Specificity mechanisms in the control of transcription

Hippel, Peter H. von; Rees, William; Rippe, Karsten; Wilson, Kevin S.

doi:10.1016/0301-4622(96)00006-3

Cited by 34 publications

(34 citation statements)

References 39 publications

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“…Although the mechanism by which P1 activation occurs in the rho mutants is not known, two lines of evidence suggest that it may be related to the relief of attenuation of transcripts initiated from P1. First, such a mechanism will be consistent with the previously characterized activities and functions of the Rho protein (21,44,56). Second, the rho mutant effect is considerably diminished for S. enterica P1⌬att (plasmid pHYD374), which bears the deletion of a 22-base C-rich segment (on the coding strand) and which has previously been shown (42) to be defective in attenuation.…”

Section: Discussionsupporting

confidence: 81%

In Vivo Expression from the RpoS-Dependent P1 Promoter of the Osmotically Regulated proU Operon in Escherichia coli and Salmonella enterica Serovar Typhimurium: Activation by rho and hns Mutations and by Cold Stress

Rajkumari

Gowrishankar

2001

J Bacteriol

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Unlike the 70 -controlled P2 promoter for the osmotically regulated proU operon of Escherichia coli and Salmonella enterica serovar Typhimurium, the s -controlled P1 promoter situated further upstream appears not to contribute to expression of the proU structural genes under ordinary growth conditions. For S. enterica proU P1, there is evidence that promoter crypticity is the result of a transcription attenuation phenomenon which is relieved by the deletion of a 22-base C-rich segment in the transcript. In this study, we have sought to identify growth conditions and trans-acting mutations which activate in vivo expression from proU P1. The cryptic S. enterica proU P1 promoter was activated, individually and additively, in a rho mutant (which is defective in the transcription termination factor Rho) as well as by growth at 10°C. The E. coli proU P1 promoter was also cryptic in constructs that carried 1.2 kb of downstream proU sequence, and in these cases activation of in vivo expression was achieved either by a rho mutation during growth at 10°C or by an hns null mutation (affecting the nucleoid protein H-NS) at 30°C. The rho mutation had no effect at either 10 or 30°C on in vivo expression from two other s -controlled promoters tested, those for osmY and csiD. In cells lacking the RNA-binding regulator protein Hfq, induction of E. coli proU P1 at 10°C and by hns mutation at 30°C was still observed, although the hfq mutation was associated with a reduction in the absolute levels of P1 expression. Our results suggest that expression from proU P1 is modulated both by nucleoid structure and by Rhomediated transcription attenuation and that this promoter may be physiologically important for proU operon expression during low-temperature growth.The ProU transporter in Escherichia coli and Salmonella enterica serovar Typhimurium is a binding-protein-dependent transport system that mediates the cytoplasmic accumulation of compatible solutes such as glycine betaine, L-proline, and related compounds during growth of cells in media of elevated osmolarity (9, 10). The subunit polypeptides of the transporter are encoded by three genes, proV, proW, and proX, which together constitute (in that order) the proU operon (16).Transcription of proU in both E. coli and S. enterica is activated several-hundredfold in cultures grown in high-osmolarity media, but the mechanism of osmotic induction of the operon is not fully understood (reviewed in references 10, 19, and 29). Two cis regulatory elements that have been identified (see Fig. 1) include a 70 -driven promoter whose transcription start site is situated 60 bases upstream of proV (16, 24, 28, 54) and a negative regulatory element (NRE) approximately 500 bp long, which is situated downstream of the promoter (overlapping the proV coding region) and whose deletion results in partial derepression of proU at low osmolarity (11,24,37,38). Mutations in hns, the gene encoding an abundant nucleoid protein, H-NS, also result in partial derepression of proU expression (for a review of H-NS...

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Section: Discussionsupporting

confidence: 81%

In Vivo Expression from the RpoS-Dependent P1 Promoter of the Osmotically Regulated proU Operon in Escherichia coli and Salmonella enterica Serovar Typhimurium: Activation by rho and hns Mutations and by Cold Stress

Rajkumari

Gowrishankar

2001

J Bacteriol

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“…Combine this wash with the first eluate and evaporate them using a Speed-Vac. Add 1ml of NH 4 OH to the column, flush it back and forth and allow it to stand for 1 hour. Add this NH 4 OH eluate to the corresponding DBU/acetonitryl eluate pellet (from the speed vac) and heat it for 14 hrs at 55°C.…”

