Mechanism of RNA polymerase II bypass of oxidative cyclopurine DNA lesions.

In human cells, the oxidative DNA lesion 8,5'-cyclo-2'-deoxyadenosine (CydA) induces prolonged stalling of RNA polymerase II (Pol II) followed by transcriptional bypass, generating both error-free and mutant transcripts with AMP misincorporated immediately downstream from the lesion. Here, we present biochemical and crystallographic evidence for the mechanism of CydA recognition. Pol II stalling results from impaired loading of the template base (5') next to CydA into the active site, leading to preferential AMP misincorporation. Such predominant AMP insertion, which also occurs at an abasic site, is unaffected by the identity of the 5'-templating base, indicating that it derives from nontemplated synthesis according to an A rule known for DNA polymerases and recently identified for Pol II bypass of pyrimidine dimers. Subsequent to AMP misincorporation, Pol II encounters a major translocation block that is slowly overcome. Thus, the translocation block combined with the poor extension of the dA.rA mispair reduce transcriptional mutagenesis. Moreover, increasing the active-site flexibility by mutation in the trigger loop, which increases the ability of Pol II to accommodate the bulky lesion, and addition of transacting factor TFIIF facilitate CydA bypass. Thus, blocking lesion entry to the active site, translesion A rule synthesis, and translocation block are common features of transcription across different bulky DNA lesions.

Oncogene PKCε controls INrf2-Nrf2 interaction in normal and cancer cells through phosphorylation of INrf2.

The INrf2 (Keap1)-Nrf2 cell sensor complex has a crucial role in protection against chemical- and radiation-induced oxidative stress and cellular transformation. INrf2, in association with Cul3-Rbx1, ubiquitylates and degrades Nrf2. Exposure to stressors leads to stabilization of Nrf2 and the coordinated activation of cytoprotective proteins and cellular protection. However, the molecular signal(s) that regulate control of Nrf2 by INrf2 remain elusive. In this report, we demonstrate that phosphorylation of INrf2 at Ser599 and Ser602 by the oncoprotein PKCε is essential for INrf2-Nrf2 interaction, and the subsequent ubiquitylation and degradation of Nrf2. Inhibition of PKCε, knockdown of PKCε and the INrf2S602A mutant all failed to phosphorylate INrf2, leading to loss of the INrf2-Nrf2 interaction, Nrf2 degradation and enhanced cytoprotection and drug resistance. Molecular modeling analyses revealed that phosphorylation of S599 exposes the deeply buried S602 for phosphorylation and enhanced INrf2-Nrf2 interaction. Analysis of human lung and liver tumor protein arrays showed lower PKCε and higher Nrf2 levels, which presumably promoted cancer cell survival and drug resistance. In conclusion, phosphorylation of INrf2 by PKCε leads to regulation of Nrf2, with significant implications for the survival of cancer cells, which often express lower levels of PKCε.

Sensitivity of mitochondrial transcription and resistance of RNA polymerase II dependent nuclear transcription to antiviral ribonucleosides.

Ribonucleoside analogues have potential utility as anti-viral, -parasitic, -bacterial and -cancer agents. However, their clinical applications have been limited by off target effects. Development of antiviral ribonucleosides for treatment of hepatitis C virus (HCV) infection has been hampered by appearance of toxicity during clinical trials that evaded detection during preclinical studies. It is well established that the human mitochondrial DNA polymerase is an off target for deoxyribonucleoside reverse transcriptase inhibitors. Here we test the hypothesis that triphosphorylated metabolites of therapeutic ribonucleoside analogues are substrates for cellular RNA polymerases. We have used ribonucleoside analogues with activity against HCV as model compounds for therapeutic ribonucleosides. We have included ribonucleoside analogues containing 2'-C-methyl, 4'-methyl and 4'-azido substituents that are non-obligate chain terminators of the HCV RNA polymerase. We show that all of the anti-HCV ribonucleoside analogues are substrates for human mitochondrial RNA polymerase (POLRMT) and eukaryotic core RNA polymerase II (Pol II) in vitro. Unexpectedly, analogues containing 2'-C-methyl, 4'-methyl and 4'-azido substituents were inhibitors of POLRMT and Pol II. Importantly, the proofreading activity of TFIIS was capable of excising these analogues from Pol II transcripts. Evaluation of transcription in cells confirmed sensitivity of POLRMT to antiviral ribonucleosides, while Pol II remained predominantly refractory. We introduce a parameter termed the mitovir (mitochondrial dysfunction caused by antiviral ribonucleoside) score that can be readily obtained during preclinical studies that quantifies the mitochondrial toxicity potential of compounds. We suggest the possibility that patients exhibiting adverse effects during clinical trials may be more susceptible to damage by nucleoside analogs because of defects in mitochondrial or nuclear transcription. The paradigm reported here should facilitate development of ribonucleosides with a lower potential for toxicity.

