DNA melting and promoter clearance by eukaryotic RNA polymerase I

Reaction Mechanisms of Pol IV, RDR2, and DCL3 Drive RNA Channeling in the siRNA-Directed DNA Methylation Pathway

In eukaryotes with multiple small RNA pathways, the mechanisms that channel RNAs within specific pathways are unclear. Here, we reveal the reactions that account for channeling in the small interfering RNA (siRNA) biogenesis phase of the Arabidopsis RNA-directed DNA methylation pathway. The process begins with template DNA transcription by NUCLEAR RNA POLYMERASE IV (Pol IV), whose atypical termination mechanism, induced by nontemplate DNA base-pairing, channels transcripts to the associated RNA-dependent RNA polymerase RDR2. RDR2 converts Pol IV transcripts into double-stranded RNAs and then typically adds an extra untemplated 3' terminal nucleotide to the second strands. The dicer endonuclease DCL3 cuts resulting duplexes to generate 24- and 23-nt siRNAs. The 23-nt RNAs bear the untemplated terminal nucleotide of the RDR2 strand and are underrepresented among ARGONAUTE4-associated siRNAs. Collectively, our results provide mechanistic insights into Pol IV termination, Pol IV-RDR2 coupling, and RNA channeling, from template DNA transcription to siRNA strand discrimination.

Structural mechanism of ATP-independent transcription initiation by RNA polymerase I

Transcription initiation by RNA Polymerase I (Pol I) depends on the Core Factor (CF) complex to recognize the upstream promoter and assemble into a Pre-Initiation Complex (PIC). Here, we solve a structure of Saccharomyces cerevisiae Pol I-CF-DNA to 3.8 Å resolution using single-particle cryo-electron microscopy. The structure reveals a bipartite architecture of Core Factor and its recognition of the promoter from -27 to -16. Core Factor's intrinsic mobility correlates well with different conformational states of the Pol I cleft, in addition to the stabilization of either Rrn7 N-terminal domain near Pol I wall or the tandem winged helix domain of A49 at a partially overlapping location. Comparison of the three states in this study with the Pol II system suggests that a ratchet motion of the Core Factor-DNA sub-complex at upstream facilitates promoter melting in an ATP-independent manner, distinct from a DNA translocase actively threading the downstream DNA in the Pol II PIC.

Complementary roles of yeast Rad4p and Rad34p in nucleotide excision repair of active and inactive rRNA gene chromatin

Nucleotide excision repair (NER) removes a plethora of DNA lesions. It is performed by a large multisubunit protein complex that finds and repairs damaged DNA in different chromatin contexts and nuclear domains. The nucleolus is the most transcriptionally active domain, and in yeast, transcription-coupled NER occurs in RNA polymerase I-transcribed genes (rDNA). Here we have analyzed the roles of two members of the xeroderma pigmentosum group C family of proteins, Rad4p and Rad34p, during NER in the active and inactive rDNA. We report that Rad4p is essential for repair in the intergenic spacer, the inactive rDNA coding region, and for strand-specific repair at the transcription initiation site, whereas Rad34p is not. Rad34p is necessary for transcription-coupled NER that starts about 40 nucleotides downstream of the transcription initiation site of the active rDNA, whereas Rad4p is not. Thus, although Rad4p and Rad34p share sequence homology, their roles in NER in the rDNA locus are almost entirely distinct and complementary. These results provide evidences that transcription-coupled NER and global genome NER participate in the removal of UV-induced DNA lesions from the transcribed strand of active rDNA. Furthermore, nonnucleosome rDNA is repaired faster than nucleosome rDNA, indicating that an open chromatin structure facilitates NER in vivo.

Formation, control, and dynamics of N localized structures in the Peyrard-Bishop model

We explore in detail the creation of stable localized structures in the form of localized energy distributions that arise from general initial conditions in the Peyrard-Bishop (PB) model. By means of a method based on the inverse scattering transform we study the solutions of PB model equations obtained in the form of planar waves whose amplitudes are described by the nonlinear Schrödinger equation (NLS). For localized initial conditions different from the pure N-soliton shape, we have obtained analytical results that predict and control the number, amplitude, and velocity of the NLS solitary waves. To verify the validity of these results we have carried out numerical simulations of the PB model with the use of realistic values of parameters and the initial conditions in the form of planar waves whose modulated amplitudes are given by the examples studied in the NLS. In the simulations we have found that N localized structures arise in agreement with the prediction of the analytical results obtained in the NLS.

