A unique structure at the carboxyl terminus of the largest subunit of eukaryotic RNA polymerase II

Rice chloroplast RNA polymerase genes: the absence of an intron in rpoC1 and the presence of an extra sequence in rpoC2

The chloroplast genome contains sequences homologous to the Escherichia coli rpoA, rpoB and rpoC genes. The chloroplast rpoC gene is divided into rpoC1 and rpoC2, of which rpoC1 contains an intron. Comparison of the rice rpo genes with those from tobacco, spinach and liverwort revealed unique features of the rice genes; the lack of an intron in rpoC1 and the presence of an extra sequence of 381 bp in rpoC2. The intron in rpoC1 is thus optional, and possible intron boundary sites in split rpoC1 genes can be estimated by comparison with rice rpoC1. The extra sequence is located in the middle of rpoC2 and has repeated structures. The amino acid sequence deduced from this sequence is extremely hydrophilic and anionic. The origin and function of this sequence are discussed.

The Euglena gracilis chloroplast rpoB gene. Novel gene organization and transcription of the RNA polymerase subunit operon

The rpoB gene coding for a beta-like subunit of the chloroplast DNA-dependent RNA polymerase has been located on the chloroplast genome of Euglena gracilis distal to the rrnC ribosomal RNA operon. We have determined 5760 base-pairs of DNA sequence, including 97 bp of the 5S rRNA gene, an intergenic spacer of 1264 bp, the rpoB gene of 4249 bp, 84 bp spacer and 67 bp of the rpoC1 gene. The rpoB gene is of the same polarity as the rRNA operons. The organization of the rpoB and rpoC genes resembles the E. coli rpoB-rpoC and higher plant chloroplast rpoB-rpoC1-rpoC2 operons. The Euglena rpoB gene (1082 codons) encodes a polypeptide with a predicted molecular weight of 124,288. The rpoB gene is interrupted by seven Group III introns of 93, 95, 94, 99, 101, 110 and 99 bp respectively and a Group II intron of 309 bp. All other known rpoB genes lack introns. All the exon-exon junctions were experimentally determined by cDNA cloning and sequencing or direct primer extension RNA sequencing. Transcripts from the rpoB locus were characterized by Northern hybridization. Fully-spliced, monocistronic rpoB mRNA, as well as rpoB-rpoC1 and rpoB1-rpoC1-rpoC2 mRNAs were identified.

The heptad repeat in the largest subunit of RNA polymerase II binds by intercalating into DNA

A TANDEM repeat of the sequence Ser-Pro-Thr-Ser-Pro-Ser-Tyr has been found at the C terminus in the largest subunit of RNA polymerase II (refs 1-5) with, for example, 26 units in yeast and 52 in mammals. By removal of this 'tail', it has been shown that 11-23 units are necessary for the normal functioning of the polymerase. The functional role of the repeat is however, unclear, although it has been proposed that it binds to transcription factors. As discussed in an earlier paper, the repeat unit contains two Ser-Pro sequences which seem to be related to a DNA-binding unit found in histones, Ser-Pro-Lys-Lys, and to the Ser-Pro-X-X motif which is often found in gene regulatory proteins and which, it has been proposed, is also a DNA-binding unit. Here, I show that the repeat does indeed bind DNA and present evidence that it does so by the intercalation of tyrosine residues. These experiments involved synthetic peptides containing one or two repeat units. As the sequence Ser-Pro-X-X (where X represents any amino acid) has a strong tendency to assume a special beta-turn, a model of the unit composed of two such beta-turns was made and compared with the structure of the drug Triostin A which is known to intercalate into DNA. Two tyrosine side chains of the repeat overlap well with two quinoxaline rings of the drug and therefore, the model can provide a good explanation of the experimental results.

Cerebellar degeneration-related antigen: a highly conserved neuroectodermal marker mapped to chromosomes X in human and mouse

Cerebellar degeneration-related antigen (designated CDR34) was previously cloned by antibody screening of a cDNA library and was shown to be one of the target molecules recognized by autoantibodies in patients with paraneoplastic cerebellar degeneration. This molecule is distinctive in that it contains a tandem hexapeptide repetitive structure, presumably the basis for its high immunogenicity. In this study, we cloned the human CDR34 gene and proved that the entire repetitive sequence is encoded by a single exon without introns. We also showed that the nucleotide repeats are preserved only in the protein-coding sequences, suggesting evolutionary constraint in this region of the gene. Corresponding mouse cDNA clones were also isolated, which encoded a larger molecule with very similar hexapeptide repeating units. Comparison of the human and mouse repeats revealed a highly conserved Glu-Asp core in each unit, implicating the functional significance of this motif. Chromosomal mapping by somatic cell hybrid analysis mapped CDR34 to both human and mouse chromosomes X, and in situ hybridization further assigned CDR34 to human Xq24-q27.

