Purification of synchronized E. coli transcription elongation complexes by reversible immobilization on magnetic beads

Synchronized transcription elongation complexes (TECs) are a fundamental tool for in vitro studies of transcription and RNA folding. Transcription elongation can be synchronized by omitting one or more NTPs from an in vitro transcription reaction so that RNA polymerase can only transcribe to the first occurrence of the omitted nucleotide(s) in the coding DNA strand. This approach was developed over four decades ago and has been applied extensively in biochemical investigations of RNA polymerase enzymes, but has not been optimized for RNA-centric assays. In this work, we describe the development of a system for isolating synchronized TECs from an in vitro transcription reaction. Our approach uses a custom 5′ leader sequence, called C3-SC1, to reversibly capture synchronized TECs on magnetic beads. We first show that complexes isolated by this procedure, called C3-SC1TECs, are >95% pure, >98% active, highly synchronous (94% of complexes chase in <15s upon addition of saturating NTPs), and compatible with solid-phase transcription; the yield of this purification is ~8%. We then show that C3-SC1TECs perturb, but do not interfere with, the function of ZTP-sensing and ppGpp-sensing transcriptional riboswitches. For both riboswitches, transcription using C3-SC1TECs improved the efficiency of transcription termination in the absence of ligand but did not inhibit ligand-induced transcription antitermination. Given these properties, C3-SC1TECs will likely be useful for developing biochemical and biophysical RNA assays that require high-performance, quantitative bacterial in vitro transcription.

Characterizing the Interaction between the HTLV-1 Transactivator Tax-1 with Transcription Elongation Factor ELL2 and Its Impact on Viral Transactivation

The human T-cell leukemia virus type 1 (HTLV-1)-encoded transactivator and oncoprotein Tax-1 is essential for HTLV-1 replication. We recently found that Tax-1 interacts with transcription elongation factor for RNA polymerase II 2, ELL2, which enhances Tax-1-mediated transactivation of the HTLV-1 promotor. Here, we characterize the Tax-1:ELL2 interaction and its impact on viral transactivation by confocal imaging, co-immunoprecipitation, and luciferase assays. We found that Tax-1 and ELL2 not only co-precipitate, but also co-localize in dot-like structures in the nucleus. Tax-1:ELL2 complex formation occurred independently of Tax-1 point mutations, which are crucial for post translational modifications (PTMs) of Tax-1, suggesting that these PTMs are irrelevant for Tax-1:ELL2 interaction. In contrast, Tax-1 deletion mutants lacking either N-terminal (aa 1–37) or C-terminal regions (aa 150–353) of Tax-1 were impaired in interacting with ELL2. Contrary to Tax-1, the related, non-oncogenic Tax-2B from HTLV-2B did not interact with ELL2. Finally, we found that ELL2-R1 (aa 1–353), which carries an RNA polymerase II binding domain, and ELL2-R3 (aa 515–640) are sufficient to interact with Tax-1; however, only ELL2-truncations expressing R1 could enhance Tax-1-mediated transactivation of the HTLV-1 promoter. Together, this study identifies domains in Tax-1 and ELL2 being required for Tax-1:ELL2 complex formation and for viral transactivation.

Defining the Influence of the A12.2 Subunit on Transcription Elongation and Termination by RNA Polymerase I In Vivo

Saccharomyces cerevisiae has approximately 200 copies of the 35S rDNA gene, arranged tandemly on chromosome XII. This gene is transcribed by RNA polymerase I (Pol I) and the 35S rRNA transcript is processed to produce three of the four rRNAs required for ribosome biogenesis. An intergenic spacer (IGS) separates each copy of the 35S gene and contains the 5S rDNA gene, the origin of DNA replication, and the promoter for the adjacent 35S gene. Pol I is a 14-subunit enzyme responsible for the majority of rRNA synthesis, thereby sustaining normal cellular function and growth. The A12.2 subunit of Pol I plays a crucial role in cleavage, termination, and nucleotide addition during transcription. Deletion of this subunit causes alteration of nucleotide addition kinetics and read-through of transcription termination sites. To interrogate both of these phenomena, we performed native elongating transcript sequencing (NET-seq) with an rpa12Δ strain of S. cerevisiae and evaluated the resultant change in Pol I occupancy across the 35S gene and the IGS. Compared to wild-type (WT), we observed template sequence-specific changes in Pol I occupancy throughout the 35S gene. We also observed rpa12Δ Pol I occupancy downstream of both termination sites and throughout most of the IGS, including the 5S gene. Relative occupancy of rpa12Δ Pol I increased upstream of the promoter-proximal Reb1 binding site and dropped significantly downstream, implicating this site as a third terminator for Pol I transcription. Collectively, these high-resolution results indicate that the A12.2 subunit of Pol I plays an important role in transcription elongation and termination.