A tunable ratchet driving human RNA polymerase II translocation adjusted by accurately templated nucleoside triphosphates loaded at downstream sites and by elongation factors

When nucleoside triphosphate (NTP) substrates and alpha-amanitin are added to a human RNA polymerase II elongation complex simultaneously, the reaction becomes stalled in the core of the bond synthesis mechanism. The mode of stalling is influenced by NTP substrates at the active site and at downstream sites and by transcription factor IIF (TFIIF) and TFIIS. NTP substrates templated at i+2, i+3, and i+4 downstream DNA sites can reverse the previously stable binding of an NTP loaded at the i+1 substrate site. Deoxy-(d)NTPs and NDPs (nucleoside diphosphates) do not substitute for NTPs at the i+2 and i+3 positions (considered together) or the i+4, i+5, and i+6 positions (considered together). The mode of stalling is altered by changing the number of downstream template sites that are accurately occupied by NTPs and by changing NTP concentration. In the presence of the translocation blocker alpha-amanitin, a steady state condition is established in which RNA polymerase II stably loads an NTP substrate at i+1 and forms a phosphodiester bond but cannot rapidly complete bond synthesis by releasing pyrophosphate. These observations support a role for incoming NTP substrates in stimulating translocation; results appear inconsistent with the secondary pore being the sole route of NTP entry for human RNA polymerase II, and results indicate mechanisms of dynamic error avoidance and error correction during rapid RNA synthesis.

Inhibiting transcription of chromosomal DNA with antigene peptide nucleic acids

Synthetic molecules that recognize specific sequences within cellular DNA are potentially powerful tools for investigating chromosome structure and function. Here, we designed antigene peptide nucleic acids (agPNAs) to target the transcriptional start sites for the human progesterone receptor B (hPR-B) and A (hPR-A) isoforms at sequences predicted to be single-stranded within the open complex of chromosomal DNA. We found that the agPNAs were potent inhibitors of transcription, showing for the first time that synthetic molecules can recognize transcription start sites inside cells. Breast cancer cells treated with agPNAs showed marked changes in morphology and an unexpected relationship between the strictly regulated levels of hPR-B and hPR-A. We confirmed these phenotypes using siRNAs and antisense PNAs, demonstrating the power of combining antigene and antisense strategies for gene silencing. agPNAs provide a general approach for controlling transcription initiation and a distinct option for target validation and therapeutic development.

Stable transfection of Acanthamoeba castellanii

A simple method for stable transfection of Acanthamoeba castellanii using plasmids which confer resistance to neomycin G418 is described. Expression of neomycin phosphotransferase is driven by the Acanthamoeba TBP gene promoter, and can be monitored by cell growth in the presence of neomycin G418 or by Western blot analysis. Transfected cells can be passaged in the same manner as control cells and can be induced to differentiate into cysts, in which form they maintain resistance to neomycin G418 for at least several weeks, although expression of neomycin phosphotransferase is repressed during encystment. Expression of EGFP or an HA-tagged EGFP-TBP fusion can be driven from the same plasmid, using an additional copy of the Acanthamoeba TBP gene promoter or a deletion mutant. The TBP-EGFP fusion is localized to the nucleus, except in a small proportion of presumptive pre-mitotic cells. EGFP expression can also be driven by the cyst-specific CSP21 gene promoter, which is completely repressed in growing cells but strongly induced in differentiating cells. Transfected cells maintain their phenotype for several weeks, even in the absence of neomycin G418, suggesting that transfected genes are stably integrated within the genome. These results demonstrate the utility of the neomycin resistance based plasmids for stable transfection of Acanthamoeba, and may assist a number of investigations.