Regulation of mammalian transcription by Gdown1 through a novel steric crosstalk revealed by cryo-EM.

In mammals, a distinct RNA polymerase II form, RNAPII(G) contains a novel subunit Gdown1 (encoded by POLR2M), which represses gene activation, only to be reversed by the multisubunit Mediator co-activator. Here, we employed single-particle cryo-electron microscopy (cryo-EM) to disclose the architectures of RNAPII(G), RNAPII and RNAPII in complex with the transcription initiation factor TFIIF, all to ~19 Å. Difference analysis mapped Gdown1 mostly to the RNAPII Rpb5 shelf-Rpb1 jaw, supported by antibody labelling experiments. These structural features correlate with the moderate increase in the efficiency of RNA chain elongation by RNAP II(G). In addition, our updated RNAPII-TFIIF map showed that TFIIF tethers multiple regions surrounding the DNA-binding cleft, in agreement with cross-linking and biochemical mapping. Gdown1's binding sites overlap extensively with those of TFIIF, with Gdown1 sterically excluding TFIIF from RNAPII, herein demonstrated by competition assays using size exclusion chromatography. In summary, our work establishes a structural basis for Gdown1 impeding initiation at promoters, by obstruction of TFIIF, accounting for an additional dependent role of Mediator in activated transcription.

Efficient reconstitution of transcription elongation complexes for single-molecule studies of eukaryotic RNA polymerase II.

Single-molecule studies of RNA polymerase II (RNAP II) require high yields of transcription elongation complexes (TECs) with long DNA tethers upstream and downstream of the TEC. Here we report on a robust system to reconstitute both yeast and mammalian RNAP II with an efficiency of ~80% into TECs that elongate with an efficiency of ~90%, followed by rapid, high-efficiency tripartite ligation of long DNA fragments upstream and downstream of the reconstituted TECs. Single mammalian and yeast TECs reconstituted with this method have been successfully used in an optical-trapping transcription assay capable of applying forces that either assist or hinder transcript elongation.

Functional association of Gdown1 with RNA polymerase II poised on human genes.

Most human genes are loaded with promoter-proximally paused RNA polymerase II (Pol II) molecules that are poised for release into productive elongation by P-TEFb. We present evidence that Gdown1, the product of the POLR2M gene that renders Pol II responsive to Mediator, is involved in Pol II elongation control. During in vitro transcription, Gdown1 specifically blocked elongation stimulation by TFIIF, inhibited the termination activity of TTF2, and influenced pausing factors NELF and DSIF, but did not affect the function of TFIIS or the mRNA capping enzyme. Without P-TEFb, Gdown1 led to the production of stably paused polymerases in the presence of nuclear extract. Supporting these mechanistic insights, ChIP-Seq demonstrated that Gdown1 mapped over essentially all poised polymerases across the human genome. Our results establish that Gdown1 stabilizes poised polymerases while maintaining their responsiveness to P-TEFb and suggest that Mediator overcomes a Gdown1-mediated block of initiation by allowing TFIIF function.

Transcriptional regulation by Pol II(G) involving mediator and competitive interactions of Gdown1 and TFIIF with Pol II.

Pol II(G) is a distinct form of RNA polymerase II that contains the tightly associated Gdown1 polypeptide (encoded by POLR2M). Unlike Pol II, Pol II(G) is highly dependent upon Mediator for robust activator-dependent transcription in a biochemically defined in vitro system. Here, in vitro studies show that Gdown1 competes with TFIIF for binding to the RPB1 and RPB5 subunits of Pol II, thereby inhibiting an essential function of TFIIF in preinitiation complex assembly, but also that Mediator can actually facilitate Pol II(G) binding to the promoter prior to subsequent Mediator functions. Complementary ChIP and RNAi analyses reveal that Pol II(G) is recruited to promoter regions of subsets of actively transcribed genes, where it appears to restrict transcription. These and other results suggest that Pol II(G) may act to modulate some genes while simultaneously, as a poised (noninitiated) polymerase, setting the stage for Mediator-dependent enhancement of their activity.

