Primary structure and functional aspects of the gene coding for the second-largest subunit of RNA polymerase III of Drosophila

Polytene Chromosomes: 70 Years of Genetic Research

Polytene chromosomes were described in 1881 and since 1934 they have served as an outstanding model for a variety of genetic experiments. Using the polytene chromosomes, numerous biological phenomena were discovered. First the polytene chromosomes served as a model of the interphase chromosomes in general. In polytene chromosomes, condensed (bands), decondensed (interbands), genetically active (puffs), and silent (pericentric and intercalary heterochromatin as well as regions subject to position effect variegation) regions were found and their features were described in detail. Analysis of the general organization of replication and transcription at the cytological level has become possible using polytene chromosomes. In studies of sequential puff formation it was found for the first time that the steroid hormone (ecdysone) exerts its action through gene activation, and that the process of gene activation upon ecdysone proceeds as a cascade. Namely on the polytene chromosomes a new phenomenon of cellular stress response (heat shock) was discovered. Subsequently chromatin boundaries (insulators) were discovered to flank the heat shock puffs. Major progress in solving the problems of dosage compensation and position effect variegation phenomena was mainly related to studies on polytene chromosomes. This review summarizes the current status of studies of polytene chromosomes and of various phenomena described using this successful model.

The second largest subunit of Trypanosoma brucei's multifunctional RNA polymerase I has a unique N-terminal extension domain

In the protist parasite Trypanosoma brucei, RNA polymerase (pol) I transcribes the large ribosomal RNA gene unit and, in addition, variant surface glycoprotein gene expression sites and procyclin gene transcription units. The multifunctional role of RNA pol I in this organism is unique among eukaryotes, but only its largest subunit TbRPA1 has been characterized thus far. We have recently established the procyclic cell line RPIC which exclusively expresses RNA pol I tagged with the protein C epitope at the TbRPA1 C-terminus. In the present study, we prepared RPIC cell extracts and immunopurified RNA pol I using anti-protein C affinity matrix under high stringency conditions. We were able to identify five specific polypeptides on a silver-stained polyacrylamide-SDS gel with apparent molecular weights of 200, 180, 55, 29, and 22 kDa. Interestingly, the second largest subunit, TbRPA2, is 42-58 kDa larger than counterparts of other organisms. We have cloned and sequenced the complete TbRPA2 cDNA and found an open reading frame for a polypeptide of 179.5 kDa. The deduced amino acid sequence of TbRPA2 contains a unique N-terminal domain of approximately 250 amino acids. By raising a polyclonal antibody against a N-terminal peptide sequence of TbRPA2, we could specifically detect this polypeptide in immunoblots showing that it co-purifies with epitope-tagged TbRPA1. Moreover, we identified the homologous gene sequence LmRPA2 in Leishmania major and found that it encodes a homologous extension domain. Therefore, the N-terminal extra domain in trypanosomatid RPA2 polypeptides may serve a parasite-specific function.

Discovery of paralogous nuclear gene sequences coding for the second-largest subunit of RNA polymerase II (RPB2) and their phylogenetic utility in gentianales of the asterids

Paralogous sequences of the RPB2 gene are demonstrated in the angiosperm order Gentianales. Two different copies were found by using different PCR primer pairs targeting a region that corresponds to exons 22-24 in the Arabidopsis RPB2 gene. One of the copies (RPB2-d) lacks introns in this region, whereas the other has introns at locations corresponding to those of green plants previously investigated. When analyzed with other available RPB2 sequences from this region, all 28 RPB2-d sequences obtained from the Gentianales and the four sequences from the Lamiales form a monophyletic group, together with a previously published tomato cDNA sequence. The substitution patterns, relative rates of change, and nucleotide compositions of the two paralogous RPB2 exon regions are similar, and none of them shows any signs of being a pseudogene. Although multiple copies of similar, paralogous sequences can confound phylogenetic interpretations, the lack of introns in RPB2-d make a priori homology assessment easy. The phylogenetic utility of RPB2-d within the Gentianales is evaluated in comparison with the chloroplast genes ndhF and rbcL. The hierarchical information in the RPB2-d region sequenced is more incongruent with that of the plastid genes than the plastid genes are with each other as determined by incongruence length difference tests. In contrast to the plastid genes, parsimony-informative third codon positions of RPB2 have a significantly higher rate of change than first and second positions. Topologically, the trees from the three genes are similar, and the differences are usually only weakly supported. In terms of support, RPB2 gives the highest jackknife support per sequenced nucleotide, whereas ndhF gives the highest Bremer support per sequenced nucleotide. The RPB2-d locus has the potential to be a valuable nuclear marker for determination of phylogenetic relationships within the euasterid I group of plants.

