NORMAL GENOMIC

• Du YJ, Hou YL, Hou WR
• Molecular characterization of a gene POLR2H encoded an essential subunit for RNA polymerase II from the Giant Panda (Ailuropoda Melanoleuca).
• Mol Biol Rep. 2013; 40: 1495-8
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• The Giant Panda is an endangered and valuable gene pool in genetic, its important functional gene POLR2H encodes an essential shared peptide H of RNA polymerases. The genomic DNA and cDNA sequences were cloned successfully for the first time from the Giant Panda (Ailuropoda melanoleuca) adopting touchdown-PCR and reverse transcription polymerase chain reaction (RT-PCR), respectively. The length of the genomic sequence of the Giant Panda is 3,285 bp, including five exons and four introns. The cDNA fragment cloned is 509 bp in length, containing an open reading frame of 453 bp encoding 150 amino acids. Alignment analysis indicated that both the cDNA and its deduced amino acid sequence were highly conserved. Protein structure prediction showed that there was one protein kinase C phosphorylation site, four casein kinase II phosphorylation sites and one amidation site in the POLR2H protein, further shaping advanced protein structure. The cDNA cloned was expressed in Escherichia coli, which indicated that POLR2H fusion with the N-terminally His-tagged form brought about the accumulation of an expected 20.5 kDa polypeptide in line with the predicted protein. On the basis of what has already been achieved in this study, further deep-in research will be conducted, which has great value in theory and practical significance.

• Tombacz I, Schauer T, Juhasz I, Komonyi O, Boros I
• The RNA Pol II CTD phosphatase Fcp1 is essential for normal development in Drosophila melanogaster.
• Gene. 2009; 446: 58-67
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• The reversible phosphorylation-dephosphorylation of RNA polymerase II (Pol II) large subunit carboxyl terminal domain (CTD) during transcription cycles in eukaryotic cells generates signals for the steps of RNA synthesis and maturation. The major phosphatase specific for CTD dephosphorylation from yeast to mammals is the TFIIF-interacting CTD-phosphatase, Fcp1. We report here on the in vivo analysis of Fcp1 function in Drosophila using transgenic lines in which the phosphatase production is misregulated. Fcp1 function is essential throughout Drosophila development and ectopic up- or downregulation of fcp1 results in lethality. The fly Fcp1 binds to specific regions of the polytene chromosomes at many sites colocalized with Pol II. In accord with the strong evolutional conservation of Fcp1: (1) the Xenopus fcp1 can substitute the fly fcp1 function, (2) similarly to its S. pombe homologue, Drosophila melanogaster (Dm)Fcp1 interacts with the RPB4 subunit of Pol II, and (3) transient expression of DmFcp1 has a negative effect on transcription in mammalian cells. The in vivo experimental system described here suggests that fly Fcp1 is associated with the transcription engaged Pol II and offers versatile possibilities for studying this evolutionary conserved essential enzyme.

• Lagos D, Ruiz MF, Sanchez L, Komitopoulou K
• Isolation and characterization of the Bactrocera oleae genes orthologous to the sex determining Sex-lethal and doublesex genes of Drosophila melanogaster.
• Gene. 2005; 348: 111-21
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• Here we report the isolation and characterization of the olive fruit fly Bactrocera oleae genes orthologous to the Drosophila melanogaster sex-determining genes Sex-lethal (Sxl) and doublesex (dsx). Fragments of the Sxl and dsx orthologous were isolated with RT-PCR. Genomic and cDNA clones were then obtained by screening a genomic library and separate male and female cDNA adult libraries using the RT-PCR products as probes in both cases. B. oleae Sxl gene (BoSxl) expresses the same pattern of transcripts which encode for a single common polypeptide in both male and female flies. The gene shares a high degree of similarity in sequence and expression to its Ceratitis capitata orthologous and does not appear to play a key regulatory role in the sex-determining cascade. B. oleae dsx gene (Bodsx) expands in a chromosomal region of more than 50 kb, with 6 exons-5 introns, producing different sex-specific mRNAs, according to the Drosophila model. The cDNA sequences are almost identical to the gene orthologous of Bactrocera tryoni. Four repeat elements identical to the D. melanogaster TRA/TRA-2 binding sites have been found in the untranslated region of the female-specific exon 4, predicting a common regulatory splicing mechanism in all studied species of Diptera.

