Purified RNA polymerase II recognizes specific termination sites during transcription in vitro

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Purified RNA polymerase II recognizes specific termination sites during transcription in vitro

RL Dedrick, CM Kane and MJ Chamberlin

We have studied the ability of certain well-defined prokaryotic DNA sequences to act as specific termination signals for highly purified calf thymus RNA polymerase II. We used duplex DNA fragments modified to direct efficient and specific transcription of defined DNA templates to follow transcription with RNA polymerase alone in the absence of additional protein factors. Elongation of RNA chains by RNA polymerase II is processive through most DNA sequences. However, certain DNA sequences serve as effective "intrinsic" terminators for RNA polymerase II; in this they resemble the "rho-independent" terminators for the bacterial RNA polymerase. Several rho-independent bacterial terminators are also able to act as termination signals for RNA polymerase II. However, there is no apparent correlation between the efficiency of termination for the bacterial enzyme and that found for the calf thymus enzyme. One very efficient bacterial terminator (phage T7 early terminator) gives no termination with RNA polymerase II, and we have identified at least two sites that cause the eukaryotic enzyme to terminate but have no effect on transcription by the bacterial enzyme. Hence, the signals recognized as intrinsic termination sites for the two enzymes are substantially different. All of the sites that act as intrinsic terminators for RNA polymerase II contain a series of consecutive thymidine residues in the nontranscribed DNA strand (T- run), and the 3' end of the completed RNA normally lies within this sequence. It is plausible that the T-run is part of the signal for an RNA polymerase II termination site; however, there is no apparent correlation between the number of T residues and the efficiency of the terminator, suggesting that other sequence elements are required for, or modulate, termination. Several lines of evidence suggest that the formation of RNA secondary structures in the nascent transcript is not an essential element of the intrinsic RNA polymerase II termination signal.
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				I. Artsimovitch and R. Landick Pausing by bacterial RNA polymerase is mediated by mechanistically distinct classes of signals PNAS, June 20, 2000; 97(13): 7090 - 7095. [Abstract] [Full Text] [PDF]

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				M. D. Rudd and D. S. Luse Amanitin Greatly Reduces the Rate of Transcription by RNA Polymerase II Ternary Complexes but Fails to Inhibit Some Transcript Cleavage Modes J. Biol. Chem., August 30, 1996; 271(35): 21549 - 21558. [Abstract] [Full Text] [PDF]

				W. Powell and D. Reines Mutations in the Second Largest Subunit of RNA Polymerase II Cause 6-Azauracil Sensitivity in Yeast and Increased Transcriptional Arrest in Vitro J. Biol. Chem., March 22, 1996; 271(12): 6866 - 6873. [Abstract] [Full Text] [PDF]

				J. McDowell, J. Roberts, D. Jin, and C Gross Determination of intrinsic transcription termination efficiency by RNA polymerase elongation rate Science, November 4, 1994; 266(5186): 822 - 825. [Abstract] [PDF]

				S Roberts, T Purton, and D L Bentley A protein-binding site in the c-myc promoter functions as a terminator of RNA polymerase II transcription. Genes & Dev., August 1, 1992; 6(8): 1562 - 1574. [Abstract] [PDF]

				R Landick, J Stewart, and D N Lee Amino acid changes in conserved regions of the beta-subunit of Escherichia coli RNA polymerase alter transcription pausing and termination. Genes & Dev., September 1, 1990; 4(9): 1623 - 1636. [Abstract] [PDF]

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