How DNA breaks in the transcribed strand alter start site selection by pol III. (A) View of the transcribed strand taken from the structure of the pol.

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How DNA breaks in the transcribed strand alter start site selection by pol III. (A) View of the transcribed strand taken from the structure of the pol II elongation complex (Gnatt et al., 2001). How DNA breaks in the transcribed strand alter start site selection by pol III. (A) View of the transcribed strand taken from the structure of the pol II elongation complex (Gnatt et al., 2001). The transcribed strand is in red (phosphate in black) from nt −9 to +4 [pyrimidine at +1 specifying the incoming ribonucleotide (yellow) across the catalytic site Mg2+ (magenta)]. Atoms of pol II subunits RpbA (green) and RpbB (blue) that come within 3.5 Å of any atom of the transcribed DNA strand are also shown. (B) Diagram of the TFIIIB–pol III open complex incorporating features shown in (A). TFIIIB (red octagon) anchors pol III (light grey circle) preventing backward and limiting forward translocation in the absence of RNA synthesis. Thick lines representing DNA within the pol III open complex are divided into colored segments to indicate complementarity and position relative to the normal start site of transcription (+1; yellow circle). The transcribed strand is constrained in the complex by non‐specific interaction with C128 (light blue) and C160 (light green), compacting an additional 4–5 bp of DNA into the structure to align nt +1 with the catalytic center [initiating ribonucleotide and Mg2+ color coded as in (A)]. The non‐transcribed strand is not significantly constrained in the complex. The open complex may be in equilibrium with closed or partially closed states. Partial closure of the open complex (C) extrudes downstream duplex DNA, since stable TFIIIB–DNA and TFIIIB–pol III interactions prevent extrusion upstream. Partial closure at the downstream or upstream edge of the bubble (the latter may also necessitate downstream edge closure) pulls the transcribed strand away from the catalytic site, preventing initiation. The transcribed strand is therefore the conduit through which TFIIIB placement specifies the transcriptional start site. Breaks in the transcribed strand within the segment that is melted in the open complex (D) remove the constraint imposed by the continuity of the transcribed strand, allowing both extrusion of downstream DNA and alignment of the transcribed strand with the catalytic site. Anne Grove et al. EMBO J. 2002;21:704-714 © as stated in the article, figure or figure legend