• Spassov DS, Jurecic R
• Mouse Pum1 and Pum2 genes, members of the Pumilio family of RNA-binding proteins, show differential expression in fetal and adult hematopoietic stem cells and progenitors.
• Blood Cells Mol Dis. 2003; 30: 55-69
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• Self-renewal is the common functional property of all types of stem cells and is thought to be regulated by unknown conserved intrinsic and extrinsic molecular mechanisms. Recently, an evolutionarily conserved Pumilio family of RNA-binding proteins that regulate asymmetric cell division was found to be essential for stem cell maintenance and self-renewal in Drosophila and Caenorhabditis elegans. Based on conserved function in invertebrates and lower vertebrates it was recently proposed that an ancestral function of Pumilio proteins is to support proliferation and self-renewal of stem cells. This raises an interesting possibility that Pumilio could be part of evolutionarily conserved intrinsic molecular mechanism that regulates self-renewal of mammalian stem cells. Here we describe cloning and comparative sequence analysis of Pum1 and Pum2 genes, mouse members of the Pumilio family, and for the first time demonstrate expression of Pumilio genes in mammalian hematopoietic stem cells (HSC). Pum1 and Pum2 share 51 and 55% overall similarity with the fly Pum, whereas their RNA-binding domains show a very high degree of evolutionary conservation (86-88% homology). Both genes are expressed in a variety of tissues suggesting that they have widespread function. During blood cell development Pum1 and Pum2 exhibit differential expression in cell populations enriched for HSC and progenitors. Both genes are highly transcribed in populations of adult HSC (Rho-123(low)Sca-1(+)c-kit(+)Lin(-) cells). In a more heterogeneous population of HSC (Lin(-)Sca-1(+)) and in progenitors (Lin(-)Sca-1(-) cells) Pum1 is not transcribed, whereas Pum2 expression is significantly down-regulated. Ongoing in vitro and in vivo functional analysis of mouse Pumilio genes will help to elucidate the biological role of mammalian Pumilio genes and determine whether they play any role in maintenance of mammalian stem cells, such as HSC.

• Kmieciak M, Simpson CG, Lewandowska D, Brown JW, Jarmolowski A
• Cloning and characterization of two subunits of Arabidopsis thaliana nuclear cap-binding complex.
• Gene. 2002; 283: 171-83
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• In this report we characterize two Arabidopsis thaliana proteins, named AtCBP20 and AtCBP80, that are homologues of human subunits of a nuclear cap-binding protein complex (CBC). AtCBP20 has a calculated molecular mass of 29.9 kDa, and AtCBP80 is a 96.5 kDa protein. AtCBP20 exhibits 68% identity and 82% similarity to human CBP20. Like its human homologue, AtCBP20 contains a canonical RNA binding domain (RBD) with single RNP2 and RNP1 motifs. In addition to the N-terminal part, which is similar to the human protein, AtCBP20 has a long C-terminus rich in arginine, glycine and aspartate residues. The second subunit of the Arabidopsis cap-binding complex, AtCBP80, shows 28% identity and 50% similarity to its homologue from HeLa cells. The protein contains a MIF4G domain at its N-terminus, the feature characteristic to all analyzed CBP80s. This domain, described also in eIF4G and NMD2 proteins, is thought to be involved in protein-protein and also in protein--RNA interactions. Both proteins AtCBP20 and AtCBP80 are encoded by single-copy genes in the A. thaliana genome. The AtCBP20 gene is located on chromosome V, and the AtCBP80 gene is encoded by chromosome II. Among introns identified in the AtCBP20 gene, we discovered an U12 type intervening sequence (an AT-AC intron). This intron is spliced out very efficiently in plants, but when isolated and tested for splicing in tobacco protoplasts, the efficiency of the U12 intron excision was low. Splicing efficiency of the U12 intron is improved by the addition of exon and intron sequences upstream or downstream of the U12 intron. AtCBP20 and AtCBP80 are constitutively expressed in all examined organs of A. thaliana, including roots, stems, leaves and flowers. Interestingly, the steady-state level of both transcripts seem to be very similar in all tissues analyzed.

