Localization of an alpha-amanitin resistance mutation in the gene encoding the largest subunit of mouse RNA polymerase II

Dynamic chromosome association with nuclear organelles in living cells

The development of progressively sophisticated tools complemented by the integration of live cell imaging enhances our understanding of the four-dimensional (4D) nucleome, revealing elaborate molecular interactions and chromatin states. Yet, the dynamics of chromosomes in relation to nuclear organelles or to each other across cell cycle in living cells are underexplored. We have developed photoconvertible GFP H3-Dendra2 stably expressing in PC3M cells. The nuclear lamina and perinucleolar associated heterochromatin or diffuse chromosome regions were photoconverted through a single-point activation using a confocal microscope. The results demonstrated a dynamic nature for both types of chromosomes in the same cell cycle and across mitosis. While some chromosome domains were heritably associated with either nuclear lamina or nucleoli, others changed alliance to different nuclear organelles postmitotically. In addition, co-photoconverted chromosome domains often do not stay together within the same cell cycle and across mitosis, suggesting a transient nature of chromosome neighborhoods. Long-range spreading and movement of chromosomes were also observed. Interestingly, when cells were treated with a low concentration of actinomycin D that inhibits Pol I transcription through intercalating GC-rich DNA, chromosome movement was significantly blocked. Treatment with another Pol I inhibitor, metarrestin, which does not impact DNA, had little effect on the movement, suggesting that the DNA structure itself plays a role in chromosome dynamics. Furthermore, inhibition of Pol II transcription with α-amanitin also reduced the chromosome movement, demonstrating that Pol II, but not Pol I transcription, is important for chromosome dynamics in the nucleus.

Crosstalk between RNA Pol II C-Terminal Domain Acetylation and Phosphorylation via RPRD Proteins

Post-translational modifications of the RNA polymerase II C-terminal domain (CTD) coordinate the transcription cycle. Crosstalk between different modifications is poorly understood. Here, we show how acetylation of lysine residues at position 7 of characteristic heptad repeats (K7ac)-only found in higher eukaryotes-regulates phosphorylation of serines at position 5 (S5p), a conserved mark of polymerases initiating transcription. We identified the regulator of pre-mRNA-domain-containing (RPRD) proteins as reader proteins of K7ac. K7ac enhanced CTD peptide binding to the CTD-interacting domain (CID) of RPRD1A and RPRD1B proteins in isothermal calorimetry and molecular modeling experiments. Deacetylase inhibitors increased K7ac- and decreased S5-phosphorylated polymerases, consistent with acetylation-dependent S5 dephosphorylation by an RPRD-associated S5 phosphatase. Consistent with this model, RPRD1B knockdown increased S5p but enhanced K7ac, indicating that RPRD proteins recruit K7 deacetylases, including HDAC1. We also report autoregulatory crosstalk between K7ac and S5p via RPRD proteins and their interactions with acetyl- and phospho-eraser proteins.

Analysis of RNA polymerase II ubiquitylation and proteasomal degradation

Transcribing RNA polymerase II (RNAPII) is decorated by a plethora of post-translational modifications that mark different stages of transcription. One important modification is RNAPII ubiquitylation, which occurs in response to numerous different stimuli that cause RNAPII stalling, such as DNA damaging agents, RNAPII inhibitors, or depletion of the nucleotide pool. Stalled RNAPII triggers a so-called "last resort pathway", which involves RNAPII poly-ubiquitylation and proteasome-mediated degradation. Different approaches have been described to study RNAPII poly-ubiquitylation and degradation, each method with its own advantages and caveats. Here, we describe optimised strategies for detecting ubiquitylated RNAPII and studying its degradation, but these protocols are suitable for studying other ubiquitylated proteins as well.

Acetylation of RNA polymerase II regulates growth-factor-induced gene transcription in mammalian cells

Lysine acetylation regulates transcription by targeting histones and nonhistone proteins. Here we report that the central regulator of transcription, RNA polymerase II, is subject to acetylation in mammalian cells. Acetylation occurs at eight lysines within the C-terminal domain (CTD) of the largest polymerase subunit and is mediated by p300/KAT3B. CTD acetylation is specifically enriched downstream of the transcription start sites of polymerase-occupied genes genome-wide, indicating a role in early stages of transcription initiation or elongation. Mutation of lysines or p300 inhibitor treatment causes the loss of epidermal growth-factor-induced expression of c-Fos and Egr2, immediate-early genes with promoter-proximally paused polymerases, but does not affect expression or polymerase occupancy at housekeeping genes. Our studies identify acetylation as a new modification of the mammalian RNA polymerase II required for the induction of growth factor response genes.

CTD serine-2 plays a critical role in splicing and termination factor recruitment to RNA polymerase II in vivo

Co-transcriptional pre-mRNA processing relies on reversible phosphorylation of the carboxyl-terminal domain (CTD) of Rpb1, the largest subunit of RNA polymerase II (RNAP II). In this study, we replaced in live cells the endogenous Rpb1 by S2A Rpb1, where the second serines (Ser2) in the CTD heptapeptide repeats were switched to alanines, to prevent phosphorylation. Although slower, S2A RNAP II was able to transcribe. However, it failed to recruit splicing components such as U2AF65 and U2 snRNA to transcription sites, although the recruitment of U1 snRNA was not affected. As a consequence, co-transcriptional splicing was impaired. Interestingly, the magnitude of the S2A RNAP II splicing defect was promoter dependent. In addition, S2A RNAP II showed an impaired recruitment of the cleavage factor PCF11 to pre-mRNA and a defect in 3'-end RNA cleavage. These results suggest that CTD Ser2 plays critical roles in co-transcriptional pre-mRNA maturation in vivo: It likely recruits U2AF65 to ensure an efficient co-transcriptional splicing and facilitates the recruitment of pre-mRNA 3'-end processing factors to enhance 3'-end cleavage.

