Sigma subunit of Escherichia coli RNA polymerase loses contacts with the 3' end of the nascent RNA after synthesis of a tetranucleotide

UBF activates RNA polymerase I transcription by stimulating promoter escape

Ribosomal RNA gene transcription by RNA polymerase I (Pol I) is the driving force behind ribosome biogenesis, vital to cell growth and proliferation. The key activator of Pol I transcription, UBF, has been proposed to act by facilitating recruitment of Pol I and essential basal factor SL1 to rDNA promoters. However, we found no evidence that UBF could stimulate recruitment or stabilization of the pre-initiation complex (PIC) in reconstituted transcription assays. In this, UBF is fundamentally different from archetypal activators of transcription. Our data imply that UBF exerts its stimulatory effect on RNA synthesis, after PIC formation, promoter opening and first phosphodiester bond formation and before elongation. We provide evidence to suggest that UBF activates transcription in the transition between initiation and elongation, at promoter escape by Pol I. This novel role for UBF in promoter escape would allow control of rRNA synthesis at active rDNA repeats, independent of and complementary to the promoter-specific targeting of SL1 and Pol I during PIC assembly. We posit that stimulation of promoter escape could be a general mechanism of activator function.

Template-dependent incorporation of 8-N3AMP into RNA with bacteriophage T7 RNA polymerase

UV-induced photochemical crosslinking is a powerful approach that can be used for the identification of specific interactions involving nucleic acid-protein and nucleic acid-nucleic acid complexes. 8-AzidoATP (8-N(3)ATP) is a photoaffinity-labeling agent which has been widely used to elucidate the ATP binding site of a variety of proteins. However, its true potential as a photoactivatable nucleotide analog could not be exploited due to the lack of 8-azidoadenosine phosphoramidite, a monomer used in the synthesis of RNA, and the inability of 8-N(3)ATP to serve as an efficient substrate for bacteriophage RNA polymerase. In this study, we explored the ability of SP6, T3, and T7 RNA polymerases and metal ion cofactors to catalyze the incorporation of 8-N(3)AMP into RNA. Whereas transcription buffer containing 2.0-2.5 mM Mn(2+) supports T7 RNA polymerase-mediated insertion of 8-N(3)AMP into RNA, a mixture of 2.5 mM Mn(2+) and 2.5 mM Mg(2+) further improves the yield of 8-N(3)AMP-containing transcript. In addition, both RNA transcription and reverse transcription proceed with high fidelity for the incorporation of 8-N(3)AMP and complementary residue, respectively. Finally, we show that a high-affinity MS2 coat protein binding sequence, in which adenosine residues were replaced by 8-azidoadenosine, crosslinks to the coat protein of the Escherichia coli phage MS2.

Translocation after synthesis of a four-nucleotide RNA commits RNA polymerase II to promoter escape

Transcription is a complex process, the regulation of which is crucial for cellular and organismic growth and development. Deciphering the molecular mechanisms that define transcription is essential to understanding the regulation of RNA synthesis. Here we describe the molecular mechanism of escape commitment, a critical step in early RNA polymerase II transcription. During escape commitment ternary transcribing complexes become stable and committed to proceeding forward through promoter escape and the remainder of the transcription reaction. We found that the point in the transcription reaction at which escape commitment occurs depends on the length of the transcript RNA (4 nucleotides [nt]) as opposed to the position of the active site of the polymerase with respect to promoter DNA elements. We found that single-stranded nucleic acids can inhibit escape commitment, and we identified oligonucleotides that are potent inhibitors of this specific step. These inhibitors bind RNA polymerase II with low nanomolar affinity and sequence specificity, and they block both promoter-dependent and promoter-independent transcription, the latter occurring in the absence of general transcription factors. We demonstrate that escape commitment involves translocation of the RNA polymerase II active site between synthesis of the third and fourth phosphodiester bonds. We propose that a conformational change in ternary transcription complexes occurs during translocation after synthesis of a 4-nt RNA to render complexes escape committed.

Two novel dATP analogs for DNA photoaffinity labeling

Two new photoreactive dATP analogs, N(6)-[4-azidobenzoyl-(2-aminoethyl)]-2'-deoxyadenosine-5'-triphospha+ ++ te (AB-dATP) and N(6)-[4-[3-(trifluoromethyl)-diazirin-3-yl]benzoyl-(2-aminoethyl) ]-2 '-deoxyadenosine-5'-triphosphate (DB-dATP), were synthesized from 2'-deoxyadenosine-5'-monophosphate in a six step procedure. Synthesis starts with aminoethylation of dAMP and continues with rearrangement of N(1)-(2-aminoethyl)-2'-deoxyadenosine-5'-monophosphate to N(6)-(2-aminoethyl)-2'-deoxyadenosine-5'-monophosphate (N(6)-dAMP). Next, N(6)-dAMP is converted into the triphosphate form by first protecting the N-6 primary amino group before coupling the pyrophosphate. After pyrophosphorylation, the material is deprotected to yield N(6)-(2-aminoethyl)-2'-deoxyadenosine-5'-triphosphate (N(6)-dATP). The N-6 amino group is subsequently used to attach either a phenylazide or phenyldiazirine and the photoreactive nucleotide is then enzymatically incorporated into DNA. N(6)-dATP and its photoreactive analogs AB-dATP and DB-dATP were successfully incorporated into DNA using the exonuclease-free Klenow fragment of DNA polymerase I in a primer extension reaction. UV irradiation of the primer extension reaction with AB-dATP or DB-dATP showed specific photocrosslinking of DNA polymerase I to DNA.