Subunits shared by eukaryotic nuclear RNA polymerases

RNA polymerases I, II, and III share three subunits that are immunologically and biochemically indistinguishable. The Saccharomyces cerevisiae genes that encode these subunits (RPB5, RPB6, and RPB8) were isolated and sequenced, and their transcriptional start sites were deduced. RPB5 encodes a 25-kD protein, RPB6, an 18-kD protein, and RPB8, a 16-kD protein. These genes are single copy, reside on different chromosomes, and are essential for viability. The fact that the genes are single copy, corroborates previous evidence suggesting that each of the common subunits is identical in RNA polymerases I, II, and III. Furthermore, immunoprecipitation of RPB6 coprecipitates proteins whose sizes are consistent with RNA polymerase I, II, and III subunits. Sequence similarity between the yeast RPB5 protein and a previously characterized human RNA polymerase subunit demonstrates that the common subunits of the nuclear RNA polymerases are well conserved among eukaryotes. The presence of these conserved and essential subunits in all three nuclear RNA polymerases and the absence of recognizable sequence motifs for DNA and nucleoside triphosphate-binding indicate that the common subunits do not have a catalytic role but are important for a function shared by the RNA polymerases such as transcriptional efficiency, nuclear localization, enzyme stability, or coordinate regulation of rRNA, mRNA, and tRNA synthesis.

The C-terminal domain of the largest subunit of RNA polymerase II and transcription initiation

Monoclonal antibodies specific for the evolutionarily conserved C-terminal heptapeptide repeat domain of the largest subunit of RNA polymerase II inhibited the initiation of transcription from mammalian promoters in vitro. Since these antibodies did not inhibit elongation and randomly initiated transcription, the heptapeptide repeats may function by binding class II transcription initiation factor(s).

Polyproline, beta-turn helices. Novel secondary structures proposed for the tandem repeats within rhodopsin, synaptophysin, synexin, gliadin, RNA polymerase II, hordein, and gluten

Seven proteins each contain 8 to 52 tandem repeats of a unique class of oligopeptide. The consensus peptide for each is rhodopsin Tyr Pro Pro Gln Gly synaptophysin Tyr Gly Pro Gln Gly synexin Tyr Pro Pro Pro Pro Gly gliadin Tyr Pro Pro Pro Gln Pro RNA polymerase II Tyr Ser Pro Thr Ser Pro Ser hordein Phe Pro Gln Gln Pro Gln Gln Pro gluten Tyr Pro Thr Ser Pro Gln Gln Gly Tyr Although there is obvious variation of sequence and of length, the penta- to nonapeptides share an initial Tyr (or Phe) and have high Pro contents and abundant Gly, Gln, and Ser. We have evaluated helical models that both recognize the uniqueness of these sequence repeats and accommodate variations on the basic theme. We have developed a group of related helical models for these proteins with about three oligopeptide repeats per turn of 10-20 A. These models share several common features: Most of the phi dihedral angles are -54 degrees, to accommodate Pro at all positions except the first (Tyr). Except for the beta-turns, most psi dihedral angles are near +140 degrees as found in polyproline. Each oligopeptide has at least one beta-turn; several have two. Some contain a cis-Tyr, Pro peptide bond; a few have a cis-bond plus one beta-turn. Tyr side chains vary from totally exposed to buried within the helices and could move to accommodate either external hydrophobic interactions or phosphorylation. The several related structures seem to be readily interconverted without major change in the overall helical parameters, and therein may lie the key to their functions.

Molecular cloning and sequencing of ama-1, the gene encoding the largest subunit of Caenorhabditis elegans RNA polymerase II

Two genomic sequences that share homology with Rp11215, the gene encoding the largest subunit of RNA polymerase II in Drosophila melanogaster, have been isolated from the nematode Caenorhabditis elegans. One of these sequences was physically mapped on chromosome IV within a region deleted by the deficiency mDf4, 25 kilobases (kb) from the left deficiency breakpoint. This position corresponds to ama-1 (resistance to alpha-amanitin), a gene shown previously to encode a subunit of RNA polymerase II. Northern (RNA) blotting and DNA sequencing revealed that ama-1 spans 10 kb, is punctuated by 11 introns, and encodes a 5.9-kb mRNA. A cDNA clone was isolated and partially sequenced to confirm the 3' end and several splice junctions. Analysis of the inferred 1,859-residue ama-1 product showed considerable identity with the largest subunit of RNAP II from other organisms, including the presence of a zinc finger motif near the amino terminus, and a carboxyl-terminal domain of 42 tandemly reiterated heptamers with the consensus Tyr Ser Pro Thr Ser Pro Ser. The latter domain was found to be encoded by four exons. In addition, the sequence oriented ama-1 transcription with respect to the genetic map. The second C. elegans sequence detected with the Drosophila probe, named rpc-1, was found to encode a 4.8-kb transcript and hybridized strongly to the gene encoding the largest subunit of RNA polymerase III from yeast, implicating rpc-1 as encoding the analogous peptide in the nematode. By contrast with ama-1, rpc-1 was not deleted by mDf4 or larger deficiencies examined, indicating that these genes are no closer than 150 kb. Genes flanking ama-1, including two collagen genes, also have been identified.