The association of TIF-IA and polymerase I mediates promoter recruitment and regulation of ribosomal RNA transcription in Acanthamoeba castellanii

Large amounts of energy are expended for the construction of the ribosome during both transcription and processing, so it is of utmost importance for the cell to efficiently regulate ribosome production. Understanding how this regulation occurs will provide important insights into cellular growth control and into the coordination of gene expression mediated by all three transcription systems. Ribosomal RNA (rRNA) transcription rates closely parallel the need for protein synthesis; as a cell approaches stationary phase or encounters conditions that negatively affect either growth rate or protein synthesis, rRNA transcription is decreased. In eukaryotes, the interaction of RNA polymerase I (pol I) with the essential transcription initiation factor IA (TIF-IA) has been implicated in this downregulation of transcription. In agreement with the first observation that rRNA transcription is regulated by altering recruitment of pol I to the promoter in Acanthamoeba castellanii, we show here that pol I and an 80-kDa homologue of TIF-IA are found tightly associated in pol I fractions competent for specific transcription. Disruption of the pol I-TIF-IA complex is mediated by a specific dephosphorylation of either pol I or TIF-IA. Phosphatase treatment of TIF-IA-containing A. castellanii pol I fractions results in a downregulation of both transcriptional activity and promoter binding, reminiscent of the inactive pol I fractions purified from encysted cells. The fraction of pol I competent for promoter recruitment is enriched in TIF-IA relative to that not bound by immobilized promoter DNA. This downregulation coincides with an altered electrophoretic mobility of TIF-IA, suggesting at least it is phosphorylated.

Photocross-linking of the RNA Polymerase I Preinitiation and Immediate Postinitiation Complexes

The architecture of eukaryotic rRNA transcription complexes was analyzed, revealing facts significant to the RNA polymerase (pol) I initiation process. Functional initiation and elongation complexes were mapped by site-specific photocross-linking to template DNA. Polymerase I is recruited to the promoter via protein-protein interactions with DNA-bound transcription initiation factor-IB. The latter's TATA-binding protein (TBP) and TAFs photocross-link to the promoter from -78 to +10 relative to the tis (+1). Although TBP does not bind DNA using its TATA-binding saddle, it does photocross-link to a 22-bp sequence that does not resemble a TATA box. Only TAF(I)96 (the mammalian TAF(I) 68, yeast Rrn7p homolog) overlaps significantly with the DNA interaction cleft of pol I based on modeling to the pol II crystal structure. None of the pol I-specific subunits that are localized on the lips of the cleft (A49 and A34.5) or the pol I-specific stalk (A43 and A14) cross-link to DNA. Pol I does not extend significantly upstream of the promoter-proximal border of the factor complex (-11 to -14), and similarly in the promoter proximal elongation complex, the enzyme does not contact DNA upstream of its normal exit from the cleft.

Analysis of the open region and of DNA-protein contacts of archaeal RNA polymerase transcription complexes during transition from initiation to elongation

The archaeal transcriptional machinery is polymerase II (pol II)-like but does not require ATP or TFIIH for open complex formation. We have used enzymatic and chemical probes to follow the movement of Pyrococcus RNA polymerase (RNAP) along the glutamate dehydrogenase gene during transcription initiation and transition to elongation. RNAP was stalled between registers +5 and +20 using C-minus cassettes. The upstream edge of RNAP was in close contact with the archaeal transcription factors TATA box-binding protein/transcription factor B in complexes stalled at position +5. Movement of the downstream edge of the RNAP was not detected by exonuclease III footprinting until register +8. A first structural transition characterized by movement of the upstream edge of RNAP was observed at registers +6/+7. A major transition was observed at registers +10/+11. In complexes stalled at these positions also the downstream edge of RNA polymerase started translocation, and reclosure of the initially open complex occurred indicating promoter clearance. Between registers +11 and +20 both RNAP and transcription bubble moved synchronously with RNA synthesis. The distance of the catalytic center to the front edge of the exo III footprint was approximately 12 nucleotides in all registers. The size of the RNA-DNA hybrid in an early archaeal elongation complex was estimated between 9 and 12 nucleotides. For complexes stalled between positions +10 and +20 the size of the transcription bubble was around 17 nucleotides. This study shows characteristic mechanistic properties of the archaeal system and also similarities to prokaryotic RNAP and pol II.