• Grandemange S et al.
• A human RNA polymerase II subunit is encoded by a recently generated multigene family.
• BMC Mol Biol. 2001; 2: 14-14
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• BACKGROUND: The sequences encoding the yeast RNA polymerase II (RPB) subunits are single copy genes. RESULTS: While those characterized so far for the human (h) RPB are also unique, we show that hRPB subunit 11 (hRPB11) is encoded by a multigene family, mapping on chromosome 7 at loci p12, q11.23 and q22. We focused on two members of this family, hRPB11a and hRPB11b: the first encodes subunit hRPB11a, which represents the major RPB11 component of the mammalian RPB complex; the second generates polypeptides hRPB11balpha and hRPB11bbeta through differential splicing of its transcript and shares homologies with components of the hPMS2L multigene family related to genes involved in mismatch-repair functions (MMR). Both hRPB11a and b genes are transcribed in all human tissues tested. Using an inter-species complementation assay, we show that only hRPB11balpha is functional in yeast. In marked contrast, we found that the unique murine homolog of RPB11 gene maps on chromosome 5 (band G), and encodes a single polypeptide which is identical to subunit hRPB11a. CONCLUSIONS: The type hRPB11b gene appears to result from recent genomic recombination events in the evolution of primates, involving sequence elements related to the MMR apparatus.

• Guru SC et al.
• Characterization of a MEN1 ortholog from Drosophila melanogaster.
• Gene. 2001; 263: 31-8
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• Multiple endocrine neoplasia type 1 (MEN1) is a familial cancer syndrome characterized by tumors of the parathyroid, entero-pancreatic neuroendocrine and pituitary tissues and caused by inactivating mutations in the MEN1 gene. Menin, the 610-amino acid nuclear protein encoded by MEN1, binds to the transcription factor JunD and can repress JunD-induced transcription. We report here the identification of a MEN1 ortholog in Drosophila melanogaster, Menin1, that encodes a 763 amino acid protein sharing 46% identity with human menin. Additionally, 69% of the missense mutations and in-frame deletions reported in MEN1 patients appear in amino acid residues that are identical in the Drosophila and human protein, suggesting the importance of the conserved regions. Drosophila Menin1 gene transcripts use alternative polyadenylation sites resulting in 4.3 and 5-kb messages. The 4.3-kb transcript appears to be largely maternal, while the 5-kb transcript appears mainly zygotic. The binding of Drosophila menin to human JunD or Drosophila Jun could not be demonstrated by the yeast two-hybrid analysis. The identification of the MEN1 ortholog from Drosophila melanogaster will provide an opportunity to utilize Drosophila genetics to enhance our understanding of the function of human menin.

• Kamura T et al.
• Cloning and characterization of ELL-associated proteins EAP45 and EAP20. a role for yeast EAP-like proteins in regulation of gene expression by glucose.
• J Biol Chem. 2001; 276: 16528-33
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• RNA polymerase II elongation factor ELL was recently purified from rat liver as a component of a multiprotein complex containing ELL and three ELL-associated proteins (EAPs) of approximately 45 (EAP45), approximately 30 (EAP30), and approximately 20 (EAP20) kDa (Shilatifard, A. (1998) J. Biol. Chem. 273, 11212-11217). Cloning of cDNA encoding the EAP30 protein revealed that it shares significant sequence similarity with the product of the Saccharomyces cerevisiae SNF8 gene (Schmidt, A. E., Miller, T., Schmidt, S. L., Shiekhattar, R., and Shilatifard, A. (1999) J. Biol. Chem. 274, 21981-21985), which is required for efficient derepression of glucose-repressed genes. Here we report the cloning of cDNAs encoding the EAP45 and EAP20 proteins. In addition, we identify the S. cerevisiae VPS36 and YJR102c genes as potential orthologs of EAP45 and EAP20 and show that they are previously uncharacterized SNF genes with properties very similar to SNF8.