RNA-protein crosslinking to AMP residues at internal positions in RNA with a new photocrosslinking ATP analog

A new photocrosslinking purine analog was synthesized and evaluated as a transcription substrate for Escherichia coli RNA polymerase. This analog, 8-[(4-azidophenacyl)thio]adenosine 5'-triphosphate (8-APAS-ATP) contains an aryl azide photocrosslinking group that is attached to the ATP base via a sulfur-linked arm on the 8 position of the purine ring. This position is not involved in the normal Watson-Crick base pairing needed for specific hybridization. Although 8-APAS-ATP could not replace ATP as a substrate for transcription initiation, once stable elongation complexes were formed, 8-APAS-AMP could be site-specifically incorporated into the RNA, and this transcript could be further elongated, placing the photoreactive analog at internal positions in the RNA. Irradiation of transcription elongation complexes in which the RNA contained the analog exclusively at the 3' end of an RNA 22mer, or a 23mer with the analog 1 nt from the 3' end, produced RNA crosslinks to the RNA polymerase subunits that form the RNA 3' end binding site (beta, beta'). Both 8-APAS-AMP and the related 8-azido-AMP were subjected to conformational modeling as nucleoside monophosphates and in DNA-RNA hybrids. Surprisingly, the lowest energy conformation for 8-APAS-AMP was found to be syn, while that of 8-azido-AMP was anti, suggesting that the conformational properties and transcription substrate properties of 8-azido-ATP should be re-evaluated. Although the azide and linker together are larger in 8-APAS-ATP than in 8-N(3)-ATP, the flexibility of the linker itself allows this analog to adopt several different energetically favorable conformations, making it a good substrate for the RNA polymerase.

Interactions of Escherichia coli sigma(70) within the transcription elongation complex

A functional transcription elongation complex can be formed without passing through a promoter by adding a complementary RNA primer and core Escherichia coli RNA polymerase in trans to an RNA-primed synthetic bubble-duplex DNA framework. This framework consists of a double-stranded DNA sequence with an internal noncomplementary DNA "bubble" containing a hybridized RNA primer. On addition of core polymerase and the requisite NTPs, the RNA primer is extended in a process that manifests most of the properties of in vitro transcription elongation. This synthetic elongation complex can also be assembled by using holo rather than core RNA polymerase, and in this study we examine the interactions and fate of the sigma(70) specificity subunit of the holopolymerase in the assembly process. We show that the addition of holopolymerase to the bubble-duplex construct triggers the dissociation of the sigma factor from some complexes, whereas in others the RNA oligomer is released into solution instead. These results are consistent with an allosteric competition between sigma(70) and the nascent RNA strand within the elongation complex and suggest that both cannot be bound to the core polymerase simultaneously. However, the dissociation of sigma(70) from the complex can also be stimulated by binding of the holopolymerase to the DNA bubble duplex in the absence of a hybridized RNA primer, suggesting that the binding of the core polymerase to the bubble-duplex construct also triggers a conformational change that additionally weakens the sigma-core interaction.

Nascent RNA in transcription complexes interacts with CspE, a small protein in E. coli implicated in chromatin condensation

Proteins in a partially fractionated Escherichia coli extract that interact with the nascent RNA in active transcription complexes from several promoters were detected using the photocrosslinking ribonucleotide analogs 5-(azidophenacyl)thio-UTP or 5-(azidophenacyl)thio-CTP as transcription substrates. Upon irradiation of ternary transcription complexes, several extract proteins were crosslinked to the RNA. Most notably, a small protein was crosslinked to the RNA in complexes on seven of nine templates tested. This protein was purified and sequenced and found to match a hypothetical protein, MsmC/CspE, recently shown to be involved in chromatin partitioning. CspE has 69% amino acid sequence identity with the major cold shock protein in E. coli, CspA, which has been shown to bind to a DNA sequence designated the Y box, with the sequence 5'-ATTGG. Of the nine templates tested, CspE was found to be most heavily crosslinked to RNA from the lambda PR' promoter, which is modified by the Q antiterminator protein. CspE was very heavily crosslinked to RNA only ten nucleotides long in initial ternary complexes on this promoter, but not to this same RNA after it had been released from the transcription complex. However, even when present from the start of transcription, CspE did not crosslink to the RNA 82 nucleotides long in elongation complexes from this same promoter. Despite the loss of interaction with the RNA after polymerase had left the promoter, CspE inhibited Q-mediated transcriptional antitermination from PR' in vitro almost 200 nucleotides downstream from the promoter, presumably by interaction with the Y box DNA upstream from PR', which overlaps with the binding site for the Q. A potential role for CspE and transcription in chromosome condensation and nucleoid structure is discussed.