Pre-existing distortions in nucleic acid structure aid polypurine tract selection by HIV-1 reverse transcriptase

Precise cleavage at the polypurine tract (PPT)/U3 junction by human immunodeficiency virus type 1 (HIV-1) reverse transcriptase RNase H is critical for generating a correct viral DNA end for subsequent integration. Using potassium permanganate (KMnO(4)) modification, we have identified a significant distortion in the nucleic acid structure at the HIV-1 PPT/U3 junction in the absence of trans-acting factors. Unusually high reactivity of template thymine +1 is detected when the PPT primer is extended by DNA or RNA at its 3' terminus. Chemical footprinting suggests that the extent of base unstacking in the wild-type species is comparable when the +1 A:T base pair is replaced by a C:T mismatch. However, reactivity of this template base is diminished after alterations to upstream (rA)(4):(dT)(4) or (rG)(6):(dC)(6) tracts. Importantly, there is a correlation between the structural deformation at base pair +1 and precise cleavage at the PPT/U3 junction by HIV-1 reverse transcriptase/RNase H. KMnO(4) modification also revealed unusually high reactivity for one of two (dT)(4):(rA)(4) duplexes upstream of the PPT/U3 junction, suggesting a significant structural distortion within the PPT itself in the absence of the retroviral polymerase. Structural abnormalities in this region are not only essential for resistance of the PPT to hydrolysis but also significantly impact the conformation of the PPT/U3 junction. Our data collectively suggest that the entire PPT sequence contributes to the structural distortion at the PPT/U3 junction, potentially providing a mechanism for its selective processing.

A novel RNA polymerase I transcription initiation factor, TIF-IE, commits rRNA genes by interaction with TIF-IB, not by DNA binding

In the small, free-living amoeba Acanthamoeba castellanii, rRNA transcription requires, in addition to RNA polymerase I, a single DNA-binding factor, transcription initiation factor IB (TIF-IB). TIF-IB is a multimeric protein that contains TATA-binding protein (TBP) and four TBP-associated factors that are specific for polymerase I transcription. TIF-IB is required for accurate and promoter-specific initiation of rRNA transcription, recruiting and positioning the polymerase on the start site by protein-protein interaction. In A. castellanii, partially purified TIF-IB can form a persistent complex with the ribosomal DNA (rDNA) promoter while homogeneous TIF-IB cannot. An additional factor, TIF-IE, is required along with homogeneous TIF-IB for the formation of a stable complex on the rDNA core promoter. We show that TIF-IE by itself, however, does not bind to the rDNA promoter and thus differs in its mechanism from the upstream binding factor and upstream activating factor, which carry out similar complex-stabilizing functions in vertebrates and yeast, respectively. In addition to its presence in impure TIF-IB, TIF-IE is found in highly purified fractions of polymerase I, with which it associates. Renaturation of polypeptides excised from sodium dodecyl sulfate-polyacrylamide gels showed that a 141-kDa polypeptide possesses all the known activities of TIF-IE.

Regulation of ribosome biogenesis within the nucleolus

Ribosome biogenesis is both necessary for cellular adaptation, growth, and proliferation as well as a major energetic and biosynthetic demand upon cells. For these reasons, ribosome biogenesis requires precise regulation to balance supply and demand. The complexity of ribosome biogenesis gives rise to many steps and opportunities where regulation could take place. For trans-acting factors involved in ribosome biogenesis in the nucleolus, there may be a dynamic coordination, both spatially and temporally, that regulates their functions from the transcription of rDNA to the assembly and export of preribosomal particles. Here we summarize most of the described regulations on ribosome biogenesis in the nucleolus. However, these may represent only a small fraction of a larger picture. Further studies are required to determine the initial signals, signal transduction pathways utilized, and the specific targets of these regulatory modifications and how these are used to control ribosome biogenesis as a whole.