• Fan W, Wang Z, Kyzysztof F, Prange C, Lennon G
• A new zinc ribbon gene (ZNRD1) is cloned from the human MHC class I region.
• Genomics. 2000; 63: 139-41
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• Eleven unique cDNA fragments were identified from YAC B30H3, which spans 330 kb in the human major histocompatibility complex class I region. One fragment (CAT80) was mapped 80 kb telomeric to the HLA-A locus. Using this cDNA fragment as probe, Northern analysis reveals a ubiquitously expressed transcript of about 850 nt in all 16 tissues tested. Based on the cDNA fragment sequence, a full-length cDNA of 858 bp that contains an open reading frame of 378 bp was cloned. Within the putative polypeptide of 126 amino acids, two zinc-ribbon domains were identified: Cx2Cx15Cx2C at the N-terminal and Cx2Cx24Cx2C at the C-terminal. The C-terminal domain is well conserved throughout evolution, including archaea, yeast, Drosophila, nematodes, amphibians, and mammals. The conserved amino acid sequence, CxRCx6Yx3QxRSADEx2TxFxCx2C, is highly homologous to the yeast RNA polymerase A subunit 9 and transcription-associated proteins. Alignment with genomic DNA demonstrates that this gene spans 3.6 kb and consists of four exons and three introns. Cross-species Northern analysis reveals a mouse homolog of a similar size and with an expression profile similar to those of the human gene. We have named this gene ZNRD1 for zinc ribbon domain-containing 1 protein.

• Guipponi M et al.
• C21orf5, a novel human chromosome 21 gene, has a Caenorhabditis elegans ortholog (pad-1) required for embryonic patterning.
• Genomics. 2000; 68: 30-40
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• To contribute to the development of the transcription map of human chromosome 21 (HC21), we isolated a new transcript, C21orf5 (chromosome 21 open reading frame 5), encoding a predicted 2298-amino-acid protein. Analysis of the genomic DNA sequence revealed that C21orf5 consists of 37 exons that extend over 130 kb and maps between the CBR3 (carbonyl reductase 3) and the KIAA0136 genes. Northern blot analyses showed a ubiquitously expressed RNA species of 8.5 kb. RNA in situ hybridization on brain sections of normal human embryos revealed a strong labeling in restricted areas of the cerebral cortex. In silico analysis of the deduced C21orf5 protein revealed several highly probable transmembrane segments but no known protein domains or homology with known proteins. However, there were significant homologies to several hypothetical Caenorhabditis elegans proteins and Drosophila melanogaster genomic sequences. To investigate the function of C21orf5, we isolated the cDNA of the C. elegans ortholog and performed double-stranded RNA-mediated genetic interference experiments. The major phenotype observed in the progeny of injected animals was embryonic lethality. Most of the tissues of the embryo failed to undergo proper patterning during gastrulation, and morphogenesis did not occur; thus we termed the ortholog pad-1, for patterning defective 1. These results indicated that pad-1 is essential for the development and the survival of C. elegans. This study provides the first example of the use of C. elegans as a model to study the function of genes on human chromosome 21 that might be involved in Down syndrome.

• Buchner G, Bassi MT, Andolfi G, Ballabio A, Franco B
• Identification of a novel homolog of the Drosophila staufen protein in the chromosome 8q13-q21.1 region.
• Genomics. 1999; 62: 113-8
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• We report the identification of a new transcript homologous to the Drosophila staufen protein. This transcript, named STAU2 (HGMW-approved gene symbol and name), maps to the chromosome 8q13-q21 region. The full-length STAU2 cDNA is 4058 bp and contains an open reading frame of 479 amino acids. Analysis of the predicted protein product indicated the presence of three double-stranded RNA-binding domains. Best-fit analysis revealed a 48.5% similarity to the Drosophila protein and a 59.9% similarity to the recently described mammalian homolog hStau, indicating that at least two different transcripts with homologies to the fly protein are present in mammals.