An enlarged largest subunit of Plasmodium falciparum RNA polymerase II defines conserved and variable RNA polymerase domains

We have isolated the gene encoding the largest subunit of RNA polymerase II from Plasmodium falciparum. The RPII gene is expressed in the asexual erythrocytic stages of the parasite as a 9 kb mRNA, and is present as a single copy gene located on chromosome 3. The P. falciparum RPII subunit is the largest (2452 amino acids) eukaryotic RPII subunit, and it contains enlarged variable regions that clearly separate and define five conserved regions of the eukaryotic RPII largest subunits. A distinctive carboxyl-terminal domain contains a short highly conserved heptapeptide repeat domain which is bounded on its 5' side by a highly diverged heptapeptide repeat domain, and is bounded on its 3' side by a long carboxyl-terminal extension.

The C-terminal domain of the largest subunit of RNA polymerase II and transcription initiation

Monoclonal antibodies specific for the evolutionarily conserved C-terminal heptapeptide repeat domain of the largest subunit of RNA polymerase II inhibited the initiation of transcription from mammalian promoters in vitro. Since these antibodies did not inhibit elongation and randomly initiated transcription, the heptapeptide repeats may function by binding class II transcription initiation factor(s).

Intragenic and extragenic suppressors of mutations in the heptapeptide repeat domain of Saccharomyces cerevisiae RNA polymerase II

The largest subunit of RNA polymerase II contains a repeated heptapeptide sequence at its carboxy terminus. Yeast mutants with certain partial deletions of the carboxy-terminal repeat (CTR) domain are temperature-sensitive, cold-sensitive and are inositol auxotrophs. Intragenic and extragenic suppressors of the cold-sensitive phenotype of CTR domain deletion mutants were isolated and studied to investigate the function of this domain. Two types of intragenic suppressing mutations suppress the temperature-sensitivity, cold-sensitivity and inositol auxotrophy of CTR domain deletion mutants. Most intragenic mutations enlarge the repeat domain by duplicating various portions of the repeat coding sequence. Other intragenic suppressing mutations are point mutations in a conserved segment of the large subunit. An extragenic suppressing mutation (SRB2-1) was isolated that strongly suppresses the conditional and auxotrophic phenotypes of CTR domain mutations. The SRB2 gene was isolated and mapped, and an SRB2 partial deletion mutation (srb2 delta 10) was constructed. The srb2 delta 10 mutants are temperature-sensitive, cold-sensitive and are inositol auxotrophs. These phenotypes are characteristic of mutations in genes encoding components of the transcription apparatus. We propose that the SRB2 gene encodes a factor that is involved in RNA synthesis and may interact with the CTR domain of the large subunit of RNA polymerase II.

Identification of a yeast protein homologous in function to the mammalian general transcription factor, TFIIA

The yeast homolog of the mammalian RNA polymerase II general transcription factor TFIIA has been identified by complementation of a mammalian in vitro transcription system depleted for TFIIA. Like the mammalian factor, the yeast protein does not bind DNA, alters the size of the TFIID DNase I footprint at the adenovirus major late promoter, and forms specific TFIIA-TFIID-DNA complexes which are stable during electrophoresis in native acrylamide gels. The partially purified yeast factor was used to investigate its effect on the binding of TFIID to the major late promoter. Contrary to earlier models, we find that TFIIA does not significantly change the affinity or kinetics of TFIID binding, suggesting that it acts by altering the conformation of TFIID and/or by serving as a bridge between TFIID and the other general transcription factors.

The evolutionary conservation of eukaryotic gene transcription

The basic components required for eukaryotic gene transcription have been highly conserved in evolution. Structural and functional homology has now been documented among promoters, promoter factors, regulatory proteins, and RNA polymerases from eukaryotes as diverse as yeast and mammals. The ability of these proteins and DNA sequences to function across phylogenetic boundaries demonstrates that common molecular mechanisms underlie gene control in all eukaryotic cells, and provides the basis for powerful new approaches to the study of eukaryotic gene transcription.