Identification and validation of protein targets of bioactive small molecules

Identification and validation of protein targets of bioactive small molecules is an important problem in chemical biology and drug discovery. Currently, no single method is satisfactory for this task. Here, we provide an overview of common methods for target identification and validation that historically were most successful. We have classified for the first time the existing methods into two distinct and complementary types, the 'top-down' and 'bottom-up' approaches. In a typical top-down approach, the cellular phenotype is used as a starting point and the molecular target is approached through systematic narrowing down of possibilities by taking advantage of the detailed existing knowledge of cellular pathways and processes. In contrast, the bottom-up approach entails the direct detection and identification of the molecular targets using affinity-based or genetic methods. A special emphasis is placed on target validation, including correlation analysis and genetic methods, as this area is often ignored despite its importance.

Distribution and mechanism of α-amanitin tolerance in mycophagous Drosophila (Diptera: Drosophilidae)

Many mycophagous species of Drosophila can tolerate the mushroom poison α-amanitin in wild mushrooms and in artificial diet. We conducted feeding assays with sixteen Drosophila species and α-amanitin in artificial diet to better determine the phylogenetic distribution of this tolerance. For eight tolerant and one related susceptible species, we sequenced the gene encoding the large subunit of RNA Polymerase II, which is the target site of α-amanitin. We found no differences in the gene that could account for differences in susceptibility to the toxin. We also conducted feeding assays in which α-amanitin was combined with chemical inhibitors of cytochrome P450s or glutathione S-transferases (GSTs) in artificial diet to determine if either of these enzyme families is involved in tolerance to α-amanitin. We found that an inhibitor of GSTs did not reduce tolerance to α-amanitin, but that an inhibitor of cytochrome P450s reduced tolerance in several species. It is possible that the same cytochrome P450 activity that produces tolerance of α-amanitin might produce tolerance of other mushroom toxins as well. If so, a general detoxification mechanism based on cytochrome P450s might answer the question of how tolerance to α-amanitin arose in mycophagous Drosophila when this toxin is found in relatively few mushrooms.

Phylogeny of parasitic parabasalia and free-living relatives inferred from conventional markers vs. Rpb1, a single-copy gene

BACKGROUND

Parabasalia are single-celled eukaryotes (protists) that are mainly comprised of endosymbionts of termites and wood roaches, intestinal commensals, human or veterinary parasites, and free-living species. Phylogenetic comparisons of parabasalids are typically based upon morphological characters and 18S ribosomal RNA gene sequence data (rDNA), while biochemical or molecular studies of parabasalids are limited to a few axenically cultivable parasites. These previous analyses and other studies based on PCR amplification of duplicated protein-coding genes are unable to fully resolve the evolutionary relationships of parabasalids. As a result, genetic studies of Parabasalia lag behind other organisms.

PRINCIPAL FINDINGS

Comparing parabasalid EF1α, α-tubulin, enolase and MDH protein-coding genes with information from the Trichomonas vaginalis genome reveals difficulty in resolving the history of species or isolates apart from duplicated genes. A conserved single-copy gene encodes the largest subunit of RNA polymerase II (Rpb1) in T. vaginalis and other eukaryotes. Here we directly sequenced Rpb1 degenerate PCR products from 10 parabasalid genera, including several T. vaginalis isolates and avian isolates, and compared these data by phylogenetic analyses. Rpb1 genes from parabasalids, diplomonads, Parabodo, Diplonema and Percolomonas were all intronless, unlike intron-rich homologs in Naegleria, Jakoba and Malawimonas.

CONCLUSIONS/SIGNIFICANCE

The phylogeny of Rpb1 from parasitic and free-living parabasalids, and conserved Rpb1 insertions, support Trichomonadea, Tritrichomonadea, and Hypotrichomonadea as monophyletic groups. These results are consistent with prior analyses of rDNA and GAPDH sequences and ultrastructural data. The Rpb1 phylogenetic tree also resolves species- and isolate-level relationships. These findings, together with the relative ease of Rpb1 isolation, make it an attractive tool for evaluating more extensive relationships within Parabasalia.

A genetic analysis of Plasmodium falciparum RNA polymerase II subunits in yeast

RNA polymerase II is an essential nuclear multi subunit enzyme that transcribes nearly the whole genome. Its inhibition by the alpha-amanitin toxin leads to cell death. The enzyme of Plasmodium falciparum remains poorly characterized. Using a complementation assay in yeast as a genetic test, we demonstrate that five Plasmodium putative RNA polymerase subunits are indeed functional in vivo. The active site of this enzyme is built from the two largest subunits. Using site directed mutagenesis we were able to modify the active site of the yeast RNA polymerase II so as to introduce Plasmodium or human structural motifs. The resulting strains allow the screening of chemical libraries for potential specific inhibitors.