The roles of the homeobox genes aristaless and Distal-less in patterning the legs and wings of Drosophila

In the leg and wing imaginal discs of Drosophila, the expression domains of the homeobox genes aristaless (al) and Distal-less (Dll) are defined by the secreted signaling molecules Wingless (Wg) and Decapentaplegic (Dpp). Here, the roles played by al and Dll in patterning the legs and wings have been investigated through loss of function studies. In the developing leg, al is expressed at the presumptive tip and a molecularly defined null allele of al reveals that its only function in patterning the leg appears to be to direct the growth and differentiation of the structures at the tip. In contrast, Dll has previously been shown to be required for the development of all of the leg more distal than the coxa. Dll protein can be detected in a central domain in leg discs throughout most of larval development, and in mature discs this domain corresponds to the distal-most region of the leg, the tarsus and the distal tibia. Clonal analysis reveals that late in development these are the only regions in which Dll function is required. However, earlier in development Dll is required in more proximal regions of the leg suggesting it is expressed at high levels in these cells early in development but not later. This reveals a correlation between a temporal requirement for Dll and position along the proximodistal axis; how this may relate to the generation of the P/D axis is discussed. Dll is required in the distal regions of the leg for the expression of tarsal-specific genes including al and bric-a-brac. Dll mutant cells in the leg sort out from wild-type cells suggesting one function of Dll here is to control adhesive properties of cells. Dll is also required for the normal development of the wing, primarily for the differentiation of the wing margin.

Transcription of DmRP140, the gene coding for the second-largest subunit of RNA polymerase II

To analyze transcriptional control regions of Drosophila melanogaster housekeeping genes, we have characterized the promoter of the gene coding for the second-largest subunit of RNA polymerase II (DmRP140). Upstream of DmRP140 the genomic region harbors a gene which is transcribed in the opposite direction (DmRP140up). By determination of the transcription start sites of both genes we found a short non-transcribed intergenic region of 220 bp. Functional analysis of various promoter reportergene constructs by transient transfection of cultured cells revealed that sequences important for transcription of DmRP140 are located in the untranslated leader of the upstream gene. The onset of DmRP140 transcription during embryonic development was studied in transgenic flies using beta-galactosidase as reportergene. To distinguish between the maternally provided DmRP140 transcripts and the embryonically transcribed RNA the offspring of nontransformed females and male transformants was examined. The development of a sensitive detection assay based on a chemiluminescent substrate for beta-galactosidase allowed us to determine the onset of DmRP140 transcription to between 8-10 h after oviposition. Thus, DmRP140 transcription does not start following the transcriptional transition period between 2-3 h of development but occurs much later in embryogenesis coinciding with decreasing DNA synthesis and cell division rates.

Molecular cloning and characterization of the obg gene of Streptomyces griseus in relation to the onset of morphological differentiation

Morphological differentiation in microorganisms is usually accompanied by a decrease in intracellular GTP pool size, as has been demonstrated in bacillaceae, streptomycetaceae, and yeasts. The obg gene, which codes for a GTP-binding protein belonging to the GTPase superfamily of proteins, was cloned from Streptomyces griseus IFO13189. The gene is located just downstream of the genes for ribosomal proteins L21 and L27, encoded a protein of 478 amino acids (51 kDa), and possessed three consensus motifs which confer GTP-binding ability; Obg protein expressed in Escherichia coli bound GTP, as demonstrated using a UV cross-linking method. Introduction of multiple copies of obg into wild-type S. griseus suppressed aerial mycelium development in cells on solid media. However, no effect on streptomycin production was detected, indicating that Obg is involved in the regulation of the onset of morphological but not physiological differentiation. Multiple copies of obg also suppressed submerged spore formation in liquid culture. Southern hybridization studies indicated that genes homologous to obg exist widely in streptomycetes, and an obg homolog was successfully cloned from S. coelicolor A3(2). We propose that by monitoring the intracellular GTP pool size, the Obg protein is involved in sensing changes in the nutritional environment leading ultimately to morphological differentiation.