Molecular cloning and sequencing of ama-1, the gene encoding the largest subunit of Caenorhabditis elegans RNA polymerase II

Two genomic sequences that share homology with Rp11215, the gene encoding the largest subunit of RNA polymerase II in Drosophila melanogaster, have been isolated from the nematode Caenorhabditis elegans. One of these sequences was physically mapped on chromosome IV within a region deleted by the deficiency mDf4, 25 kilobases (kb) from the left deficiency breakpoint. This position corresponds to ama-1 (resistance to alpha-amanitin), a gene shown previously to encode a subunit of RNA polymerase II. Northern (RNA) blotting and DNA sequencing revealed that ama-1 spans 10 kb, is punctuated by 11 introns, and encodes a 5.9-kb mRNA. A cDNA clone was isolated and partially sequenced to confirm the 3' end and several splice junctions. Analysis of the inferred 1,859-residue ama-1 product showed considerable identity with the largest subunit of RNAP II from other organisms, including the presence of a zinc finger motif near the amino terminus, and a carboxyl-terminal domain of 42 tandemly reiterated heptamers with the consensus Tyr Ser Pro Thr Ser Pro Ser. The latter domain was found to be encoded by four exons. In addition, the sequence oriented ama-1 transcription with respect to the genetic map. The second C. elegans sequence detected with the Drosophila probe, named rpc-1, was found to encode a 4.8-kb transcript and hybridized strongly to the gene encoding the largest subunit of RNA polymerase III from yeast, implicating rpc-1 as encoding the analogous peptide in the nematode. By contrast with ama-1, rpc-1 was not deleted by mDf4 or larger deficiencies examined, indicating that these genes are no closer than 150 kb. Genes flanking ama-1, including two collagen genes, also have been identified.

Modification of an adenovirus major late promoter-binding factor during poliovirus infection

To further characterize the mechanism involved in poliovirus-induced inhibition of HeLa cells mRNA synthesis, in vitro formation of DNA-protein complexes between nuclear upstream stimulatory transcription factor (USF) and the adenovirus type 2 major late promoter upstream promoter element (UPE; located between -45 and -65 base pairs) was studied. Using the gel shift assay, we found differences between the UPE-protein complex formed with partially purified nuclear extracts from poliovirus-infected HeLa cells and that obtained in the presence of mock-infected extracts. Formation of the modified UPE-USF complex coincided with virus-induced inhibition of host cell RNA synthesis in vivo and with a less efficient in vitro transcriptional activity of the nuclear extracts from infected cells. Furthermore, using a cross-linking protocol, we found that the host 46-kilodalton UPE-binding USF factor was severely diminished and that a virus-induced or -modified 50-kilodalton polypeptide appeared to be specifically bound to the UPE template.

A protein kinase from wheat germ that phosphorylates the largest subunit of RNA polymerase II

A protein kinase from wheat germ that phosphorylates the largest subunit of RNA polymerase IIA has been partially purified and characterized. The kinase has a native molecular weight of about 200 kilodaltons. This kinase utilizes Mg2+ and ATP and transfers about 20 phosphates to the heptapeptide repeats Pro-Thr-Ser-Pro-Ser-Tyr-Ser in the carboxyl-terminal domain of the 220-kilodalton subunit of soybean RNA polymerase II. This phosphorylation results in a mobility shift of the 220-kilodalton subunits of a variety of eukaryotic RNA polymerases to polypeptides ranging in size from greater than 220 kilodaltons to 240 kilodaltons on sodium dodecyl sulfate-polyacrylamide gels. The phosphorylation is highly specific to the heptapeptide repeats since a degraded subunit polypeptide of 180 kilodaltons that lacks the heptapeptide repeats is poorly phosphorylated. Synthetic heptapeptide repeat multimers inhibit the phosphorylation of the 220-kilodalton subunit.

Phosphorylation of RNA polymerase by the murine homologue of the cell-cycle control protein cdc2

Actively transcribing eukaryotic RNA polymerase II is highly phosphorylated on its repetitive carboxyl-terminal domain. We have isolated a protein kinase that phosphorylates serine residues in this repetitive domain. A component of this kinase is cdc2, the product of a cell-cycle control gene previously shown to be a component of M-phase-promoting factor and M-phase-specific histone H1 kinase. This observation suggests a role for the cdc2 protein kinase in transcriptional regulation.