• Shpakovskii GV, Shematorova EK
• [Characteristics of the cDNA of the Schizosaccharomyces pombe rpa43+ gene: structural similarity of the Rpa43 subunit of RNA-polymerase I with the Rpc25 subunit of RNA-polymerase III].
• Bioorg Khim. 1999; 25: 791-6
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• We isolated and characterized full-length cDNA of the rpa43+ gene encoding one of subunits of the nuclear RNA polymerase I of Schizosaccharomyces pombe. The gene contains two introns and is located on chromosome II. Comparison of the primary structure of the subunit Rpa43 of Sz. pombe (173 aa; M 19,385 Da; pl 5.36), deduced from the cDNA obtained, with the amino acid sequences of subunits A43 from Saccharomyces cerevisiae and Drosophila melanogaster demonstrates a high divergence of this protein in evolution. A comparison of the Rpa43 with other proteins from the SwissProt database revealed a similarity of this subunit to subunit Rpc25 of RNA polymerase III, which, as was shown previously, is structurally similar to subunit Rpb7 of RNA polymerase II. Thus, including the Rpa43<-->Rpc25<-->Rpb7 family, nuclear RNA polymerases I-III contain at least 11 identical and/or similar subunits. This fact illustrates a pronounced resemblance of the organization of all three enzymes of the eukaryotic transcription apparatus. Moreover, at least ten out of these eleven families of eukaryotic RNA polymerase subunits have homologues in the 13-subunit archaeal RNA polymerase.

• Olsen DS, Jordan B, Chen D, Wek RC, Cavener DR
• Isolation of the gene encoding the Drosophila melanogaster homolog of the Saccharomyces cerevisiae GCN2 eIF-2alpha kinase.
• Genetics. 1998; 149: 1495-509
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• Genomic and cDNA clones homologous to the yeast GCN2 eIF-2alpha kinase (yGCN2) were isolated from Drosophila melanogaster. The identity of the Drosophila GCN2 (dGCN2) gene is supported by the unique combination of sequence encoding a protein kinase catalytic domain and a domain homologous to histidyl-tRNA synthetase and by the ability of dGCN2 to complement a deletion mutant of the yeast GCN2 gene. Complementation of Deltagcn2 in yeast by dGCN2 depends on the presence of the critical regulatory phosphorylation site (serine 51) of eIF-2alpha. dGCN2 is composed of 10 exons encoding a protein of 1589 amino acids. dGCN2 mRNA is expressed throughout Drosophila development and is particularly abundant at the earliest stages of embryogenesis. The dGCN2 gene was cytogenetically and physically mapped to the right arm of the third chromosome at 100C3 in STS Dm2514. The discovery of GCN2 in higher eukaryotes is somewhat unexpected given the marked differences between the amino acid biosynthetic pathways of yeast vs. Drosophila and other higher eukaryotes. Despite these differences, the presence of GCN2 in Drosophila suggests at least partial conservation from yeast to multicellular organisms of the mechanisms responding to amino acid deprivation.

• Neveling U, Klasen R, Bringer-Meyer S, Sahm H
• Purification of the pyruvate dehydrogenase multienzyme complex of Zymomonas mobilis and identification and sequence analysis of the corresponding genes.
• J Bacteriol. 1998; 180: 1540-8
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• The pyruvate dehydrogenase (PDH) complex of the gram-negative bacterium Zymomonas mobilis was purified to homogeneity. From 250 g of cells, we isolated 1 mg of PDH complex with a specific activity of 12.6 U/mg of protein. Analysis of subunit composition revealed a PDH (E1) consisting of the two subunits E1alpha (38 kDa) and E1beta (56 kDa), a dihydrolipoamide acetyltransferase (E2) of 48 kDa, and a lipoamide dehydrogenase (E3) of 50 kDa. The E2 core of the complex is arranged to form a pentagonal dodecahedron, as shown by electron microscopic images, resembling the quaternary structures of PDH complexes from gram-positive bacteria and eukaryotes. The PDH complex-encoding genes were identified by hybridization experiments and sequence analysis in two separate gene regions in the genome of Z. mobilis. The genes pdhAalpha (1,065 bp) and pdhAbeta (1,389 bp), encoding the E1alpha and E1beta subunits of the E1 component, were located downstream of the gene encoding enolase. The pdhB (1,323 bp) and lpd (1,401 bp) genes, encoding the E2 and E3 components, were identified in an unrelated gene region together with a 450-bp open reading frame (ORF) of unknown function in the order pdhB-ORF2-lpd. Highest similarities of the gene products of the pdhAalpha, pdhAbeta, and pdhB genes were found with the corresponding enzymes of Saccharomyces cerevisiae and other eukaryotes. Like the dihydrolipoamide acetyltransferases of S. cerevisiae and numerous other organisms, the product of the pdhB gene contains a single lipoyl domain. The E1beta subunit PDH was found to contain an amino-terminal lipoyl domain, a property which is unique among PDHs.