The gene upstream of DmRP128 codes for a novel GTP-binding protein of Drosophila melanogaster

Upstream of the gene coding for the second-largest subunit of RNA polymerase III (DmRP128) we have found another gene (128up), which is transcribed in the same direction as the RNA polymerase gene. The intergenic distance between the 3' end of 128up mRNA and the 5' end of DmRP128 mRNA is only about 100 bp. Transcripts of 128up are present at a much higher level than DmRP128 RNA in Drosophila Schneider 2 cells, embryos, and adult flies. Two transcription start points, seven nucleotides apart, are found for 128up compared to multiple scattered starts for DmRP128. Sequence analysis of 128up cDNA reveals that the gene codes for a 41 kDa protein with homology to GTP-binding proteins and matching four of the structural sequence motifs characteristic of the superfamily of GTPases. Bacterially expressed 128up protein fused to maltose-binding protein specifically binds GTP. Sequences closely related to the 128up protein are found in species as distant as Halobacterium, yeast or mouse; the murine protein is 80% identical to 128up. This evolutionary conservation is indicative of an important, but as yet unknown, physiological role. In accordance with the sequence conservation, antibodies against 128up specifically cross-react with mouse 3T3 cells and human Hep2 cells where the subcellular localization of the protein is predominantly perinuclear. We propose that 128up is a member of a novel class of GTP-binding proteins.

Mapping mutations in genes encoding the two large subunits of Drosophila RNA polymerase II defines domains essential for basic transcription functions and for proper expression of developmental genes

We have mapped a number of mutations at the DNA sequence level in genes encoding the largest (RpII215) and second-largest (RpII140) subunits of Drosophila melanogaster RNA polymerase II. Using polymerase chain reaction (PCR) amplification and single-strand conformation polymorphism (SSCP) analysis, we detected 12 mutations from 14 mutant alleles (86%) as mobility shifts in nondenaturing gel electrophoresis, thus localizing the mutations to the corresponding PCR fragments of about 350 bp. We then determined the mutations at the DNA sequence level by directly subcloning the PCR fragments and sequencing them. The five mapped RpII140 mutations clustered in a C-terminal portion of the second-largest subunit, indicating the functional importance of this region of the subunit. The RpII215 mutations were distributed more broadly, although six of eight clustered in a central region of the subunit. One notable mutation that we localized to this region was the alpha-amanitin-resistant mutation RpII215C4, which also affects RNA chain elongation in vitro. RpII215C4 mapped to a position near the sites of corresponding mutations in mouse and in Caenorhabditis elegans genes, reinforcing the idea that this region is involved in amatoxin binding and transcript elongation. We also mapped mutations in both RpII215 and RpII140 that cause a developmental defect known as the Ubx effect. The clustering of these mutations in each gene suggests that they define functional domains in each subunit whose alteration induces the mutant phenotype.

Mapping mutations in genes encoding the two large subunits of Drosophila RNA polymerase II defines domains essential for basic transcription functions and for proper expression of developmental genes

We have mapped a number of mutations at the DNA sequence level in genes encoding the largest (RpII215) and second-largest (RpII140) subunits of Drosophila melanogaster RNA polymerase II. Using polymerase chain reaction (PCR) amplification and single-strand conformation polymorphism (SSCP) analysis, we detected 12 mutations from 14 mutant alleles (86%) as mobility shifts in nondenaturing gel electrophoresis, thus localizing the mutations to the corresponding PCR fragments of about 350 bp. We then determined the mutations at the DNA sequence level by directly subcloning the PCR fragments and sequencing them. The five mapped RpII140 mutations clustered in a C-terminal portion of the second-largest subunit, indicating the functional importance of this region of the subunit. The RpII215 mutations were distributed more broadly, although six of eight clustered in a central region of the subunit. One notable mutation that we localized to this region was the alpha-amanitin-resistant mutation RpII215C4, which also affects RNA chain elongation in vitro. RpII215C4 mapped to a position near the sites of corresponding mutations in mouse and in Caenorhabditis elegans genes, reinforcing the idea that this region is involved in amatoxin binding and transcript elongation. We also mapped mutations in both RpII215 and RpII140 that cause a developmental defect known as the Ubx effect. The clustering of these mutations in each gene suggests that they define functional domains in each subunit whose alteration induces the mutant phenotype.