Archaebacterial DNA-dependent RNA polymerases testify to the evolution of the eukaryotic nuclear genome

Genes for DNA-dependent RNA polymerase components B, A, and C from the archaebacterium Sulfolobus acidocaldarius and for components B", B', A, and C from the archaebacterium Halobacterium halobium were cloned and sequenced. They are organized in gene clusters in the order above, which corresponds to the order of the homologous rpoB and rpoC genes in the corresponding operon of the Escherichia coli genome. Derived amino acid sequences of archaebacterial components A and C were aligned with each other and with the sequences of corresponding (largest) subunits from the archaebacterium Methanobacterium thermoautotrophicum, with sequences of various eukaryotic nuclear RNA polymerases I, II, and III, and with the sequence of the beta' component from E. coli polymerase. The archaebacterial genes for component A are homologous to about the first two-thirds of genes for the eukaryotic component A and the eubacterial component beta', and the archaebacterial genes for component C are homologous to the last third of the genes for the eukaryotic component A and the eubacterial component beta'. Unrooted phylogenetic dendrograms derived from both distance matrix and parsimony analyses show the archaebacteria are a coherent group closely related to the eukaryotic nuclear RNA polymerase II and/or III lineages. The eukaryotic polymerase I lineage appears to arise separately from a bifurcation with the eubacterial beta' component lineage.

Unusual C-terminal domain of the largest subunit of RNA polymerase II of Crithidia fasciculata

The C-terminal domain of the largest subunit of RNA polymerase II in higher eukaryotes is present in the protozoan parasite Trypanosoma brucei in a strongly modified form. To determine whether this is a general feature of the Kinetoplastida and to determine the role of this domain in RNA polymerase II transcription, we have analysed the C-terminal domain of the distantly related species Crithidia fasciculata. No positional identity of amino acid residues between the C-termini of C. fasciculata and T. brucei can be found. Moreover, both domains lack the heptapeptide repeat structure present in higher eukaryotes. The two domains are, however, very similar in amino acid composition, being rich in acidic residues as well as serine and tryosine. The latter observation is compatible with the concept that in vivo phosphorylation of the C-terminus activates RNA polymerase II.

A protein kinase that phosphorylates the C-terminal repeat domain of the largest subunit of RNA polymerase II

The unique C-terminal repeat domain (CTD) of the largest subunit (IIa) of eukaryotic RNA polymerase II consists of multiple repeats of the heptapeptide consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. The number of repeats ranges from 26 in yeast to 42 in Drosophila to 52 in mouse. The CTD is essential in vivo, but its structure and function are not yet understood. The CTD can be phosphorylated at multiple serine and threonine residues, generating a form of the largest subunit (II0) with markedly reduced mobility in NaDodSO4/polyacrylamide gels. To investigate this extensive phosphorylation, which presumably modulates functional properties of RNA polymerase II, we began efforts to purify a specific CTD kinase. Using CTD-containing fusion proteins as substrates, we have purified a CTD kinase from the yeast Saccharomyces cerevisiae. The enzyme extensively phosphorylates the CTD portion of both the fusion proteins and intact subunit IIa, producing products with reduced electrophoretic mobilities. The properties of the CTD kinase suggest that it is distinct from previously described protein kinases. Analogous activities were also detected in Drosophila and HeLa cell extracts.

Mutations in RNA polymerase II enhance or suppress mutations in GAL4

The activation domains of eukaryotic DNA-binding transcription factors, such as GAL4, may regulate transcription by contacting RNA polymerase II. One potential site on RNA polymerase II for such interactions is the C-terminal tandemly repeated heptapeptide domain in the largest subunit (RPO21). We have changed the number of heptapeptide repeats in this yeast RPO21 C-terminal domain and have expressed these mutant RNA polymerase II polypeptides in yeast cells containing either wild-type or defective GAL4 proteins. Although the number of RPO21 heptapeptide repeats had no effect on the activity of wild-type GAL4, changing the length of the C-terminal domain modified the ability of mutant GAL4 proteins to activate transcription. Shorter or longer RPO21 C-terminal domains enhanced or partially suppressed, respectively, the effects of deletions in the transcriptional-activation domains of GAL4. The same RPO21 mutations also affected transcriptional activation by a GAL4-GCN4 chimera. These data suggest that the activation domains of DNA-binding transcription factors could interact, either directly or indirectly, with the heptapeptide repeats of RNA polymerase II.