Regulation of RUNX2 transcription factor-DNA interactions and cell proliferation by vitamin D3 (cholecalciferol) prohormone activity.

The fat-soluble prohormone cholecalciferol (Vitamin D3) is a precursor of the circulating 25-OH Vitamin D3, which is converted by 1α-hydroxylase to the biologically active 1,25-OH Vitamin D3. Active Vitamin D3 interacts with the Vitamin D receptor (VDR), a transcription factor that plays an important role in calcium mobilization and bone formation. RUNX2 is a DNA-binding transcription factor that regulates target genes important in bone formation, angiogenesis, and cancer metastasis. Using computer-assisted drug design (CADD) and a microtiter plate-based DNA-binding enzyme-linked immunosorbent assay (D-ELISA) to measure nuclear RUNX2 DNA binding, we have found that Vitamin D3 prohormones can modulate RUNX2 DNA binding, which was dose-dependent and sensitive to trypsin, salt, and phosphatase treatment. Unlabeled oligonucleotide or truncated, dominant negative RUNX2 proteins were competitive inhibitors of RUNX2 DNA binding. The RUNX2 heterodimeric partner, Cbfß, was detected in the binding complexes with specific antibodies. Evaluation of several RUNX2:DNA targeted small molecules predicted by CADD screening revealed a previously unknown biological activity of the inactive Vitamin D3 precursor, cholecalciferol. Cholecalciferol modulated RUNX2:DNA binding at nanomolar concentrations even in cells with low VDR. Cholecalciferol and 25-OH Vitamin D3 prohormones were selective inhibitors of RUNX2-positive endothelial, bone, and breast cancer cell proliferation, but not of cells lacking RUNX2 expression. These compounds may have application in modulating RUNX2 activity in an angiogenic setting, in metastatic cells, and to promote bone formation in disease-mediated osteoporosis. The combination CADD discovery and D-ELISA screening approaches allows the testing of other novel derivatives of Vitamin D and/or transcriptional inhibitors with the potential to regulate DNA binding and biological function.

Differential blocking effects of the acetaldehyde-derived DNA lesion N2-ethyl-2'-deoxyguanosine on transcription by multisubunit and single subunit RNA polymerases.

Acetaldehyde, the first metabolite of ethanol, reacts with DNA to form adducts, including N(2)-ethyl-2'-deoxyguanosine (N(2)-Et-dG). Although the effects of N(2)-Et-dG on DNA polymerases have been well studied, nothing is known about possible effects of this lesion on transcription by RNA polymerases (RNAPs). Using primer extension assays in vitro, we found that a single N(2)-Et-dG lesion is a strong block to both mammalian RNAPII and two other multisubunit RNAPs, (yeast RNAPII and Escherichia coli RNAP), as well as to T7 RNAP. However, the mechanism of transcription blockage appears to differ between the multisubunit RNAPs and T7 RNAP. Specifically, all three of the multisubunit RNAPs can incorporate a single rNTP residue opposite the lesion, whereas T7 RNAP is essentially unable to do so. Using the mammalian RNAPII, we found that CMP is exclusively incorporated opposite the N(2)-Et-dG lesion. In addition, we also show that the accessory transcription factor TFIIS does not act as a lesion bypass factor, as it does for other nonbulky DNA lesions; instead, it stimulates the polymerase to remove the CMP incorporated opposite the lesion by mammalian RNAPII. We also include models of the N(2)-Et-dG within the active site of yeast RNAPII, which are compatible with our observations.

Knockdown of TFIIS by RNA silencing inhibits cancer cell proliferation and induces apoptosis.

