability, as well as revealing the role of BamE within the Bam complex.

Local and global regulation of transcription initiation in bacteria

Gene expression in bacteria relies on promoter recognition by the DNA-dependent RNA polymerase and subsequent transcription initiation. Bacterial cells are able to tune their transcriptional programmes to changing environments, through numerous mechanisms that regulate the activity of RNA polymerase, or change the set of promoters to which the RNA polymerase can bind. In this Review, we outline our current understanding of the different factors that direct the regulation of transcription initiation in bacteria, whether by interacting with promoters, with RNA polymerase or with both, and we discuss the diverse molecular mechanisms that are used by these factors to regulate gene expression.

Independent regulation of the divergent Escherichia coli nrfA and acsP1 promoters by a nucleoprotein assembly at a shared regulatory region

Expression from the Escherichia coli nrfA promoter (pnrfA) is activated by both the FNR protein (an anaerobically triggered transcription activator) and the NarL or NarP proteins (transcription activators triggered by nitrite and nitrate). Under anaerobic conditions, FNR binds to a site centred at position –41.5 at pnrfA and activates transcription. Further activation, induced by the presence of nitrite, results from the binding of NarL and NarP to a site centred at position –74.5. A second promoter (pacsP1), which directs transcription into the adjacent gene encoding acetyl coenzyme A synthetase (acs), is overlapping and divergent to pnrfA. Despite extensive overlap of regulatory elements, pnrfA and pacsP1 are regulated independently. We demonstrate that at least two nucleoid‐associated factors bind to the nrfA–acs intergenic region. The Fis protein binds to a site centred at position –15 (in relation to pnrfA transcription), whereas the IHF protein binds to a site centred at position –54. Both Fis and IHF repress in vivo expression from pacsP1, but have smaller repressive effects on expression from pnrfA. Gel retardation assays were used to investigate the pairwise binding of FNR, NarL, Fis and IHF proteins to the nrfA–acs intergenic region. The binding of NarL and IHF is mutually exclusive, whereas all other combinations can bind simultaneously. Experiments in which deletions and point mutations were introduced into the upstream region of pnrfA demonstrated that an additional factor must bind upstream to inhibit FNR‐dependent transcription. We conclude that the nrfA–acs intergenic region is folded into an ordered nucleoprotein structure that permits the two divergent promoters to be regulated independently in response to different physiological signals.

Suppression of FNR-dependent transcription activation at the Escherichia coli nir promoter by Fis, IHF and H-NS: modulation of transcription initiation by a complex nucleo-protein assembly.

Expression from the Escherichia coli nir promoter is co‐dependent on both the FNR protein (an anaerobically triggered transcription activator) and the NarL or NarP proteins (transcription activators triggered by nitrite and nitrate). Under anaerobic conditions, FNR binds to a site centred between positions −41 and −42, activating transcription of the nir operon. In previous work, we showed that this activation is suppressed by the binding of Fis protein, and at least one other protein, to sequence elements located upstream of the nir promoter. We proposed that the binding of NarL or NarP to a site centred between positions −69 and −70 counteracts this suppression, resulting in increased transcription in response to nitrite or nitrate. Here we have further investigated the different proteins that downregulate the nir promoter. We show that the nir promoter is repressed by three DNA binding proteins, Fis, IHF and H‐NS. We demonstrate that, in addition to binding to its previously characterized upstream site located at position −142, Fis also binds to a second downstream site located at position +23. A second suppressing factor is IHF, that binds to a site located at position −88. Finally, the nucleoid associated protein, H‐NS, preferentially binds to upstream sequences at the nir promoter and represses promoter activity. The association of Fis, IHF and H‐NS suggests that nir promoter DNA is sequestrated into a highly ordered nucleo‐protein structure that represses FNR‐dependent transcription activation. NarL and NarP can relieve both IHF‐ and Fis‐mediated repression, but are unable to counteract H‐NS‐mediated repression.