Transcription elongation factor SII interacts with a domain of the large subunit of human RNA polymerase II

Genomic sequences for the large subunit of human RNA polymerase II corresponding to a part of the fifth exon were inserted into an expression vector at the carboxy-terminal end of the beta-galactosidase gene. The in-frame construct produced a 125-kilodalton fusion protein, containing approximately 10 kilodaltons of the large subunit of RNA polymerase II and 116 kilodaltons of beta-galactosidase. The purified bacterially produced fusion protein inhibited specific transcription from the adenovirus type 2 major late promoter, while beta-galactosidase had no effect. This effect of the fusion protein was during RNA elongation, not at the level of initiation, resembling the faithfully initiated but incomplete transcripts produced with purified factors in the absence of SII. Similarly, monoclonal antibody 2-7B, which reacts with the RNA polymerase II region represented in the fusion protein, inhibited specific transcription at the level of elongation in a whole-cell extract. Both monoclonal antibody 2-7B and the fusion protein, although unable to inhibit purified RNA polymerase II in a nonspecific transcription assay, selectively blocked the stimulation elicited by transcription elongation factor SII on the activity of the purified enzyme in vitro. This suggests that the fusion protein traps the SII in nonstimulatory interactions and that antibody 2-7B inhibits SII binding to RNA polymerase II. Thus, this suggests that an SII-binding contact required for specific RNA elongation resides within the fifth exon region of the largest RNA polymerase II subunit.

Essential roles of the RNA polymerase I largest subunit and DNA topoisomerases in the formation of fission yeast nucleolus

A temperature-sensitive lethal mutant nuc1-632 of Schizosaccharomyces pombe shows marked reduction in macromolecular synthesis and a defective nuclear phenotype with an aberrant nucleolus, indicating a structural role of the nuc1+ gene product in nucleolar organization. We cloned the nuc1+ gene by transformation and found that it appears to encode the largest subunit of RNA polymerase I. We raised antisera against nuc1+ fusion polypeptides and detected a polypeptide (approximately 190 kD and 2 x 10(4) copies/cell) in the S. pombe nuclear fraction. By immunofluorescence microscopy, anti-nuc1+ antibody revealed intense staining at a particular nuclear domain previously defined as the nucleolus. The nucleolar immunofluorescence by anti-nuc1+ was faded in nuc1-632 at restrictive temperature and dramatically diminished in the absence of DNA topoisomerases I and II. Thus active RNA polymerase I appears to be required for the formation of the nucleolus as its major component, and DNA topoisomerases appear to be required for the folding of rDNA and RNA polymerase I molecules into the functional organization of nucleolar genes.

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.

Structure and sequence of the gene for the largest subunit of trypanosomal RNA polymerase III

As the first step in the analysis of the transcription process in the African trypanosome, Trypanosoma brucei, we have started to characterise the trypanosomal RNA polymerases. We have previously described the gene encoding the largest subunit of RNA polymerase II and found that two almost identical RNA polymerase II genes are encoded within the genome of T. brucei. Here we present the identification, cloning and sequence analysis of the gene encoding the largest subunit of RNA polymerase III. This gene contains a single open reading frame encoding a polypeptide with a Mr of 170 kD. In total, eight encoding a polypeptide with a Mr of 170 kD. In total, eight highly conserved regions with significant homology to those previously reported in other eukaryotic RNA polymerase largest subunits were identified. Some of these domains contain functional sites, which are conserved among all eukaryotic largest subunit genes analysed thus far. Since these domains make up a large part of each polypeptide, independent of the RNA polymerase class, these data strongly support the hypothesis that these domains provide a major part of the transcription machinery of the RNA polymerase complex. The additional domains which are uniquely present in the largest subunit of RNA polymerase I and II, respectively, two large hydrophylic insertions and a C-terminal extension, might be a determining factor in specific transcription of the gene classes.

Transcription elongation factor SII interacts with a domain of the large subunit of human RNA polymerase II

Genomic sequences for the large subunit of human RNA polymerase II corresponding to a part of the fifth exon were inserted into an expression vector at the carboxy-terminal end of the beta-galactosidase gene. The in-frame construct produced a 125-kilodalton fusion protein, containing approximately 10 kilodaltons of the large subunit of RNA polymerase II and 116 kilodaltons of beta-galactosidase. The purified bacterially produced fusion protein inhibited specific transcription from the adenovirus type 2 major late promoter, while beta-galactosidase had no effect. This effect of the fusion protein was during RNA elongation, not at the level of initiation, resembling the faithfully initiated but incomplete transcripts produced with purified factors in the absence of SII. Similarly, monoclonal antibody 2-7B, which reacts with the RNA polymerase II region represented in the fusion protein, inhibited specific transcription at the level of elongation in a whole-cell extract. Both monoclonal antibody 2-7B and the fusion protein, although unable to inhibit purified RNA polymerase II in a nonspecific transcription assay, selectively blocked the stimulation elicited by transcription elongation factor SII on the activity of the purified enzyme in vitro. This suggests that the fusion protein traps the SII in nonstimulatory interactions and that antibody 2-7B inhibits SII binding to RNA polymerase II. Thus, this suggests that an SII-binding contact required for specific RNA elongation resides within the fifth exon region of the largest RNA polymerase II subunit.

