Transcription activation by phage phi29 protein p4 is mediated by interaction with the alpha subunit of Bacillus subtilis RNA polymerase.

Mencı́a, Mario; Monsalve, Marı́a; Rojo, Fernando; Salas, Margarita

doi:10.1073/pnas.93.13.6616

Cited by 48 publications

(51 citation statements)

References 32 publications

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“…As expected, when RNAP was the only protein incubated with the DNA fragment, binding of RNAP to PA2b and PA2c was detected (Fig. 3, lane 2; Rojo and Salas 1995;Monsalve et al 1996a). When p4 (330 nM) and RNAP were simultaneously present, the set of hypersensitive bands that characterize binding of p4 immediately upstream of RNAP at PA2c and PA3 was observed; in addition, the −82 hypersensitive band at PA2b was lost as a conse- Figure 3.…”

Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Prosupporting

confidence: 61%

“…Thus, the presence of RNAP is not essential for p4 to exert its effect on the binding of p6 to this DNA region. Because p4 binds with very low affinity to its site at PA2c and with high affinity to its site at PA3 in the absence of RNAP Monsalve et al 1996a), these observations suggest that it is the binding of p4 to the latter site that is important in facilitating binding of p6.…”

Section: Genes and Development 2507mentioning

confidence: 95%

“…Arrows at right indicate DNase I hypersensitivities created on binding of protein p6 (numbered relative to the transcription start site at PA2c) and binding of protein p4 to PA3 (numbered relative to the transcription start sites at PA2c/PA3). Numbers in boxes are the specific bands that were densitometrically scanned to obtain data presented in Table 1. quence of p4 binding at PA3 Monsalve et al 1996a). Because the presence of p4 is required for stabilization of RNAP at PA3, protection downstream of the p4-binding site at this promoter was now observed because of the binding of RNAP to PA3.…”

Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Promentioning

confidence: 99%

“…It should be noted that although the footprint assay presented here was performed in the absence of nucleotides (to visualize binding of RNAP to PA3, which would otherwise escape the promoter), the same results regarding PA2c were obtained in the presence of nucleotides. Basically, the footprint that characterizes protein p4 holding the RNAP at PA2c (Monsalve et al 1996a) was replaced by that of protein p6 bound to this promoter (data not shown).…”

Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Promentioning

confidence: 99%

“…8). When p6 is absent, binding of p4 to its PA2c site causes repression by preventing RNAP promoter clearance (Monsalve et al 1996a). However, in the presence of both p4 and p6, it is p6 that directly represses PA2c by blocking access to RNAP.…”

Section: The Interplay Between P6 and P4 In Dna Binding And Transcripmentioning

confidence: 99%

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Functional interactions between a phage histone-like protein and a transcriptional factor in regulation of phi 29 early-late transcriptional switch

Elías‐Arnanz

Salas²

1999

Genes & Development

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Protein p6 is a nonspecific DNA-binding protein occurring in high abundance in phage 29-infected cells. Here, we demonstrate a novel role for this versatile histone-like protein: its involvement in regulating the viral switch between early and late transcription. p6 performs this role by exhibiting a reciprocal functional interaction with the regulatory protein p4, also phage encoded, which is required for repression of the early A2b and A2c promoters and activation of the late A3 promoter. On the one hand, p6 promotes p4-mediated repression of the A2b promoter and activation of the A3 promoter by enhancing binding of p4 to its recognition site at PA3; on the other, p4 promotes p6-mediated repression of the A2c promoter by favoring the formation of a stable p6-nucleoprotein complex that interferes with RNA polymerase binding to PA2c. We propose that the observed interplay between proteins p6 and p4 is based on their DNA architectural properties. The process of transcription, like other DNA transactions such as replication and recombination, occurs on an inherently stiff molecule (see Shore and Baldwin 1983;Wang and Giaever 1988). However, DNA must be at least locally flexible for the appropriate nucleoprotein complexes to assemble. This requirement is partially fulfilled by the participation of DNA-binding proteins that have the ability to remodel DNA (Nash 1990(Nash , 1996Grosschedl et al. 1994;Werner and Burley 1997). Such architectural factors are found in both eukaryotes and prokaryotes and include specific as well as nonspecific DNA-binding proteins.Nonspecific architectural factors presumably regulate transcription by introducing conformational changes that either hinder or assist DNA recognition by sequence-specific control proteins. In prokaryotes, there is substantial evidence that factors capable of altering general DNA flexibility such as the major histone-like proteins HU and H-NS can also function as transcriptional modulators. Thus, HU has been shown to stimulate lac repressor-operator binding and CAP binding to lac DNA (Flashner and Gralla 1988), to stabilize Mu repressor binding to the Mu early operator (Betermier et al. 1995), to aid in GalR-mediated repression of the gal operon (Aki and Adhya 1997), and to displace the LexA repressor from its DNA-binding sites (Preobrajenskaya et al. 1994). Likewise, H-NS has been reported to influence transcription of a number of genes involved in diverse biological processes (Falconi et al. 1993;Zuber et al. 1994;Atlung and Ingmer 1997;Williams and Rimsky 1997).In eukaryotes, the abundant nonhistone chromosomal protein HMG-1 (and the highly homologous protein HMG-2) also functions as an architectural element in the assembly of several transcriptional nucleoprotein complexes (for review, see Grosschedl et al. 1994;Bustin and Reeves 1996). Thus, HMG-1 and HMG-2 have been shown to enhance the sequence-specific DNA binding of a variety of proteins, such as steroid receptors (Oñ ate et al. 1994;Verrier et al. 1997;Boonyaratanakornkit et al. 1998); the POU domain-...