BACKGROUND: A common element among cancer cells is the presence of improperly controlled transcription. In these cells, the degree of specific activation of some genes is abnormal, and altering the aberrant transcription may therefore directly target cancer. TFIIS is a transcription elongation factor, which directly binds the transcription motor, RNA Polymerase II and allows it to read through various transcription arrest sites. We report on RNA interference of TFIIS, a transcription elongation factor, and its affect on proliferation of cancer cells in culture. METHODS: RNA interference was performed by transfecting siRNA to specifically knock down TFIIS expression in MCF7, MCF10A, PL45 and A549 cells. Levels of TFIIS expression were determined by the Quantigene method, and relative protein levels of TFIIS, c-myc and p53 were determined by C-ELISA. Induction of apoptosis was determined by an enzymatic Caspase 3/7 assay, as well as a non-enzymatic assay detecting cytoplasmic mono- and oligonucleosomes. A gene array analysis was conducted for effects of TFIIS siRNA on MCF7 and MCF10A cell lines. RESULTS: Knockdown of TFIIS reduced cancer cell proliferation in breast, lung and pancreatic cancer cell lines. More specifically, TFIIS knockdown in the MCF7 breast cancer cell line induced cancer cell death and increased c-myc and p53 expression whereas TFIIS knockdown in the non-cancerous breast cell line MCF10A was less affected. Differential effects of TFIIS knockdown in MCF7 and MCF10A cells included the estrogenic, c-myc and p53 pathways, as observed by C-ELISA and gene array, and were likely involved in MCF7 cell-death. CONCLUSION: Although transcription is a fundamental process, targeting select core transcription factors may provide for a new and potent avenue for cancer therapeutics. In the present study, knockdown of TFIIS inhibited cancer cell proliferation, suggesting that TFIIS could be studied as a potential cancer target within the transcription machinery.

A Mediator-responsive form of metazoan RNA polymerase II.

RNA polymerase II (Pol II), whose 12 subunits are conserved across eukaryotes, is at the heart of the machinery responsible for transcription of mRNA. Although associated general transcription factors impart promoter specificity, responsiveness to gene- and tissue-selective activators additionally depends on the multiprotein Mediator coactivator complex. We have isolated from tissue extracts a distinct and abundant mammalian Pol II subpopulation that contains an additional tightly associated polypeptide, Gdown1. Our results establish that Gdown1-containing Pol II, designated Pol II(G), is selectively dependent on and responsive to Mediator. Thus, in an in vitro assay with general transcription factors, Pol II lacking Gdown1 displays unfettered levels of activator-dependent transcription in the presence or absence of Mediator. In contrast, Pol II(G) is dramatically less efficient in responding to activators in the absence of Mediator yet is highly and efficiently responsive to activators in the presence of Mediator. Our results reveal a transcriptional control mechanism in which Mediator-dependent regulation is enforced by means of Gdown1, which likely restricts Pol II function only to be reversed by Mediator.

Fcp1 directly recognizes the C-terminal domain (CTD) and interacts with a site on RNA polymerase II distinct from the CTD.

Fcp1 is an essential protein phosphatase that hydrolyzes phosphoserines within the C-terminal domain (CTD) of the largest subunit of RNA polymerase II (Pol II). Fcp1 plays a major role in the regulation of CTD phosphorylation and, hence, critically influences the function of Pol II throughout the transcription cycle. The basic understanding of Fcp1-CTD interaction has remained ambiguous because two different modes have been proposed: the "dockingsite" model versus the "distributive" mechanism. Here we demonstrate biochemically that Fcp1 recognizes and dephosphorylates the CTD directly, independent of the globular non-CTD part of the Pol II structure. We point out that the recognition of CTD by the phosphatase is based on random access and is not driven by Pol II conformation. Results from three different types of experiments reveal that the overall interaction between Fcp1 and Pol II is not stable but dynamic. In addition, we show that Fcp1 also interacts with a region on the polymerase distinct from the CTD. We emphasize that this non-CTD site is functionally distinct from the docking site invoked previously as essential for the CTD phosphatase activity of Fcp1. We speculate that Fcp1 interaction with the non-CTD site may mediate its stimulatory effect on transcription elongation reported previously.

Elongation by RNA polymerase II: structure-function relationship.

RNA polymerase II is the eukaryotic enzyme that transcribes all the mRNA in the cell. Complex mechanisms of transcription and its regulation underlie basic functions including differentiation and morphogenesis. Recent evidence indicates the process of RNA chain elongation as a key step in transcription control. Elongation was therefore expected and found to be linked to human diseases. For these reasons, major efforts in determining the structures of RNA polymerases from yeast and bacteria, at rest and as active enzymes, were undertaken. These studies have revealed much information regarding the processes involved in transcription. Eukaryotic RNA polymerases and their homologous bacterial counterparts are flexible enzymes with domains that separate DNA and RNA, prevent the escape of nucleic acids during transcription, allow for extended pausing or "arrest" during elongation, allow for translocation of the DNA and more. Structural studies of RNA polymerases are described below within the context of the process of transcription elongation, its regulation and function.