Splicing- and cleavage-independent requirement of RNA polymerase II CTD for mRNA release from the transcription site

Eukaryotic cells have a surveillance mechanism that identifies aberrantly processed pre-mRNAs and prevents their flow to the cytoplasm by tethering them near the site of transcription. Here we provide evidence that mRNA release from the transcription site requires the heptad repeat structure of the C-terminal domain (CTD) of RNA polymerase II. The mammalian CTD, which is essential for normal co-transcriptional maturation of mRNA precursors, comprises 52 heptad repeats. We show that a truncated CTD containing 31 repeats (heptads 1–23, 36–38, and 48–52) is sufficient to support transcription, splicing, cleavage, and polyadenylation. Yet, the resulting mRNAs are mostly retained in the vicinity of the gene after transcriptional shutoff. The retained mRNAs maintain the ability to recruit components of the exon junction complex and the nuclear exosome subunit Rrp6p, suggesting that binding of these proteins is not sufficient for RNA release. We propose that the missing heptads in the truncated CTD mutant are required for binding of proteins implicated in a final co-transcriptional maturation of spliced and 3′ end cleaved and polyadenylated mRNAs into export-competent ribonucleoprotein particles.

Abundance of the largest subunit of RNA polymerase II in the nucleus is regulated by nucleo-cytoplasmic shuttling

Eukaryotic RNA polymerase II is a complex enzyme composed of 12 distinct subunits that is present in cells in low abundance. Transcription of mRNA by RNA polymerase II involves a phosphorylation/dephosphorylation cycle of the carboxyl-terminal domain (CTD) of the enzyme's largest subunit. We have generated stable murine cell lines expressing an alpha-amanitin-resistant form of the largest subunit of RNA polymerase II (RNA Pol II LS). These cells maintained transcriptional activity in the presence of alpha-amanitin, indicating that the exogenous protein was functional. We observed that over-expressed RNA Pol II LS was predominantly hypophosphorylated, soluble and accumulated in the cytoplasm in a CRM1-dependent manner. Our results further showed that the transcriptionally active form of RNA Pol II LS containing phosphoserine in position 2 of the CTD repeats was restricted to the nucleus and its levels remained remarkably constant. We propose that nucleo-cytoplasmic shuttling of RNA Pol II LS may provide a mechanism to control the pool of RNA polymerase subunits that is accessible for assembly of a functional enzyme in the nucleus.

Intrinsic transcript cleavage in yeast RNA polymerase II elongation complexes

Transcript elongation can be interrupted by a variety of obstacles, including certain DNA sequences, DNA-binding proteins, chromatin, and DNA lesions. Bypass of many of these impediments is facilitated by elongation factor TFIIS through a mechanism that involves cleavage of the nascent transcript by the RNA polymerase II/TFIIS elongation complex. Highly purified yeast RNA polymerase II is able to perform transcript hydrolysis in the absence of TFIIS. The "intrinsic" cleavage activity is greatly stimulated at mildly basic pH and requires divalent cations. Both arrested and stalled complexes can carry out the intrinsic cleavage reaction, although not all stalled complexes are equally efficient at this reaction. Arrested complexes in which the nascent transcript was cleaved in the absence of TFIIS were reactivated to readthrough blocks to elongation. Thus, cleavage of the nascent transcript is sufficient for reactivating some arrested complexes. Small RNA products released following transcript cleavage in stalled ternary complexes differ depending upon whether the cleavage has been induced by TFIIS or has occurred in mildly alkaline conditions. In contrast, both intrinsic and TFIIS-induced small RNA cleavage products are very similar when produced from an arrested ternary complex. Although alpha-amanitin interferes with the transcript cleavage stimulated by TFIIS, it has little effect on the intrinsic cleavage reaction. A mutant RNA polymerase previously shown to be refractory to TFIIS-induced transcript cleavage is essentially identical to the wild type polymerase in all tested aspects of intrinsic cleavage.

Mutations of bacterial RNA polymerase leading to resistance to microcin j25

A mutation in the conserved segment of the rpoC gene, which codes for the largest RNA polymerase (RNAP) subunit, beta', was found to make Escherichia coli cells resistant to microcin J25 (MccJ25), a bactericidal 21-amino acid peptide active against Gram-negative bacteria (Delgado, M. A., Rintoul, M. R., Farias, R. N., and Salomon, R. A. (2001) J. Bacteriol. 183, 4543-4550). Here, we report that mutant RNAP prepared from MccJ25-resistant cells, but not the wild-type RNAP, is resistant to MccJ25 in vitro, thus establishing that RNAP is a true cellular target of MccJ25. We also report the isolation of additional rpoC mutations that lead to MccJ25 resistance in vivo and in vitro. The new mutations affect beta' amino acids in evolutionarily conserved segments G, G', and F and are exposed into the RNAP secondary channel, a narrow opening that connects the enzyme surface with the catalytic center. We also report that previously known rpoB (RNAP beta subunit) mutations that lead to streptolydigin resistance cause resistance to MccJ25. We hypothesize that MccJ25 inhibits transcription by binding in RNAP secondary channel and blocking substrate access to the catalytic center.

