On the role of small regulatory molecules in the interplay between σ54- and σ70-dependent transcription

Holmfeldt, Linda

January 2009

Signal responsive transcriptional control in bacteria is mediated through both specific and global regulatory circuits to attune promoter output to prevailing conditions. Divergent transcription of a regulatory gene and a cognate promoter under its control provides an opportunity for interplay between transcription dependent on RNA polymerases utilizing various σ-factors, each of which programs the holoenzyme to recognize different classes of promoters. The work presented in this thesis analyses the consequences and mechanisms behind interplay between σ54- and σ70-dependent transcription within the dmp-system of Pseudomonas sp. CF600. The dmp-system confers the ability to grow at the expense of (methyl)phenols and is controlled by two promoters that drive non-overlapping divergent transcription from a common intergenic region: i) the σ54-Po promoter, which controls an operon encoding a suit of specialized catabolic enzymes, and ii) the σ70-Pr promoter, which controls production of the aromatic sensor DmpR - a mechano-activator whose transcription-promoting activity is obligatory for activity of the σ54-Po promoter. The σ54-Po promoter and its dependence on two non-classical transcriptional regulators - the alarmone ppGpp and its co-factor DksA that directly target RNA polymerase - are the focus of the first part of the thesis. These studies utilized ppGpp and DksA deficient strains, mutant RNA polymerases that bypass the need for ppGpp and DksA, reconstituted in vitro transcription systems, and a series of DmpR-regulated hybrid σ54-promoters with different affinities for σ54-RNA polymerase, together with analysis of protein levels of key transcriptional components. Collectively with previous work, these studies provide the experimental support for a robust but purely passive mechanism for ppGpp and DksA global regulation of σ54-transcription, which is likely to also be pertinent for transcription mediated via any alternative σ-factor (Papers I-III). The second part of the thesis focuses on additional roles of ppGpp and DksA through their direct and indirect effects on the activity of the σ70-Pr promoter. These studies unexpectedly revealed that the σ70-Pr promoter is regulated by a novel mechanism in which σ54-RNA polymerase occupancy and activity at the σ54-Po promoter stimulates σ70-Pr output. Evidence is presented that ppGpp and DksA, through DmpR levels, control a feed forward loop to reinforce silence of the σ54-Po promoter under high energy conditions with robust transcription from σ54-Po when the catabolic enzymes are needed. The interplay outlined above effectively places a σ70-dependent promoter under dual control of two forms of RNA polymerases, and also makes it subservient to regulatory signals that elicit activity of σ54-RNA polymerase. The possibility that such dual sensitivity may be a prevalent, but previously unappreciated, mechanism by which bacteria integrate diverse and/or conflicting signals to gain appropriate transcriptional control is discussed.

σ54

σ70

ppGpp

DksA

transcription regulation

Molecular biology

Molekylärbiologi

On the role of ppGpp and DksA mediated control of σ54-dependent transcription

Bernardo, Lisandro

January 2006

The σ54-dependent Po promoter drives transcription of an operon that encodes a suite of enzymes for (methyl)phenols catabolism. Transcription from Po is controlled by the sensor-activator DmpR that binds (methyl)phenol effectors to take up its active form. The σ54 factor imposes kinetic constraints on transcriptional initiation by the σ54-RNA polymerase holoenzyme which cannot undergo transition from the closed complex without the aid of the activator. DmpR acts from a distance on promoter-bound σ54-holoenzyme, and physical contact between the two players is facilitated by the DNA-bending protein IHF. The bacterial alarmone ppGpp and DksA directly bind RNA polymerase to have far reaching consequences on global transcriptional capacity in the cell. The work presented in this thesis uses the DmpR-regulated Po promoter as a framework to dissect how these two regulatory molecules act in vivo to control the functioning of σ54-dependent transcription. The strategies employed involved development of i) a series of hybrid σ54-promoters that could be directly compared and in which key DNA elements could be manipulated ii) mutants incapable of synthesizing ppGpp and/or DksA, iii) reconstituted in vitro transcription systems, and iv) genetic selection and purification of mutant RNA polymerases that bypass the need for ppGpp and DksA in vivo. The collective results presented show that the effects of ppGpp and DksA on σ54-dependent transcription are major, with simultaneous loss of these regulatory molecules essentially abolishing σ54-transcription in intact cells. However, neither of these regulatory molecules have discernable effects on in vitro reconstituted σ54-transcription, suggesting an indirect mechanism of control. The major effects of ppGpp and DksA in vivo cannot be accounted for by consequent changes in the levels of DmpR or other specific proteins needed for σ54-transcription. The data presented here shows i) that the effects of loss of ppGpp and DksA are related to promoter affinity for σ54-holoenzyme, ii) that σ54 is under significant competition with other σ-factors in the cell, and iii) that mutants of σ70, and the beta- and beta prime-subunits of RNA polymerase that can bypass the need for ppGpp and DksA in vivo have defects that would favour the formation of σ54-RNA holoenzyme over that with σ70, and that mimic the effects of ppGpp and DksA for negative regulation of stringent σ70-promoters. A purely passive model for ppGpp/DksA regulation of σ54-dependent transcription that functions through their potent negative effects on transcription from powerful σ70-stringent promoters is presented.