Sequence of the Schizosaccharomyces pombe gtp1 gene and identification of a novel family of putative GTP-binding proteins

A new gene, gtp1, has been identified by sequence analysis in Schizosaccharomyces pombe. The open reading frame was identified downstream from the stf1 locus. The deduced GTP1 protein has strong sequence similarity to a family of putative GTP-binding proteins from Halobacterium cutirubrum, Bacillus subtilis, Drosophila melanogaster and mouse. The conserved P-loop phosphate-binding motif places gtp1 in a family separate from previously described groups of such proteins.

TGA cysteine codons and intron sequences in conserved and nonconserved positions are found in macronuclear RNA polymerase genes of Euplotes octocarinatus

The gene sequences of the second largest subunits of RNA polymerases I and II of Euplotes octocarinatus, RPA2 and RPB2, were determined and compared to the respective known sequences of Saccharomyces cerevisiae. The similarity of the derived polypeptide sequences permitted their assignment to the respective polymerases and allowed the comparison of the zinc binding regions. In frame TGA codons were detected, which are likely to encode conserved cysteinyl residues in the putative zinc-finger region of the RPA2 gene. They were also found in other positions in both the RPA2 and RPB2 genes. The RPB2 gene contains a 30 bp intron close to the 5'-end of its coding region. The 5'-ends of the coding regions of all three genes encoding the largest subunits of the three different polymerases were also analyzed. The zinc finger structures again show the use of TGA codons for conserved cysteinyl residues in two of the genes. An N-terminal intron is located in the RPB1 gene at a conserved position as compared to the respective genes of several other eucarya.

Gene dosage as a possible major determinant for equal expression levels of genes encoding RNA polymerase subunits in the hypotrichous ciliate Euplotes octocarinatus

Ciliated protozoa harbor two different types of nuclei in each cell. The diploid micronucleus is the transcriptionally inactive generative nucleus, while the macronuclous contains a highly amplified transcriptionally active genome of lower complexity. The macronuclear genes encoding the two largest subunits of both RNA polymerases I and II of Euplotes octocarinatus were identified by a novel method of two step PCR walking, employing primer pairs derived from telomeric sequences of the organism and known conserved RNA polymerase polypeptide sequences, respectively. The relative gene dosage was determined. The genes are present in equal copy numbers for the respective matching subunits. Northern hybridizations showed comparable amounts of transcripts, as well, within the matching pairs. Mapping of the 5'-termini of the transcripts of the gene sized chromosomes showed that the upstream nontranscribed regions are very short and contain characteristic sequence motifs which could be the determinants of equal promoter strengths for subunits of a common RNA polymerase.

Identification of the genes coding for the second-largest subunits of RNA polymerases I and III of Drosophila melanogaster

We have isolated cDNA and genomic clones of Drosophila melanogaster by cross-hybridization with a 658 bp fragment of the yeast gene coding for the second-largest subunit of RNA polymerase III (RET1). Determination of the sequence by comparison of genomic and cDNA regions reveals an ORF of 3405 nucleotides which is interrupted in the genomic sequence by an intron of 48 bp. The deduced polypeptide consists of 1135 amino acids with a calculated molecular weight of 128 kDa. The protein sequence shows the same conserved regions of homology as those observed for all the second-largest subunits of RNA polymerases cloned so far. The gene (DmRP128) obviously codes for a second-largest subunit of an RNA polymerase which is different from DmRP140 and DmRP135. We have purified three distinct RNA polymerase activities from D. melanogaster. By using specific RNA polymerase inhibitors in enzyme assays and by comparing their subunit composition we were able to distinguish between RNA polymerase I, II, and III. RNA polymerase preparations of D. melanogaster were blotted and the second-largest subunits were identified with antibodies raised against polypeptides expressed from DmRP128 and DmRP135. Anti-DmRP135 antibodies react strongly with the second-largest subunit of RNA polymerase I but do not react with the respective subunits of RNA polymerase II and III. The second-largest subunit of RNA polymerase III is only recognized by anti-DmRP128. Previously, we have claimed that DmRP135 codes for the second-largest subunit of RNA polymerase III.(ABSTRACT TRUNCATED AT 250 WORDS)