RNA polymerase II large subunit is cleaved by caspases during DNA damage-induced apoptosis

UV radiation induces DNA lesions that are repaired by the nucleotide excision repair (NER) pathway. Cells that are NER deficient such as those derived from xeroderma pigmentosum (XP) patients are susceptible to apoptosis after 10J/m(2) UV radiation, a dose largely survivable by repair proficient cells. Herein, we report that RNA polymerase II large subunit (RNAP II-LS) undergoes caspase-mediated cleavage, yielding a 140kDa C-terminal fragment in XP lymphoblasts but not NER proficient lymphoblasts after 10J/m(2) UV irradiation. Cleavage could also be induced by cisplatin or oxaliplatin, but not transplatin, an isomer of cisplatin that does not induce DNA adducts. The cleavage of RNAP II-LS was blocked by a panel of caspase inhibitors but not by proteasomal inhibitors or inhibitors of other proteases. In vitro cleavage with caspase 8 yielded the same 140kDa RNAP II-LS fragment observed in vivo. Using site-directed mutagenesis, the RNAP II-LS cleavage site was localized to an LETD sequence ending at residue 1339, which is near its C-terminal domain.

TBP dynamics in living human cells: constitutive association of TBP with mitotic chromosomes

The recruitment of TATA binding protein (TBP) to gene promoters is a critical rate-limiting step in transcriptional regulation for all three eukaryotic RNA polymerases. However, little is known regarding the dynamics of TBP in live mammalian cells. In this report, we examined the distribution and dynamic behavior of green fluorescence protein (GFP)-tagged TBP in live HeLa cells using fluorescence recovery after photobleaching (FRAP) analyses. We observed that GFP-TBP associates with condensed chromosomes throughout mitosis without any FRAP. These results suggest that TBP stably associates with the condensed chromosomes during mitosis. In addition, endogenous TBP and TBP-associated factors (TAFs), specific for RNA polymerase II and III transcription, cofractionated with mitotic chromatin, suggesting that TBP is retained as a TBP-TAF complex on transcriptionally silent chromatin throughout mitosis. In interphase cells, GFP-TBP distributes throughout the nucleoplasm and shows a FRAP that is 100-fold slower than the general transcription factor GFP-TFIIB. This difference supports the idea that TBP and, most likely, TBP-TAF complexes, remain promoter- bound for multiple rounds of transcription. Altogether, our observations demonstrate that there are cell cycle specific characteristics in the dynamic behavior of TBP. We propose a novel model in which the association of TBP-TAF complexes with chromatin during mitosis marks genes for rapid transcriptional activation as cells emerge from mitosis.

The Leishmania major RNA polymerase II largest subunit lacks a carboxy-terminus heptad repeat structure and its encoding gene is linked with the calreticulin gene

The gene encoding the RNA polymerase II largest subunit (RPOIILS) has been isolated and sequenced from the kinetoplastid protozoan, Leishmania (Leishmania) major. The RPOIILS gene was shown to be present as a single copy and is composed of an uninterrupted open reading frame of 4.99 kb, specifying a protein 1663 aa in length with a predicted molecular mass of approximately 185 kDa. The carboxy terminus domain (CTD) of the RPOIILS from L. (L.) major, typical of the more evolutionary primitive protozoa, lacked a heptad repeat structure which is present in higher eukaryotes and some other protozoan phyla. Comparison of the predicted aa composition of the CTD from a diverse range of eukaryotic species revealed the abundance of Ser and Pro residues as the only discernible evolutionary conservative feature. A putative ATG start codon for an additional expressed sequence was located 1.1 kb downstream of the L. (L.) major RPOIILS gene stop codon. Nucleic acid database searches revealed the identity of this gene as that encoding the calcium binding protein calreticulin (CLT). The close proximity of the RPOIILS and CLT genes in L. (L.) major raises the possibility that these genes are transcribed as part of the same polycistronic unit.

Transcription of the kinetoplastid spliced leader RNA gene

In recent years, much has been learned about the cis-elements controlling transcription of the kinetoplastid spliced leader (SL) RNA gene. The SL RNA gene contains the first 39 nucleotides that are trans-spliced on to all nuclear-derived mRNAs in these organisms. Transcription initiation is determined by two precisely spaced upstream elements and transcription termination is directed by the downstream poly-T tract, although the RNA polymerase responsible for SL RNA synthesis is still questioned. In this article, David Campbell, Nancy Sturm and Michael Yu review the field of kinetoplastid SL RNA gene transcription, address past proposals in light of current data and discuss some of the differences that appear in the literature.

Specific HDV RNA-templated transcription by pol II in vitro

RNA polymerase II is implicated in the RNA-templated RNA synthesis during replication of viroids and Hepatitis Delta Virus (HDV); however, neither the RNA template nor protein factor requirements for this process are well defined. We have developed an in vitro transcription system based on HeLa cell nuclear extract (NE), in which a segment of antigenomic RNA corresponding to the left-hand tip region of the HDV rod-like structure serves as a template for efficient and highly specific RNA synthesis. Accumulation of the unique RNA product is highly sensitive to alpha-amanitin in HeLa NE and only partially sensitive to this drug in NE from PMG cells that contain an allele of the alpha-amanitin-resistant subunit of pol II, strongly suggesting pol II involvement in this reaction. Detailed analysis of the RNA product revealed that it represents a chimeric molecule composed of a newly synthesized transcript covalently attached to the 5' half of the RNA template. Selection of the start site for transcription is remarkably specific and depends on the secondary structure of the RNA template, rather than on its primary sequence. Some features of this reaction resemble the RNA cleavage-extension process observed for pol II-arrested complexes in vitro. A possible involvement of the described reaction in HDV replication is discussed.