On the early evolution of RNA polymerase

The lines of evidence suggesting that RNA preceded double-stranded DNA as an informational macromolecule are briefly reviewed. RNA polymerase is hypothesized to have been one of the earliest proteins to appear. It is argued that an important vestige of the original enzyme is found in the contemporary eubacterial beta' subunit of DNA-dependent RNA polymerase and its homologues among the archaebacterial and eukaryotic enzymes. The evidence that supports a catalytic role in replicase activity of this polypeptide is reviewed. It is suggested that several characteristics of the Escherichia coli transcriptional apparatus are relatively recent evolutionary developments. The phylogenetic importance of the eubacterial beta' subunit from RNA polymerase and its homologues is emphasized, because it allows the study of the evolutionary relationships of the major cellular lines (eubacteria, archaebacteria, and eukaryotes) as well as of some viral lineages.

Function of a yeast TATA element-binding protein in a mammalian transcription system

Saccharomyces cerevisiae contains a protein which is functionally similar to the mammalian TATA element-binding transcription factor, TFIID. The yeast factor substitutes for TFIID in a mammalian RNA polymerase II in vitro transcription system, forms a stable preinitiation complex on the Adenovirus-2 major late promoter, and binds specifically to the TATA boxes of the viral promoter and the yeast CYC1 promoter. Interestingly, the yeast factor promotes initiation at a distance from the TATA element typical of a mammalian system.

Two mouse genes encoding potential transcription factors with identical DNA-binding domains are activated by growth factors in cultured cells

We previously reported the identification of a mouse gene, Krox-20, encoding a protein with three "zinc fingers" (DNA-binding domains with coordinated zinc ions) whose expression is regulated during G0/G1 transition (cell-cycle reentry). We now have isolated cDNAs corresponding to a related gene, Krox-24. Krox-24 encodes a protein with zinc fingers nearly identical to those encoded by Krox-20 and similar to those of transcription factor Sp1. Similarity between Krox-20 and Krox-24 proteins also extends to several blocks of amino acid sequence located upstream of the finger region. Like Krox-20, Krox-24 is transiently activated in quiescent cells after treatment with fetal bovine serum or purified growth factors. The kinetics of activation are similar to those of the protooncogene c-fos. The induction does not require de novo protein synthesis, and cycloheximide treatment of the cells leads to superinduction due, at least in part, to mRNA stabilization. In the mouse, the two genes are expressed in a tissue-specific manner, with slightly different patterns. These properties suggest that Krox-20 and Krox-24 may encode transcription factors with identical DNA target sequences and that these factors may be involved in the modulation of cell proliferation and differentiation.

The C-terminal repeat domain of RNA polymerase II largest subunit is essential in vivo but is not required for accurate transcription initiation in vitro

DNA sequence analysis of RpII215, the gene that encodes the Mr215,000 subunit of RNA polymerase II (EC 2.7.7.6) in Drosophila melanogaster, reveals that the 3'-terminal exon includes a region encoding a C-terminal domain composed of 42 repeats of a seven-residue amino acid consensus sequence, Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A hemi- and homozygous lethal P-element insertion into the coding sequence of this domain causes premature translation termination and therefore truncation of the protein, leaving only 20 heptamer repeats. While loss of approximately 50% of the repeat structure in this mutant is a lethal event in vivo, enzyme containing the truncated subunit remains capable of accurate initiation at promoters in vitro. Moreover, treatment of purified intact RNA polymerase II with protease, to remove the entire repeat domain, does not eliminate the enzyme's ability to initiate accurately in vitro. Possible in vivo functions for this unusual protein domain are considered in light of these results.

The C-terminal domain of the largest subunit of RNA polymerase II of Saccharomyces cerevisiae, Drosophila melanogaster, and mammals: a conserved structure with an essential function

Using DNA encoding the largest subunit of Drosophila melanogaster RNA polymerase II, we isolated the homologous hamster RPO21 gene. Nucleotide sequencing of both the hamster and D. melanogaster RPO21 DNAs confirmed that the RPO21 polypeptides of these two species, like the Saccharomyces cerevisiae RPO21 polypeptide, contain both an N-terminal region homologous to the Escherichia coli RNA polymerase subunit beta' and a unique polymerase II-specific C-terminal domain. This C-terminal domain, encoded by separate exons in the D. melanogaster and hamster genes, consists of a tandemly repeated heptapeptide sequence. By constructing a series of deletions in DNA encoding the 26 heptapeptide repeats normally present in the S. cerevisiae RPO21 polypeptide, we have established that a minimum of between 9 and 11 repeats is necessary for RPO21 function in yeast cells. Replacement of the yeast RPO21 heptapeptide repeats by the longer hamster repetitive domain resulted in viable yeast cells with no detectable mutant phenotype, while a similar replacement of the yeast repeats by the more divergent D. melanogaster repeats was a recessive lethal mutation. We suggest that this novel repetitive domain is essential for proper initiation of transcription by RNA polymerase II and that it may mediate the functions of TATA boxes, upstream activating sequences, and enhancers.

