Structural changes in the RNA polymerase II transcription complex during transition from initiation to elongation.

We obtained exonuclease III (exoIII) footprints for a series of RNA polymerase II transcription complexes stalled between positions +20 to +51. Downstream advance of the exoIII footprint is normally tightly coordinated with RNA synthesis. However, arrested RNA polymerases slide back along the template, as indicated by exoIII footprints in which the last transcribed base is abnormally close to the downstream edge of the footprint. None of the polymerase II complexes stalled between +20 and +51 were arrested. Nevertheless, the exoIII footprints of complexes with 20-, 23-, or 25-nucleotide RNAs resembled those of arrested complexes, with the last transcribed base very close to the footprint's front edge. The exoIII footprint of the +27 complex was displaced downstream by 17 bp compared to the footprint of the +25 complex. Many complexes between +27 and +42 also showed evidence of sliding back along the template. We compared the effects of template sequence and transcript length by constructing a new template in which the initial transcribed sequence was duplicated beginning at +98. The exoIII footprints of transcription complexes stalled between +122 to +130 on this DNA did not resemble those of arrested complexes, in contrast to the footprints of analogous complexes stalled over the same DNA sequences early in transcription. Our results indicate that the RNA polymerase II transcription complex passes through a major, sequence-independent structural transition about 25 bases downstream of the starting point of transcription. The fully mature form of the elongation complex may not appear until more than 40 bonds have been made.

Translocation and transcriptional arrest during transcript elongation by RNA polymerase II.

RNA polymerase II may stop transcription, or arrest, while transcribing certain DNA sequences. The molecular basis for arrest is not well understood, but a connection has been suggested between arrest and a transient failure of the polymerase to translocate along the template. We have investigated this question by monitoring the movement of RNA polymerase II along a number of templates, using exonuclease III protection as our assay. We found that normal transcription is accompanied by essentially coordinate movement of the active site and both the leading and trailing edges of the polymerase. However, as polymerase approaches an arrest site, translocation of the body of the polymerase stops while transcription continues, leading to an arrested complex in which the 3' end of the transcript is located much closer than normal to the front edge of the polymerase. Surprisingly, mutated arrest sites that no longer block transcription continue to direct the transient failure of polymerase translocation. As transcription proceeds through these sequences, the initially stationary polymerase moves forward 10-15 bases along the template in response to the addition of only 3 bases to the nascent RNA. Mutagenesis studies indicate that the sequences responsible for the transient block to polymerase movement are located downstream of the T-rich motif required for arrest. Our results indicate that blocking translocation is not sufficient to cause arrest.

RNA polymerase II ternary complexes may become arrested after transcribing to within 10 bases of the end of linear templates.

In the presence of elongation factor SII, arrested RNA polymerase II ternary complexes cleave 7-17 nucleotides from the 3'-ends of their nascent RNAs. It has been shown that transcription of linear templates generates apparent run-off RNAs, which are nevertheless truncated upon incubation with SII. By using high resolution gels, we demonstrate that transcription of blunt or 3'-overhung templates with RNA polymerase II generates two populations of ternary complexes. The first class pauses 5-10 bases prior to the end of the template strand. These complexes respond to SII by cleaving approximately 9-17 nucleotide RNAs from their 3'-ends and therefore may be termed arrested. A second class of complexes, which fail to respond to SII, transcribe to within 3 bases of the end of the template strand. These complexes appear to have run off the template since they have released their nascent RNAs. Run-off transcription occurs on all types of templates, but it is the predominant reaction on DNAs with 5'-overhung ends. Thus, RNA polymerase II ternary complexes that retain 5-10 bases of contact with the template strand down-stream of the catalytic site become arrested. Further reduction of downstream template contacts can lead to termination. We also show that the addition of Sarkosyl to the elongation reactions significantly changes the pattern of transcriptional arrest near the end of linear templates.