Identification of the epitope for a highly cross-reactive monoclonal antibody on the major sigma factor of bacterial RNA polymerase

A highly cross-reactive monoclonal antibody (MAb), 2G10, was found to react in a conserved region of Escherichia coli RNA polymerase sigma70. The epitope was localized to amino acids 470 to 486, which included part of conserved region 3.1. The epitope for MAb 3D3, a MAb which maps close to the 2G10 epitope, was also determined.

Preparation of probe-modified RNA with 5-mercapto-UTP for analysis of protein-RNA interactions

We report a modified synthesis for 5-mercapto-UTP (5-SH-UTP) and its use for analysis of protein-RNA interactions utilizing Escherichia coli and T7 RNA polymerases and yeast RNA polymerases I and III. 5-SH-UTP did not affect transcriptional pausing, Rho-independent termination or recognition of the E. coli transcription complex by NusA. RNA containing 5-SH-UMP did not crosslink to polymerase when irradiation was 302 or 337 nm. Transcription complexes containing RNA substituted with 5-SH-UMP were post-transcriptionally modified to attach a photocross-linking group to thiol-tagged nucleotides in the RNA on the surface of the polymerase of free in solution. The pKa for 5-SH-UTP was determined to be 5.6, so modification of the thiol groups in the RNA with p-azidophenacyl bromide could be carried out at pH 7. Addition of the transcription termination factor Rho, a RNA binding protein, to E. coli transcription complexes resulted in RNA crosslinking to Rho and to the beta and beta' subunits of polymerase. Using 5-SH-UTP, one can distinguish RNA binding domains on the surface of RNA polymerases or other RNA binding proteins from those buried within the protein.

Mapping of the active site of T7 RNA polymerase with 8-azidoATP

The photoaffinity analog of ATP, 8-azidoATP, labels T7 RNA polymerase. Photoincorporation exhibits saturation behavior and is protected against by the substrate ATP. 8-AzidoATP is a competitive inhibitor of ATP incorporation with Ki approximately 40 microM. The photolabeled T7 RNA polymerase, following cyanogen bromide digestion, was analyzed by phenylboronate agarose column chromatography followed by reverse-phase high pressure liquid chromatography. Sequencing of the peptides labeled with radioactive photoprobe allowed the identification of three peptides, P314-M362 (I), L550-M666 (II), and F751-M861 (III). These peptides are in the proximity of the photoprobe 8-azidoATP and, therefore, expected to contain functionally significant residues and define an active site domain. These peptides (I and II) contain residues previously implicated in T7 RNA polymerase activity or show homology to active site regions of the Klenow fragment of DNA polymerase I (II and III).

RNA-protein interactions in a Nus A-containing Escherichia coli transcription complex paused at an RNA hairpin

We have isolated Escherichia coli transcription complexes, paused in the presence and absence of Nus A, which contain RNA substituted at every UMP residue with a photocrosslinking nucleotide analog. The pause site is immediately downstream from an RNA stem-loop structure, and although pausing occurs in the absence of Nus A, it is substantially enhanced in the presence of Nus A. We have analyzed the secondary structure of this RNA and show that the analog does not interfere with the formation of the normal stem-loop structures. Additionally, the analog substrate does not alter transcriptional pausing, in the presence or absence of Nus A, indicating that Nus A recognition of the transcription complex is not affected by the presence of the crosslinking groups in the RNA. Ribonuclease digestion of the RNA in paused complexes identifies two accessible regions, two nucleotides in the loop and one near the base of the upstream side of the stem-loop. Cleavage at one loop nucleotide is enhanced by Nus A, while the nucleotide near the base of the stem-loop is partially protected. Upon irradiation of the transcription complex, Nus A is not photoaffinity labeled by the RNA, even at a high molar ration to RNA polymerase (250:1). Both the beta and beta' subunits are labeled, however, indicating that the putative stem-loop binding domain on the core polymerase involves both subunits. Because the nucleotide protected from ribonuclease by Nus A is very near two analogs, yet Nus A is not crosslinked to the RNA, it is unlikely that Nus A could be protecting this position through direct contact. Furthermore, analog is substituted at positions in both the loop and at several positions in the stem, and again, no crosslinking to Nus A is observed. We conclude that enhancement of pausing by Nus A probably does not require direct interaction with the bases in the RNA stem-loop.