RNA polymerase II targets pre-mRNA splicing factors to transcription sites in vivo

Biochemical evidence indicates that pre-mRNA splicing factors physically interact with the C-terminal domain of the largest subunit of RNA polymerase II. We have investigated the in vivo function of this interaction. In mammalian cells, truncation of the CTD of RNA pol II LS prevents the targeting of the splicing machinery to a transcription site. In the absence of the CTD, pre-mRNA splicing is severely reduced. The presence of unspliced RNA alone is not sufficient for the accumulation of splicing factors at the transcription site, nor for its efficient splicing. Our results demonstrate a critical role for the CTD of RNA pol II LS in the intranuclear targeting of splicing factors to transcription sites in vivo.

Functional organization of two large subunits of the fission yeast Schizosaccharomyces pombe RNA polymerase II. Location of the catalytic sites

The catalytically competent transcription complex of RNA polymerase II from the fission yeast Schizosaccharomyces pombe was affinity labeled with photoreactive nucleotide analogues incorporated at 3' termini of nascent RNA chains. To locate the catalytic site for RNA polymerization, the labeled subunits were separated by SDS-polyacrylamide gel electrophoresis and subjected to partial proteolysis. After microsequencing of proteolytic fragments, a complex multidomain organization was indicated for both of the two large subunits, Rpb1 and Rpb2, with the most available sites of proteolysis in junctions between the conserved sequences among RNA polymerase from both prokaryotes and eukaryotes. The cross-linking studies indicate the following: (i) the 3' termini of growing RNA chains are most extensively cross-linked to the second largest subunit Rpb2 between amino acids 825 and 994; (ii) the regions 298-535 of Rpb2 and 614-917 of Rpb1 are cross-linked to less extents, suggesting that these regions are situated in the vicinity of the catalytic site. All these regions include the conserved sequences of RNA polymerases, and the catalytic site of Rpb2 belongs to an NH2-terminal part of its conserved sequence H.

Ultraviolet radiation-induced ubiquitination and proteasomal degradation of the large subunit of RNA polymerase II. Implications for transcription-coupled DNA repair

We have shown previously that UV radiation and other DNA-damaging agents induce the ubiquitination of a portion of the RNA polymerase II large subunit (Pol II LS). In the present study UV irradiation of repair-competent fibroblasts induced a transient reduction of the Pol II LS level; new protein synthesis restored Pol II LS to the base-line level within 16-24 h. In repair-deficient xeroderma pigmentosum cells, UV radiation-induced ubiquitination of Pol II LS was followed by a sustained reduction of Pol II LS level. In both normal and xeroderma pigmentosum cells, the ubiquitinated Pol II LS had a hyperphosphorylated COOH-terminal domain (CTD), which is characteristic of elongating Pol II. The portion of Pol II LS whose steady-state level diminished most quickly had a relatively hypophosphorylated CTD. The ubiquitinated residues did not map to the CTD. Importantly, UV-induced reduction of Pol II LS level in repair-competent or -deficient cells was inhibited by the proteasome inhibitors lactacystin or MG132. These data demonstrate that UV-induced ubiquitination of Pol II LS is followed by its degradation in the proteasome. These results suggest, contrary to a current model of transcription-coupled DNA repair, that elongating Pol II complexes which arrest at intragenic DNA lesions may be aborted rather than resuming elongation after repair takes place.

Localization of yeast RNA polymerase I core subunits by immunoelectron microscopy

Immunoelectron microscopy was used to determine the spatial organization of the yeast RNA polymerase I core subunits on a three-dimensional model of the enzyme. Images of antibody-labeled enzymes were compared with the native enzyme to determine the localization of the antibody binding site on the surface of the model. Monoclonal antibodies were used as probes to identify the two largest subunits homologous to the bacterial beta and beta' subunits. The epitopes for the two monoclonal antibodies were mapped using subunit-specific phage display libraries, thus allowing a direct correlation of the structural data with functional information on conserved sequence elements. An epitope close to conserved region C of the beta-like subunit is located at the base of the finger-like domain, whereas a sequence between conserved regions C and D of the beta'-like subunit is located in the apical region of the enzyme. Polyclonal antibodies outlined the alpha-like subunit AC40 and subunit AC19 which were found co-localized also in the apical region of the enzyme. The spatial location of the subunits is correlated with their biological activity and the inhibitory effect of the antibodies.