Suppressor analysis of temperature-sensitive mutations of the largest subunit of RNA polymerase I in Saccharomyces cerevisiae: a suppressor gene encodes the second-largest subunit of RNA polymerase I

The SRP3-1 mutation is an allele-specific suppressor of temperature-sensitive mutations in the largest subunit (A190) of RNA polymerase I from Saccharomyces cerevisiae. Two mutations known to be suppressed by SRP3-1 are in the putative zinc-binding domain of A190. We have cloned the SRP3 gene by using its suppressor activity and determined its complete nucleotide sequence. We conclude from the following evidence that the SRP3 gene encodes the second-largest subunit (A135) of RNA polymerase I. First, the deduced amino acid sequence of the gene product contains several regions with high homology to the corresponding regions of the second-largest subunits of RNA polymerases of various origins, including those of RNA polymerase II and III from S. cerevisiae. Second, the deduced amino acid sequence contains known amino acid sequences of two tryptic peptides from the A135 subunit of RNA polymerase I purified from S. cerevisiae. Finally, a strain was constructed in which transcription of the SRP3 gene was controlled by the inducible GAL7 promoter. When this strain, which can grow on galactose but not on glucose, was shifted from galactose medium to glucose medium, a large decrease in the cellular concentration of A135 was observed by Western blot analysis. We have also identified the specific amino acid alteration responsible for suppression by SRP3-1 and found that it is located within the putative zinc-binding domain conserved among the second-largest subunits of eucaryotic RNA polymerases. From these results, it is suggested that this putative zinc-binding domain is in physical proximity to and interacts with the putative zinc-binding domain of the A190 subunit.

Suppressor analysis of temperature-sensitive mutations of the largest subunit of RNA polymerase I in Saccharomyces cerevisiae: a suppressor gene encodes the second-largest subunit of RNA polymerase I

The SRP3-1 mutation is an allele-specific suppressor of temperature-sensitive mutations in the largest subunit (A190) of RNA polymerase I from Saccharomyces cerevisiae. Two mutations known to be suppressed by SRP3-1 are in the putative zinc-binding domain of A190. We have cloned the SRP3 gene by using its suppressor activity and determined its complete nucleotide sequence. We conclude from the following evidence that the SRP3 gene encodes the second-largest subunit (A135) of RNA polymerase I. First, the deduced amino acid sequence of the gene product contains several regions with high homology to the corresponding regions of the second-largest subunits of RNA polymerases of various origins, including those of RNA polymerase II and III from S. cerevisiae. Second, the deduced amino acid sequence contains known amino acid sequences of two tryptic peptides from the A135 subunit of RNA polymerase I purified from S. cerevisiae. Finally, a strain was constructed in which transcription of the SRP3 gene was controlled by the inducible GAL7 promoter. When this strain, which can grow on galactose but not on glucose, was shifted from galactose medium to glucose medium, a large decrease in the cellular concentration of A135 was observed by Western blot analysis. We have also identified the specific amino acid alteration responsible for suppression by SRP3-1 and found that it is located within the putative zinc-binding domain conserved among the second-largest subunits of eucaryotic RNA polymerases. From these results, it is suggested that this putative zinc-binding domain is in physical proximity to and interacts with the putative zinc-binding domain of the A190 subunit.

Phylogenetic analysis of the RNA polymerases of Trypanosoma brucei, with special reference to class-specific transcription

We have sequenced the genes encoding to largest subunits of the three classes of DNA-dependent RNA polymerases of Trypanosoma brucei. The nucleotide and deduced amino acid sequences were compared and aligned with the corresponding sequences of other eukaryotes. Phylogenetic relationships were subsequently calculated with a distant matrix, a bootstrapped parsimony and a maximum-likelihood method. These independent calculations resulted in trees with very similar topologies. The analyses show that all the largest subunits of T. brucei are evolutionarily distant members within each of the three RNA polymerase classes. An early separation of the trypanosomal subunits from the eukaryotic lineage might form the fundamental basis for the unusual transcription process of this species. Finally, all dendrograms show a separate ramification for the largest subunit of RNA polymerase I, II and III. RNA polymerase II and/or III form a bifurcation with the archaebacterial lineage, RNA polymerase I, however, arises separately from the eubacterial beta' lineage. This suggests that the three eukaryotic RNA polymerase classes are not simply derived by two gene duplications of an ancestral gene with subsequent differentiation.