Section: Oligonucleotidesmentioning

confidence: 99%

Structural Confirmation of a Bent and Open Model for the Initiation Complex of T7 RNA Polymerase

et al. 2007

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T7 RNA polymerase is known to induce bending of its promoter DNA upon binding, as evidenced by gel-shift assays and by recent end-to-end fluorescence energy transfer distance measurements. Crystal structures of promoter-bound and initially transcribing complexes, however, lack downstream DNA, providing no information on the overall path of the DNA through the protein.Crystal structures of the elongation complex do include downstream DNA and provide valuable guidance in the design of models for the complete melted bubble structure at initiation. In the current study, we test a specific structural model for the initiation complex, obtained by alignment of the Cterminal regions of the protein structures from both initiation and elongation and then simple transferal of the downstream DNA from the elongation complex onto the initiation complex. FRET measurement of distances from a point upstream on the promoter DNA to various points along the downstream helix reproduce the expected helical periodicity in the distances and support the model's orientation and phasing of the downstream DNA. The model also makes predictions about the extent of melting downstream of the active site. By monitoring fluorescent base analogs incorporated at various positions in the DNA we have mapped the downstream edge of the bubble, confirming the model. The initially melted bubble, in the absence of substrate, encompasses 7-8 bases and is sufficient to allow synthesis of a 3 base transcript before further melting is required. The results demonstrate that despite massive changes in the N-terminal portion of the protein and in the DNA upstream of the active site, the DNA downstream of the active site is virtually identical in both initiation and elongation complexes.

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“…To this respect, we remark that each match will stabilize the complex, while mismatches will act as to destabilize the protein, which will tend therefore to move away from the "wrong" positions [6,7]. For each position n along the chain we can therefore define an energy E(n), simply by counting the number of matches and mismatches, and adding a corresponding negative or positive amount of energy, respectively (empty sites in the recognition pattern do not contribute to the energy).…”

Section: Sequence Dependent Diffusive Modelmentioning

confidence: 99%

“…This hypothesis can be justified on the basis of some known protein-DNA complex features. The stability of the protein-DNA nonspecific complex is mainly due to electrostatic interaction with the backbone phosphate of DNA [7] and to the entropic release of cations [19][20][21]. Besides these stabilizing factors, sequencedependent interaction allows the protein to test the DNA during the target search [17].…”

Section: Protein-dna Interaction and Specific Site Recognitionmentioning

confidence: 99%

“…It is believed that during the sliding motion, the activation barrier for the translocation of the protein to continuous nonspecific positions is high enough to randomize the protein motion through collisions with the solvent molecules, but appropriately small compared to the thermal energy, in order to allow the protein to move [6]. This has induced some authors to propose a model where protein freely slides along DNA under the effect of the thermal fluctuations without any sequence dependent interaction, i.e., the DNA is seen as an homogeneous cylinder on which the protein can diffuse until the specific site is reached [6][7][8]. During sliding, however, the protein must be able to distinguish the specific region from nonspecific DNA so that a recognition mechanism must be involved.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Model of Sequence-Dependent Protein Diffusion Along DNA

Barbi

Place

Popkov

et al. 2004

Journal of Biological Physics

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Abstract.We introduce a probabilistic model for protein sliding motion along DNA during the search of a target sequence. The model accounts for possible effects due to sequence-dependent interaction between the nonspecific DNA and the protein. Hydrogen bonds formed at the target site are used as the main sequence-dependent interaction between protein and DNA. The resulting dynamical properties and the possibility of an experimental verification are discussed in details. We show that, while at large times the process reaches a linear diffusion regime, it initially displays a sub-diffusive behavior. The sub-diffusive regime can last sufficiently long to be of biological interest.

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Specificity mechanisms in the control of transcription

Cited by 34 publications

References 39 publications

In Vivo Expression from the RpoS-Dependent P1 Promoter of the Osmotically Regulated proU Operon in Escherichia coli and Salmonella enterica Serovar Typhimurium: Activation by rho and hns Mutations and by Cold Stress

In Vivo Expression from the RpoS-Dependent P1 Promoter of the Osmotically Regulated proU Operon in Escherichia coli and Salmonella enterica Serovar Typhimurium: Activation by rho and hns Mutations and by Cold Stress

Structural Confirmation of a Bent and Open Model for the Initiation Complex of T7 RNA Polymerase

A Model of Sequence-Dependent Protein Diffusion Along DNA

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