ppGpp

DksA

σ54-transcription

global regulation

E. coli

P. putida

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

DksA Beyond the Stringent Response: Investigating the Functions of a Diverse Bacterial Transcription Factor

Furman, Ran

27 August 2013

No description available.

Biochemistry

Microbiology

RNA polymerase

DksA

Transcription factor

Metal ion

ppGpp

Acid stress

stringent response

New insights into the role of ppGpp and DksA through their effect on transcriptional regulation of housekeeping and colonization related genes of Escherichia coli

Åberg, Anna

January 2008

Bacteria have the ability to sense different environmental signals. When an environmental stress is detected, bacteria rapidly adjust their gene expression profile to be able to survive and thrive. The transduction of such environmental signals often requires the coordinated involvement of several factors that constitute complex regulatory networks. Hence, depending on the combination of signals, a unique gene expression profile required to adapt to the specific stress conditions is generated. Proteins are the best-known regulatory factors. However, non-proteinaceous molecules are also important in signal-responsive control of bacterial gene expression. Alarmones are low molecular weight non-proteinaceous regulatory factors which can characteristically be rapidly turned-over to mediate instant changes in gene expression. One such alarmone is the modified nucleotide ppGpp, which directly binds to RNA polymerase to alter its activity. The levels of this alarmone are expected to rapidly increase in response to any environmental stress that result in slow proliferation. DksA, a putative ppGpp co-regulator that likewise directly targets RNA polymerase, has been suggested to be required for both the positive and negative regulation mediated by ppGpp in Escherichia coli. This thesis describes dissection of the role of ppGpp and DksA on transcriptional regulation, primarily using the fim genetic determinant that encodes for the type 1 fimbriae. Type 1 fimbriae are involved in adhesion to abiotic surface and initial adhesion/invasion of bladder cells, as well as in biofilm formation. We found that ppGpp regulates phase variation by increasing the sub-population of cells that express the fimbriae. The effect of ppGpp was ultimately traced to its role in transcription of the fimB gene that encodes a recombinase involved in the phase variation process (paper 1). In contrast, we unexpectedly found that lack of DksA causes an increase, rather than a decrease, in transcription from the fimB P2 promoter in vivo. However, in vitro transcription studies demonstrated that ppGpp and DksA, both independently and co-dependently, stimulate transcription from the fimB P2 promoter. These seemingly contradictory results from the in vivo and in vitro transcriptional studies were shown to be, at least in part, a consequence of the increased association of Gre-factors with RNA polymerase that can occur in the absence of DksA in vivo (paper 2). The results outlined above have implications for the role of ppGpp and/or DksA in global gene expression. Using gene expression profile (microarray analysis) during the transition from logarithmic to stationary phase of E. coli, we found that while most of the genes regulated by ppGpp and DksA are regulated in the same direction by the two factors, many were not. In addition to the fim genes, genes involved in flagella functioning, taxis responses, and a few genes encoding different transport systems are also differentially regulated in ppGpp- and DksA-deficient strains in vivo. Our results clearly indicate that the effect of deficiencies in ppGpp and DksA is far more complex than phenotypic similarity of the corresponding mutants anticipated by the proposed concerted action of ppGpp and DksA on gene expression (paper 2 & 3).

Escherichia coli

type 1 fimbriae

fimB

phase variation

transcription

global gene regualtion

ppGpp

DksA

gre-factors

RNA polymerase

Medical microbiology

Medicinsk mikrobiologi