Transcription in the early diverging eukaryote Trichomonas vaginalis: an unusual RNA polymerase II and alpha-amanitin-resistant transcription of protein-coding genes

We have examined transcription in an early diverging eukaryote by analyzing the effect of the fungus-derived toxin alpha-amanitin on the transcription of protein-coding genes of the protist Trichomonas vaginalis. In contrast to that typical in eukaryotes, the RNA polymerase that transcribes T. vaginalis protein-coding genes is relatively resistant to alpha-amanitin (50% inhibition = 250 microg alpha-amanitin/ml). We have also characterized the gene encoding the largest subunit of RNA polymerase II, the subunit that binds alpha-amanitin. This protein is 41% identical to the mouse RNA polymerase II. Sequence analysis of the 50-amino-acid region thought to bind alpha-amanitin shows that this region of the trichomonad RNA polymerase II lacks many of the conserved amino acids present in the putative binding site, in agreement with the observed insensitivity to this inhibitor. Similar to other RNA polymerase IIs analyzed from ancient eukaryotes, the T. vaginalis RNA polymerase II lacks the typical heptapeptide (Tyr-Ser-Pro-Thr-Ser-Pro-Ser) repeat carboxyl-terminal domain (CTD) that is a hallmark of higher eukaryotic RNA polymerase IIs. The trichomonad enzyme, however, does contain a short modified CTD that is rich in the amino acid residues that compose the repeat. These data suggest that T. vaginalis protein-coding genes are transcribed by a RNA polymerase II that is relatively insensitive to alpha-amanitin and that differs from typical eukaryotic RNA polymerase IIs as it lacks a heptapeptide repeated CTD.

Amanitin greatly reduces the rate of transcription by RNA polymerase II ternary complexes but fails to inhibit some transcript cleavage modes

The toxin alpha-amanitin is frequently employed to completely block RNA synthesis by RNA polymerase II. However, we find that polymerase II ternary transcription complexes stalled by the absence of NTPs resume RNA synthesis when NTPs and amanitin are added. Chain elongation with amanitin can continue for hours at approximately 1% of the normal rate. Amanitin also greatly slows pyrophosphorolysis by elongation-competent complexes. Complexes which are arrested (that is, which have paused in transcription for long periods in the presence of excess NTPs) are essentially incapable of resuming transcription in the presence of alpha-amanitin. Complexes traversing sequences that can provoke arrest are much more likely to stop transcription in the presence of the toxin. The substitution of IMP for GMP at the 3' end of the nascent RNA greatly increases the sensitivity of stalled transcription complexes to amanitin. Neither arrested nor stalled complexes display detectable SII-mediated transcript cleavage following amanitin treatment. However, arrested complexes possess a low level, intrinsic transcript cleavage activity which is completely amanitin-resistant; furthermore, pyrophosphorolytic transcript cleavage in arrested complexes is not affected by amanitin.

A structure/function analysis of Escherichia coli RNA polymerase

Control of RNA polymerase is a common means of regulating gene expression. A detailed picture of both the structure and how the structural details of RNA polymerase encode function is a key to understanding the molecular strategies used to regulate RNA polymerase. We review here data which ascribes functions to some regions of the primary sequence of the subunits (alpha, beta beta' sigma) which make up E. coli RNA polymerase. We review both genetic and biochemical data which place regions of the primary sequence that are distant from one another in close proximity in the tertiary structure. Finally we discuss the implications of these findings on the quaternary structure of RNA polymerase.

Mutations in the alpha-amanitin conserved domain of the largest subunit of yeast RNA polymerase III affect pausing, RNA cleavage and transcriptional transitions

The alpha-amanitin domain or domain f of the largest subunit of RNA polymerases is one of the most conserved of these enzymes. We have found that the C-terminal part of domain f can be swapped between yeast RNA polymerase II and III. An extensive mutagenesis of domain f of C160, the largest subunit of RNA polymerase III, was carried out to better define its role and understand the mechanism through which C160 participates in transcription. One mutant enzyme, C160-270, showed much reduced transcription of a non-specific template at low DNA concentrations. Abortive synthesis of trinucleotides in a dinucleotide-primed reaction proceeded at roughly wild-type levels, indicating that the mutation did not affect the formation of the first phosphodiester bond, but rather the transition from abortive initiation to processive elongation. In specific transcription assays, on the SUP4 tRNA gene, pausing was extended but the rate of RNA elongation between pause sites was not affected. Finally, the rate of cleavage of nascent RNA transcripts by halted mutant RNA polymerase was increased approximately 10-fold. We propose that the domain f mutation affects the transition between two transcriptional modes, one being adopted during abortive transcription and at pause sites, the other during elongation between pause sites.

Transcriptional competition and homeosis in Drosophila

Interference between different classes of RNA polymerase II alleles causes a mutant phenotype called the "Ubx effect" that resembles one seen in flies haploinsufficient for the transcription factor, Ultrabithorax (Ubx). Flies carrying the mutation in the largest subunit of Drosophila RNA polymerase II, RpII215(4), display the Ubx effect when heterozygous as in RpII215(4)/+ but not when homozygous mutant or wild type. In this report we demonstrate that the interaction between alleles in different classes of polymerase occurs even in the absence of transcription by the wild-type polymerase. We utilized the resistance to the transcriptional inhibitor alpha-amanitin conferred by RpII215(4) to show that RpII215(4)/+ flies raised on alpha-amanitin-containing food still show the Ubx effect and are indistinguishable from flies raised on normal food. We demonstrate using HPLC that the intracellular concentration of alpha-amanitin in the developing larvae is sufficient to inhibit transcription by alpha-amanitin-sensitive polymerase. Furthermore, fluorescein-labeled alpha-amanitin accumulates in imaginal discs, which are the precursor cells for the tissue showing the homeotic transformation in adults. We conclude that the interaction between different classes of RNA polymerase II alleles resulting in the Ubx effect occurs prior to the block in transcription caused by alpha-amanitin.