Genetic analysis of the repetitive carboxyl-terminal domain of the largest subunit of mouse RNA polymerase II

The carboxyl-terminal domain (CTD) of the mouse RNA polymerase II largest subunit consists of 52 repeats of a seven-amino-acid block with the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A genetic approach was used to determine whether the CTD plays an essential role in RNA polymerase function. Deletion, insertion, and substitution mutations were created in the repetitive region of an alpha-amanitin-resistant largest-subunit gene. The effects of these mutations on RNA polymerase II activity were assayed by measuring the ability of mutant genes to confer alpha-amanitin resistance after transfection of susceptible rodent cells. Mutations that resulted in CTDs containing between 36 and 78 repeats had no effect on the transfer of alpha-amanitin resistance, whereas mutations with 25 or fewer repeats were inactive in this assay. Mutations that contained 29, 31, or 32 repeats had an intermediate effect; the number of alpha-amanitin-resistant colonies was lower and the colonies obtained were smaller, indicating that the mutant RNA polymerase II was defective. In addition, not all of the heptameric repeats were functionally equivalent in that repeats that diverged in up to three amino acids from the consensus sequence could not substitute for the conserved heptamer repeats. We concluded that the CTD is essential for RNA polymerase II activity, since substantial mutations in this region result in loss of function.

The C-terminal domain of the largest subunit of RNA polymerase II of Saccharomyces cerevisiae, Drosophila melanogaster, and mammals: a conserved structure with an essential function

Using DNA encoding the largest subunit of Drosophila melanogaster RNA polymerase II, we isolated the homologous hamster RPO21 gene. Nucleotide sequencing of both the hamster and D. melanogaster RPO21 DNAs confirmed that the RPO21 polypeptides of these two species, like the Saccharomyces cerevisiae RPO21 polypeptide, contain both an N-terminal region homologous to the Escherichia coli RNA polymerase subunit beta' and a unique polymerase II-specific C-terminal domain. This C-terminal domain, encoded by separate exons in the D. melanogaster and hamster genes, consists of a tandemly repeated heptapeptide sequence. By constructing a series of deletions in DNA encoding the 26 heptapeptide repeats normally present in the S. cerevisiae RPO21 polypeptide, we have established that a minimum of between 9 and 11 repeats is necessary for RPO21 function in yeast cells. Replacement of the yeast RPO21 heptapeptide repeats by the longer hamster repetitive domain resulted in viable yeast cells with no detectable mutant phenotype, while a similar replacement of the yeast repeats by the more divergent D. melanogaster repeats was a recessive lethal mutation. We suggest that this novel repetitive domain is essential for proper initiation of transcription by RNA polymerase II and that it may mediate the functions of TATA boxes, upstream activating sequences, and enhancers.

Genetic analysis of the repetitive carboxyl-terminal domain of the largest subunit of mouse RNA polymerase II

The carboxyl-terminal domain (CTD) of the mouse RNA polymerase II largest subunit consists of 52 repeats of a seven-amino-acid block with the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A genetic approach was used to determine whether the CTD plays an essential role in RNA polymerase function. Deletion, insertion, and substitution mutations were created in the repetitive region of an alpha-amanitin-resistant largest-subunit gene. The effects of these mutations on RNA polymerase II activity were assayed by measuring the ability of mutant genes to confer alpha-amanitin resistance after transfection of susceptible rodent cells. Mutations that resulted in CTDs containing between 36 and 78 repeats had no effect on the transfer of alpha-amanitin resistance, whereas mutations with 25 or fewer repeats were inactive in this assay. Mutations that contained 29, 31, or 32 repeats had an intermediate effect; the number of alpha-amanitin-resistant colonies was lower and the colonies obtained were smaller, indicating that the mutant RNA polymerase II was defective. In addition, not all of the heptameric repeats were functionally equivalent in that repeats that diverged in up to three amino acids from the consensus sequence could not substitute for the conserved heptamer repeats. We concluded that the CTD is essential for RNA polymerase II activity, since substantial mutations in this region result in loss of function.