Phosphorylation of the RNA-dependent protein kinase regulates its RNA-binding activity

The RNA-dependent protein kinase (PKR) is an interferon-induced, RNA-activated enzyme that phosphorylates the alpha-subunit of eukaryotic initiation factor 2 (eIF2alpha), inhibiting the function of the eIF2 complex and continued initiation of translation. When bound to an activating RNA and ATP, PKR undergoes autophosphorylation reactions at multiple serine and threonine residues. This autophosphorylation reaction stimulates the eIF2alpha kinase activity of PKR. The binding of certain viral RNAs inhibits the activation of PKR. Wild-type PKR is obtained as a highly phosphorylated protein when overexpressed in Escherichia coli. We report here that treatment of the isolated phosphoprotein with the catalytic subunit of protein phosphatase 1 dephosphorylates the enzyme. The in vitro autophosphorylation and eIF2alpha kinase activities of the dephosphorylated enzyme are stimulated by addition of RNA. Thus, inactivation by phosphatase treatment of autophosphorylated PKR obtained from overexpression in bacteria generates PKR in a form suitable for in vitro analysis of the RNA-induced activation mechanism. Furthermore, we used gel mobility shift assays, methidiumpropyl-EDTA.Fe footprinting and affinity chromatography to demonstrate differences in the RNA-binding properties of phospho- and dephosphoPKR. We found that dephosphorylation of PKR increases binding affinity of the enzyme for both kinase activating and inhibiting RNAs. These results are consistent with an activation mechanism that includes release of the activating RNA upon autophosphorylation of PKR prior to phosphorylation of eIF2alpha.

The RNA polymerase III transcription initiation factor TFIIIB participates in two steps of promoter opening

Evidence for post-recruitment functions of yeast transcription factor (TF)IIIB in initiation of transcription was first provided by the properties of TFIIIB-RNA polymerase III-promoter complexes assembled with deletion mutants of its Brf and B" subunits that are transcriptionally inactive because they fail to open the promoter. The experiments presented here show that these defects can be repaired by unpairing short (3 or 5 bp) DNA segments spanning the transcription bubble of the open promoter complex. Analysis of this suppression phenomenon indicates that TFIIIB participates in two steps of promoter opening by RNA polymerase III that are comparable to the successive steps of promoter opening by bacterial RNA polymerase holoenzyme. B" deletions between amino acids 355 and 421 interfere with the initiating step of DNA strand separation at the upstream end of the transcription bubble. Removing an N-terminal domain of Brf interferes with downstream propagation of the transcription bubble to and beyond the transcriptional start site.

Interaction of a group II intron ribonucleoprotein endonuclease with its DNA target site investigated by DNA footprinting and modification interference

Group II intron mobility occurs by a target DNA-primed reverse transcription mechanism in which the intron RNA reverse splices directly into one strand of a double-stranded DNA target site, while the intron-encoded protein cleaves the opposite strand and uses it as a primer to reverse transcribe the inserted intron RNA. The group II intron endonuclease, which mediates this process, is an RNP particle that contains the intron-encoded protein and the excised intron RNA and uses both cooperatively to recognize DNA target sequences. Here, we analyzed the interaction of the Lactococcus lactis Ll.LtrB group II intron endonuclease with its DNA target site by DNA footprinting and modification-interference approaches. In agreement with previous mutagenesis experiments showing a relatively large target site, DNase I protection extends from position -25 to +19 from the intron-insertion site on the top strand and from -28 to +16 on the bottom strand. Our results suggest that the protein first recognizes a small number of specific bases in the distal 5'-exon region of the DNA target site via major-groove interactions. These base interactions together with additional phosphodiester-backbone interactions along one face of the helix promote DNA unwinding, enabling the intron RNA to base-pair to DNA top-strand positions -12 to +3 for reverse splicing. Notably, DNA unwinding extends to at least position +6, somewhat beyond the region that base-pairs with the intron RNA, but is not dependent on interaction of the conserved endonuclease domain with the 3' exon. Bottom-strand cleavage occurs after reverse splicing and requires recognition of a small number of additional bases in the 3' exon, the most critical being T+5 in the now single-stranded downstream region of the target site. Our results provide the first detailed view of the interaction of a group II intron endonuclease with its DNA target site.