Streptolydigin-resistant mutants in an evolutionarily conserved region of the beta' subunit of Escherichia coli RNA polymerase

Mutations conferring streptolydigin resistance onto Escherichia coli RNA polymerase have been found exclusively in the beta subunit (Heisler, L. M., Suzuki, H., Landick, R., and Gross, C. A. (1993) J. Biol. Chem. 268, 25369-25375). We report here the isolation of a streptolydigin-resistant mutation in the E. coli rpoC gene, encoding the beta' subunit. The mutation is the Phe793-->Ser substitution, which occurred in an evolutionarily conserved segment of the beta' subunit. The homologous segment in the eukaryotic RNA polymerase II largest subunit harbors mutations conferring alpha-amanitin resistance. Both streptolydigin and alpha-amanitin are inhibitors of transcription elongation. Thus, the two antibiotics may inhibit transcription in their respective systems by a similar mechanism, despite their very different chemical nature.

RNA polymerase II C-terminal domain required for enhancer-driven transcription

The RNA polymerase II carboxy-terminal domain (CTD) consists of tandem repeats of the sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. The CTD may participate in activated transcription through interaction with a high-molecular-weight mediator complex. Such a role would be consistent with observations that some genes are preferentially sensitive to CTD mutations. Here we investigate the function of the mouse RNA polymerase CTD in enhancer-driven transcription. Transcription by alpha-amanitin-resistant CTD-deletion mutants was tested by transient transfection of tissue culture cells in the presence of alpha-amanitin in order to inhibit endogenous RNA polymerase II. Removal of most of the CTD abolishes transcriptional activation by all enhancers tested, whereas transcription from promoters driven by Sp1, a factor that typically activates housekeeping genes from positions proximal to the initiation sites, is not affected. These findings show that the CTD is essential in mediating 'enhancer'-type activation of mammalian transcription.

Clustered alpha-amanitin resistance mutations in mouse

We report the identification of three new alpha-amanitin resistance mutations in the gene encoding the largest subunit of mouse RNA polymerase II (RPII215). These mutations are clustered in a region of the largest subunit that is important for transcription elongation. This same domain has been identified as the site of alpha-amanitin resistance mutations in both Drosophila and Caenarhabditis elegans. The sequences encompassing this cluster of mutations are highly conserved among RNA polymerase II genes from a number of species, including those that are naturally more resistant to alpha-amanitin suggesting that this region of the largest subunit is critical for a conserved catalytic function. The mutations reported here change leucine 745 to phenylalanine, arginine 749 to proline, or isoleucine 779 to phenylalanine. Together with the previously reported asparagine 792 to aspartate substitution these mutations define a potential alpha-amanitin binding pocket in a region of the mouse subunit that could be involved in translocation of polymerase during elongation.

Molecular characterization of the largest subunit of Plasmodium falciparum RNA polymerase I

Plasmodium species possess developmentally regulated ribosomal RNA (rRNA) genes. This report describes the expression and gene structure of the largest subunit of P. falciparum RNA polymerase I (RNAPI), which is responsible for the synthesis of rRNA. The RNAPI largest subunit gene was present as a single copy gene on chromosome 9. Three exons encode the 2910-amino acid RNAPI polypeptide (340 140 Da). A comparison of Plasmodium, Trypanosoma, and Saccharomyces cerevisiae nuclear RNAP largest subunits identified conserved amino acid positions and class-specific amino acid positions. Novel amino acid insertions were found between RNAPI conserved regions A and B (region A'), D and DE1 (region D'), DE2 and E (region DE2'), and F and G (region F'). Leucine zipper domains were found within regions D', DE2, and DE2'. A novel serine-rich repeat domain, a domain with homology to the C-terminal domain of eukaryotic upstream binding factor (UBF), and 4 highly conserved casein kinase II (CKII) Ser/Thr phosphorylation motifs were found within a 127-amino acid sub-region of enlarged region F'. The novel RNAPI serine-rich repeat contained a conserved motif, Ser-X3-Ser, which was also identified in the serine-rich repeat domains of the P. falciparum RNAPII and RNAPIII largest subunits, as well as within a highly homologous serine-rich repeat from trophozoite antigen R45. The results of this molecular analysis indicate that phosphorylation and dephosphorylation mechanisms regulate the activity of P. falciparum RNAPI.

Homologous domains of the largest subunit of eucaryotic RNA polymerase II are conserved in plants

Genomic and cDNA clones homologous to the RpII215 gene of Drosophila were isolated from Arabidopsis thaliana and assigned to a single copy gene encoding a transcript of 6.8 kb. Nucleotide sequence analysis of Arabidopsis genomic and cDNAs revealed a striking homology to yeast, Caenorhabditis, Drosophila and mouse genes encoding the largest subunit of RNA polymerase II. The Arabidopsis gene rpII215 contains 13 introns, 12 of which interrupt the coding sequence of a protein of 205 kDa. The position of the first intron is conserved between plant and animal genes, while an intron located in the 3' untranslated region of the rpII215 gene is unique to Arabidopsis. Common domains present in all known largest subunits of eucaryotic RNA polymerase II were identified in the predicted sequence of the Arabidopsis RpII215 protein. Both the order and the position of N-terminal Zn2+ finger and of DNA and alpha-amanitin binding motifs are conserved in Arabidopsis. The C-terminal region of the Arabidopsis protein contains 15 consensus and 26 variant YSPTSPS repeats (CTDs). Highly conserved structure among the various C-terminal domains suggests that the largest subunit of RNA polymerase II in plants may also interact with transcription factors and with protein kinases that control the cell cycle as in other organisms.