EKLF/Klf1 Regulates Erythroid Transcription By Its Pioneering Activity and Subsequent Control of RNA Pol II Pause-Release

EKLF/Klf1 is a master transcriptional activator of critical genes that regulate both erythroid fate specification and terminal erythroid maturation. EKLF binds to DNA using three Zn-fingers at its C-terminus while the N-terminus constitutes a transcription activation domain (TAD) that interacts with various transcription co-factors including the protein acetylase CBP. An autosomal semi-dominant mutation at a single residue (E339D) in the mouse EKLF Zn-finger leads to Neonatal anemia (Nan). A mutation at the same residue in human EKLF (E325K) causes Congenital Dyserythropoietic Anemia type IV (CDA IV). Nan/Nan mice show lethality at embryonic day E10-11, in contrast to EKLF-/- homozygotes that survive until E15. Nan/+ heterozygotes survive to adulthood but are severely anemic, unlike EKLF+/- heterozygotes that display no aberrant phenotypes. The Nan-EKLF protein has an altered DNA binding specificity leading to a vastly altered transcriptome by two mechanisms. First, Nan-EKLF binding causes ectopic gene expression that significantly contributes to the severe anemia in Nan/+. Second, a subset of EKLF targets is downregulated in heterozygous Nan/+ mutants despite the presence of one copy of wild type EKLF, exacerbating the anemia. Thus, uncovering the mechanism by which gene expression is altered in Nan/+ may illuminate how EKLF normally activates transcription of its targets in vivo. To this end, we first examined the global occupancy of RNA Pol II phospho-Ser5 (as a paused mark) and phospho-Ser2 (as an elongation mark) in the mouse E13.5 fetal liver as a source of primary definitive erythroid cells. At promoters of ectopically expressed genes, where only Nan-EKLF (but not WT) binding is expected, we predominantly find increased levels of both paused and elongating RNA Pol II suggesting that Nan-EKLF binding activates transcription at ectopic genes by RNA Pol II recruitment and promoter proximal pausing. Further, we find increased levels of H3K27ac and CBP occupancy at these sites indicating that the mechanism of Pol II recruitment relies on CBP-mediated H3K27 acetylation and increased chromatin accessibility. Overall, this suggests robust pioneering activity of Nan-EKLF likely mediated by the interaction of its TAD with the CBP/p300 acetylase complex. At genes downregulated in Nan/+ we find two major patterns of Pol II occupancy. One is the converse of that seen at ectopic genes wherein there is a concomitant decrease in both Pol II p-Ser5 and p-Ser2 levels, along with lower H3K27ac and CBP levels suggesting EKLF gene activation has been lost at these sites in Nan/+. This includes cell cycle EKLF targets such as E2f2 and Rgcc. The second set of genes have comparable levels of p-Ser5 (paused) Pol II in Nan/+ and WT, but lower levels of p-Ser2 (elongating) Pol II in Nan/+. This suggests that although Pol II is being recruited to the TSS and pauses effectively, the pause-release step leading to effective transcription elongation is impaired. This subset includes important EKLF targets such as Bcl11a, Pax7, Xpo7, and several membrane transporters. As expected, CBP and H3K27ac levels are similar in WT and Nan/+ at these sites. To determine the cause of impaired RNA Pol II pause-release we examined the global occupancies of key transcription elongation factors such as P-TEFb and NELF. We find that levels of NELF, a negative elongation factor, remain unchanged in WT and Nan/+. However, levels of the P-TEFb subunit Cdk9, a positive elongation factor that facilitates release of paused RNA Pol II, is significantly lower at the TSS of these genes in Nan/+. This suggests that in Nan/+, possible reduction or loss of EKLF binding at some EKLF target promoters impairs effective recruitment of positive transcription elongation factors, resulting in a failure to efficiently release paused RNA Pol II. This causes downregulation of these EKLF target genes and contributes to the severe anemic phenotypes of the Nan mouse. We conclude that: EKLF exhibits expression control of its target genes at both the transcriptional initiation and elongation steps in vivo; EKLF can act as a pioneer transcription factor and increase chromatin accessibility through H3K27 acetylation by CBP leading to recruitment and pausing of RNA Pol II; and EKLF recruits the positive transcription elongation complex P-TEFb, enabling the controlled release of paused RNA Pol II at transcription start sites of a select group of its targets. Disclosures No relevant conflicts of interest to declare.