Increased accommodation of nascent RNA in a product site on RNA polymerase II during arrest

The RNA-DNA hybrid maintains the register of transcription by preventing backtracking of RNA polymerase

An 8-9 bp RNA-DNA hybrid in the transcription elongation complex is essential for keeping the RNA 3' terminus engaged with the active site of E. coli RNA polymerase (RNAP). Destabilization of the hybrid leads to detachment of the transcript terminus, RNAP backtracking, and shifting of the hybrid upstream. Eventually, the exposed 3' segment of RNA can be removed through transcript cleavage. At certain sites, cycles of unwinding-rewinding of the hybrid are coupled to reverse-forward sliding of the transcription elongation complex. This explains apparent discontinuous elongation, which was previously interpreted as contraction and expansion of an RNAP molecule (inch-worming). Thus, the 3'-proximal RNA-DNA hybrid plays the dual role of keeping the active site in register with the template and sensing the helix-destabilizing mismatches in RNA, launching correction through backtracking and cleavage.

Mechanism and regulation of transcriptional elongation and termination by RNA polymerase II

Over the past year, key advances in several areas of research on the structure and function of the RNA polymerase (pol II) elongation complex have shed considerable light on the mechanisms governing the elongation stage of eukaryotic mRNA synthesis. Novel features of the regulation of elongation by DNA and RNA binding transcriptional activators have been brought to light; the mechanisms of action of elongation factors that suppress pausing and premature arrest by transcribing pol II have been defined in greater detail; and novel elongation factors implicated in human disease have been identified and characterized.

Transcriptional arrest: Escherichia coli RNA polymerase translocates backward, leaving the 3' end of the RNA intact and extruded

RNA polymerase (RNAP) may become arrested during transcript elongation when ternary complexes remain intact but further RNA synthesis is blocked. Using a combination of DNA and RNA footprinting techniques, we demonstrate that the loss of catalytic activity upon arrest of Escherichia coli RNAP is accompanied by an isomerization of the ternary complex in which the enzyme disengages from the 3' end of the transcript and moves backward along the DNA with concomitant reverse threading of the intact RNA through the enzyme. The reversal of RNAP brings the active center to the internal RNA position and thereby it represents a step in factor-facilitated transcript cleavage. Secondary structure elements or the 5' end of the transcript can prevent the isomerization by blocking the RNA threading. The described novel property of RNAP has far-reaching implications for the understanding of the elongation mechanism and gene regulation.

Interplay of two uridylate-specific RNA binding sites in the translocation of poly(A) polymerase from vaccinia virus

The VP55 (catalytic) subunit of vaccinia virus heterodimeric poly(A) polymerase (PAP) contacts 31-40 nucleotide segments of RNA in a uridylate-dependent manner, and effects the rapid, processive addition of a 30 nt oligo(A) tail. Here, the minimum size of uridylate-containing RNA required for stable VP55 interaction was refined to 33-34 nt. VP55 binding experiments using a set of sixteen 34 nt DNA-RNA chimeras, each containing a differently positioned tetra-uridylate cluster within an oligo(dC) background, indicated that the protein contacts uridylates at two positions within the oligonucleotide. Combination of two optimally positioned tetra-uridylate clusters into a single oligonucleotide fully restored the properties of an optimal substrate, rU34, in VP55 binding and salt-resistant polyadenylylation. The positions of the two uridylate interaction sites, approximately 10 and approximately 25 nt from the oligonucleotide 3' OH, were confirmed using a selection scheme employing dC-rU oligonucleotide chimera pools. These and additional data suggest a mechanism for polymerase translocation with respect to RNA comparable with inchworming models of transcriptional elongation. In selection experiments incorporating the PAP-associated processivity factor VP39, the latter was shown to replace the 3' OH-distal uridylate contact site with one approximately 10 nt further upstream.

Nuclease cleavage of the upstream half of the nontemplate strand DNA in an Escherichia coli transcription elongation complex causes upstream translocation and transcriptional arrest

We tested the susceptibility of nucleic acid strands in a halted transcription elongation complex to digestion by micrococcal nuclease (MN). The 16-nucleotide nascent RNA was protected within RNA polymerase. A 27-28-nucleotide template strand DNA fragment also was resistant to MN digestion. However, the upstream half of the nontemplate DNA within this region was digested rapidly by MN, suggesting that the nontemplate strand emerges from the RNA polymerase near the middle of the melted transcription bubble with the bases oriented away from the enzyme surface. MN cleavage of the exposed nontemplate DNA shifted polymerase backward, making it unable to extend the RNA chain. However, the MN-trimmed G16 complexes could be reactivated by GreB-stimulated cleavage of the nascent RNA. These results favor a model of transcriptional arrest involving upstream slippage of RNA polymerase along the RNA and DNA chains. They also suggest that the exposed segment of nontemplate DNA may directly or indirectly stabilize the lateral position of the transcription complex along the DNA.

Promoter proximal sequences modulate RNA polymerase II elongation by a novel mechanism

The adenovirus major late arrest site blocks transcription by mammalian RNA polymerase II in vitro downstream of the major late promoter but not the mouse beta-globin promoter. We localized the sequences responsible for anti-arrest to the 5' end of the beta-globin transcript and demonstrated that anti-arrest required that this region of RNA form base pairs with the nascent transcript upstream of the arrest site. Small antisense RNA or DNA oligonucleotides hybridizing upstream of the arrest site also prevented arrest when added in trans. Our results suggest that arrest is accompanied by retraction of the nascent transcript into the interior of the polymerase and that hybridization of the transcript prevents this movement, thereby allowing the polymerase to continue elongation.

Elongation factor SII contacts the 3'-end of RNA in the RNA polymerase II elongation complex

Elongation factor SII (also known as TFIIS) is an RNA polymerase II binding protein that allows bypass of template arrest sites by activating a nascent RNA cleavage reaction. Here we show that SII contacts the 3'-end of nascent RNA within an RNA polymerase II elongation complex as detected by photoaffinity labeling. Photocross-linking was dependent upon the presence of SII, incorporation of 4-thio-UMP into RNA, and irradiation and was sensitive to treatment by RNase and proteinase. A transcriptionally active mutant of SII lacking the first 130 amino acids was also cross-linked to the nascent RNA, but SII from Saccharomyces cerevisiae, which is inactive in concert with mammalian RNA polymerase II, failed to become photoaffinity labeled. SII-RNA contact was not detected after a labeled oligoribonucleotide was released from the complex by nascent RNA cleavage, demonstrating that this interaction takes place between elongation complex-associated but not free RNA. This shows that the 3'-end of RNA is near the SII binding site on RNA polymerase II and suggests that SII may activate the intrinsic RNA hydrolysis activity by positioning the transcript in the enzyme's active site.