A 7 bp mutation converts a human RNA polymerase II snRNA promoter into an RNA polymerase III promoter

The human U2 snRNA promoter directs the formation of a specialized RNA polymerase II transcription complex that recognizes the snRNA gene 3' box as a signal for RNA 3' end formation. In contrast, the human U6 promoter is recognized by RNA polymerase III and transcription terminates in a run of Ts. We show that transcription from the U6 promoter is dependent on a sequence similar to the U2 proximal element and on an AT-rich element centered around position -27. Mutation of the AT-rich element induces RNA polymerase II transcription from the U6 promoter, whereas insertion of this element within the U2 promoter converts it into a predominantly RNA polymerase III promoter. The site of transcription termination always correlates with the nature of the transcribing polymerase: the 3' box with RNA polymerase II and a run of Ts with RNA polymerase III. Thus, a single element determines the RNA polymerase specificity of snRNA promoters and hence the site of transcription termination.

In trypanosomes the homolog of the largest subunit of RNA polymerase II is encoded by two genes and has a highly unusual C-terminal domain structure

We have isolated the genes encoding the largest subunit of all three classes of RNA polymerase from Trypanosoma brucei. While the pol II largest subunit is encoded by a single gene in all organisms examined to date, trypanosomes contain two copies of the gene. Both genes are expressed in the procyclic and bloodstream stages of the trypanosome life cycle. The two pol II genes differ from one another in their coding sequences by 21 silent substitutions and 4 amino acid substitutions. In the core part of the large subunit, the predicted polypeptides are similar to other eukaryotic RNA polymerases. Both trypanosome pol II polypeptides, like those of other eukaryotes, also have a unique C-terminal extension. However, this domain in the trypanosome polypeptides, unlike those of other eukaryotes, is not a tandemly repeated heptapeptide sequence.

Sequence, organization, transcription and evolution of RNA polymerase subunit genes from the archaebacterial extreme halophiles Halobacterium halobium and Halococcus morrhuae

The genes for the four largest subunits, A, B', B" and C, of the DNA-dependent RNA polymerase were cloned from the extreme halophile Halobacterium halobium and sequenced and their transcription was analyzed. The downstream half of this gene cluster from another extreme halophile Halococcus morrhuae was also cloned, sequenced and its transcription products characterized. The H. halobium genes were transcribed into a common transcript from an upstream promoter in the order B", B', A and C. They are flanked by, and co-transcribed with, two smaller genes coding for 75 and 139 amino acid residues, respectively. Immediately downstream from these genes were two open reading frames that are homologous to ribosomal proteins S12 and S7 from Escherichia coli. In both extreme halophiles these genes were transcribed from their own promoter, but in Hc. morrhuae there was also considerable read-through from the RNA polymerase genes. Sequence alignment studies showed that the combined B" + B' subunits are equivalent to the B subunits of the eukaryotic polymerases I and II and to the eubacterial beta subunit, while the combined A + C subunits correspond to the A subunits of eukaryotic RNA polymerases I, II and III and to the eubacterial beta' subunit. The sequence similarity to the eukaryotic subunits was always much higher than to the eubacterial subunits. Conserved sequence regions within the individual subunits were located which are likely to constitute functionally important domains; they include sites associated with rifampicin and alpha-amanitin binding and two possible zinc binding fingers. Phylogenetic analyses based on sequence alignments confirmed that the extreme halophiles belong to the archaebacterial kingdom.

Analysis of the gene encoding the largest subunit of RNA polymerase II in Drosophila

We have characterized RpII215, the gene encoding the largest subunit of RNA polymerase II in Drosophila melanogaster. DNA sequencing and nuclease S1 analyses provided the primary structure of this gene, its 7 kb RNA and 215 kDa protein products. The amino-terminal 80% of the subunit harbors regions with strong homology to the beta' subunit of Escherichia coli RNA polymerase and to the largest subunits of other eukaryotic RNA polymerases. The carboxyl-terminal 20% of the subunit is composed of multiple repeats of a seven amino acid consensus sequence, Tyr-Ser-Pro-Thr-Ser-Pro-Ser. The homology domains, as well as the unique carboxyl-terminal structure, are considered in the light of current knowledge of RNA polymerase II and the properties of its largest subunit. Additionally, germline transformation demonstrated that a 9.4 kb genomic DNA segment containing the alpha-amanitin-resistant allele, RpII215C4, includes all sequences required to produce amanitin-resistant transformants.

The role of the host cell nucleus in vaccinia virus morphogenesis

Despite the fact that cells infected with wild type vaccinia virus synthesize viral DNA and assemble progeny virus particles within the cytoplasm, the host cell nucleus is required for a productive infection. Recent evidence suggests that vaccinia virus selectively recruits components from the host cell nucleus into the cytoplasm for use by the developing virus. One of these components is the largest subunit of the cellular RNA polymerase II (Pol II).