The Specificity Loop of T7 RNA Polymerase Interacts First with the Promoter and Then with the Elongating Transcript, Suggesting a Mechanism for Promoter Clearance
During the early stages of transcription, T7 RNA polymerase forms an unstable initiation complex that synthesizes and releases transcripts 2-8 nt in length before disengaging from the promoter and isomerizing to a stable elongation complex. In this study, we used RNA·protein and RNA·DNA crosslinking...
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| Veröffentlicht in: | Proceedings of the National Academy of Sciences - PNAS 2000-12, Vol.97 (26), p.14109-14114 |
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| container_title | Proceedings of the National Academy of Sciences - PNAS |
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| creator | Temiakov, D Mentesana, P E Ma, K Mustaev, A Borukhov, S McAllister, W T |
| description | During the early stages of transcription, T7 RNA polymerase forms an unstable initiation complex that synthesizes and releases transcripts 2-8 nt in length before disengaging from the promoter and isomerizing to a stable elongation complex. In this study, we used RNA·protein and RNA·DNA crosslinking methods to probe the location of newly synthesized RNA in halted elongation complexes. The results indicate that the RNA in an elongation complex remains in an RNA·DNA hybrid for about 8 nt from the site of nucleotide addition and emerges to the surface of the enzyme about 12 nt from the addition site. Strikingly, as the transcript leaves its hybrid with the template, the crosslinks it forms with the RNA polymerase involve a portion of a hairpin loop (the specificity loop) that makes specific contacts with the binding region of the promoter during initiation. This observation suggests that the specificity loop may have a dual role in transcription, binding first to the promoter and subsequently interacting with the RNA product. It seems likely that association of the nascent RNA with the specificity loop facilitates disengagement from the promoter and is an important part of the process that leads to a stable elongation complex. |
| doi_str_mv | 10.1073/pnas.250473197 |
| format | Article |
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In this study, we used RNA·protein and RNA·DNA crosslinking methods to probe the location of newly synthesized RNA in halted elongation complexes. The results indicate that the RNA in an elongation complex remains in an RNA·DNA hybrid for about 8 nt from the site of nucleotide addition and emerges to the surface of the enzyme about 12 nt from the addition site. Strikingly, as the transcript leaves its hybrid with the template, the crosslinks it forms with the RNA polymerase involve a portion of a hairpin loop (the specificity loop) that makes specific contacts with the binding region of the promoter during initiation. This observation suggests that the specificity loop may have a dual role in transcription, binding first to the promoter and subsequently interacting with the RNA product. 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In this study, we used RNA·protein and RNA·DNA crosslinking methods to probe the location of newly synthesized RNA in halted elongation complexes. The results indicate that the RNA in an elongation complex remains in an RNA·DNA hybrid for about 8 nt from the site of nucleotide addition and emerges to the surface of the enzyme about 12 nt from the addition site. Strikingly, as the transcript leaves its hybrid with the template, the crosslinks it forms with the RNA polymerase involve a portion of a hairpin loop (the specificity loop) that makes specific contacts with the binding region of the promoter during initiation. This observation suggests that the specificity loop may have a dual role in transcription, binding first to the promoter and subsequently interacting with the RNA product. 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| ispartof | Proceedings of the National Academy of Sciences - PNAS, 2000-12, Vol.97 (26), p.14109-14114 |
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| subjects | Active sites Bacteriophage T7 - enzymology Binding Sites Biochemistry Biological Sciences Cross-Linking Reagents Crosslinking Deoxyribonucleic acid DNA DNA-Directed RNA Polymerases - chemistry DNA-Directed RNA Polymerases - metabolism Enzymes Gels Hybridity Models, Molecular Nucleotides Phage T7 Product labeling Promoter Regions, Genetic Proteins Ribonucleic acid RNA Transcription, Genetic Viral Proteins |
| title | The Specificity Loop of T7 RNA Polymerase Interacts First with the Promoter and Then with the Elongating Transcript, Suggesting a Mechanism for Promoter Clearance |
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