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Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Prosupporting

confidence: 61%

Section: Genes and Development 2507mentioning

confidence: 95%

Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Promentioning

confidence: 99%

Section: Protein P6 Enhances Binding Of Protein P4 To Pa3 Whereas Promentioning

confidence: 99%

Section: The Interplay Between P6 and P4 In Dna Binding And Transcripmentioning

confidence: 99%

See 3 more Smart Citations

Functional interactions between a phage histone-like protein and a transcriptional factor in regulation of phi 29 early-late transcriptional switch

Elías‐Arnanz

Salas²

1999

Genes & Development

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Bacteriophage Ø29 protein p6: an architectural protein involved in genome organization, replication and control of transcription

González-Huici

Alcorlo

Salas

et al. 2004

J of Molecular Recognition

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Protein p6 of B. subtilis bacteriophage Ø29 binds to DNA forming a nucleoprotein complex in which the DNA wraps a protein core forming a right-handed superhelix, therefore restraining positive supercoiling and compacting the DNA. The protein does not specifically recognize a nucleotide sequence but rather a structural feature and it binds as a dimer through the minor groove. Protein p6 is in a monomer-dimer equilibrium that shifts to higher-order structures at a concentration of about 1 mM. These structures are probably present in vivo as the intracellular concentration of p6 is estimated to be in this range, and in fact the effective concentration should be still higher due to the macromolecular crowding. The p6 oligomers show an elongated shape compatible with a helical structure reminiscent of the superhelical DNA of the nucleoprotein complex, therefore it was proposed that protein p6 forms a scaffold on which the DNA folds. Since protein p6 is very abundant in infected cells, enough to bind the entire viral progeny, it was proposed to have an architectural role organizing and compacting the viral genome. It has been demonstrated that protein p6 binds in vivo to most, if not all, the Ø29 genome, although with different affinity, the highest one corresponding to the genome ends. Binding to plasmidic DNA was much lower, although it increased dramatically when the negative superhelicity was decreased. Hence, protein p6 binding specificity for Ø29 DNA is based on supercoiling, providing that the Ø29 genome, although topologically constrained, has a negative superhelicity lower than that of plasmid DNA. The formation of the nucleoprotein complex has functional implications in DNA replication and the control of transcription. It activates the initiation of replication that occurs at the genome ends for which the binding affinity is highest. It represses early transcription from promoter C2, and, together with protein p4, it represses transcription from promoters A2b and A2c and activates late transcription from promoter A3; therefore, protein p6 is involved in the early to late transcription switch.

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Helicobacter pylori RNA polymerase α‐subunit C‐terminal domain shows features unique to ɛ‐proteobacteria and binds NikR/DNA complexes

2014

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Bacterial RNA polymerase is a large, multi-subunit enzyme responsible for transcription of genomic information. The C-terminal domain of the a subunit of RNA polymerase (aCTD) functions as a DNA and protein recognition element localizing the polymerase on certain promoter sequences and is essential in all bacteria. Although aCTD is part of RNA polymerase, it is thought to have once been a separate transcription factor, and its primary role is the recruitment of RNA polymerase to various promoters. Despite the conservation of the subunits of RNA polymerase among bacteria, the mechanisms of regulation of transcription vary significantly. We have determined the tertiary structure of Helicobacter pylori aCTD. It is larger than other structurally determined aCTDs due to an extra, highly amphipathic helix near the C-terminal end. Residues within this helix are highly conserved among E-proteobacteria. The surface of the domain that binds A/T rich DNA sequences is conserved and showed binding to DNA similar to aCTDs of other bacteria. Using several NikR dependent promoter sequences, we observed cooperative binding of H. pylori aCTD to NikR:DNA complexes. We also produced aCTD lacking the 19 C-terminal residues, which showed greatly decreased stability, but maintained the core domain structure and binding affinity to NikR:DNA at low temperatures. The modeling of H. pylori aCTD into the context of transcriptional complexes suggests that the additional amphipathic helix mediates interactions with transcriptional regulators.

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Transcription activation by phage phi29 protein p4 is mediated by interaction with the alpha subunit of Bacillus subtilis RNA polymerase.

Cited by 48 publications

References 32 publications

Functional interactions between a phage histone-like protein and a transcriptional factor in regulation of phi 29 early-late transcriptional switch

Functional interactions between a phage histone-like protein and a transcriptional factor in regulation of phi 29 early-late transcriptional switch

Bacteriophage Ø29 protein p6: an architectural protein involved in genome organization, replication and control of transcription

Helicobacter pylori RNA polymerase α‐subunit C‐terminal domain shows features unique to ɛ‐proteobacteria and binds NikR/DNA complexes

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