• Kurzik-Dumke U, Kaymer M, Gundacker D, Debes A, Labitzke K
• Gene within gene configuration and expression of the Drosophila melanogaster genes lethal(2) neighbour of tid [l(2)not] and lethal(2) relative of tid[l(2)rot].
• Gene. 1997; 200: 45-58
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• In this paper, we describe the structure and temporal expression pattern of the Drosophila melanogaster genes l(2)not and l(2)rot located at locus 59F5 vis a vis the tumor suppressor gene l(2)tid described previously and exhibiting a gene within gene configuration. The l(2)not protein coding region, 1530 nt, is divided into two exons by an intron, 2645 nt, harboring the genes l(2)rot, co-transcribed from the same DNA strand, and l(2)tid, co-transcribed from the opposite DNA strand, located vis a vis. To determine proteins encoded by the genes described in this study polyclonal rabbit antibodies (Ab), anti-Not and anti-Rot, were generated. Immunostaining of developmental Western blots with the anti-Not Ab resulted in the identification of a 45-kDa protein, Not45, which is smaller than the Not56 protein predicted from the sequence. Its localization in endoplasmic reticulum (ER) was established by immunoelectron microscopy of Drosophila melanogaster Schneider 2 cells. Not45 shows significant homology to yeast ALG3 protein acting as a dolichol mannosyltransferase in the asparagine-linked glycosylation. It is synthesized ubiquitously throughout embryonic life. The protein predicted from the l(2)rot sequence, Rot57, shows a homology to the NS2B protein of the yellow fever virus1 (yefv1). The results of l(2)rot RNA analysis by developmental Northern blot and by in situ RNA localization, as well as the results of the protein analysis via Western blot and immunohistochemistry suggest that l(2)rot is transcribed but not translated. Since RNAs encoded by the genes l(2)tid and l(2)rot are complementary and l(2)rot is presumably not translated we performed preliminary experiments on the function of the l(2)rot RNA as a natural antisense RNA (asRNA) regulator of l(2)tid expression, expressed in the same temporal and spatial manner as the l(2)tid- and l(2)not RNA. l(2)tid knock-out by antisense RNA yielded late embryonic lethality resulting from multiple morphogenetic defects.

• Kasukabe T, Okabe-Kado J, Honma Y
• TRA1, a novel mRNA highly expressed in leukemogenic mouse monocytic sublines but not in nonleukemogenic sublines.
• Blood. 1997; 89: 2975-85
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• Mouse monocytic Mm-A, Mm-P, Mm-S1, and Mm-S2 cells are sublines of mouse monocytic and immortalized Mm-1 cells derived from spontaneously differentiated, mouse myeloblastic M1 cells. Although these subline cells retain their monocytic characteristics in vitro, Mm-A and Mm-P cells are highly leukemogenic to syngeneic SL mice and athymic nude mice, whereas Mm-S1 and Mm-S2 cells are not or are only slightly leukemogenic. To better understand the molecular mechanisms of these levels of leukemogenicity, we investigated putative leukemogenesis-associated genes or oncogenes involved in the maintenance of growth, especially in vivo, by means of differential mRNA display. We isolated a fragment clone (15T01) from Mm-P cells. The mRNA probed with 15T01 was expressed at high levels in leukemogenic Mm-P and Mm-A cells but not in nonleukemogenic Mm-S1 and Mm-S2 cells. The gene corresponding to 15T01, named TRA1, was isolated from an Mm-P cDNA library. The longest open reading frame of the TRA1 clone predicts a peptide containing 204 amino acids with a calculated molecular weight of 23,049 D. The predicted TRA1 protein is cysteine-rich and contains multiple cysteine doublets. A putative normal counterpart gene, named NOR1, was also isolated from a normal mouse kidney cDNA library and sequenced. NOR1 cDNA predicts a peptide containing 234 amino acids. The sequence of 201 amino acids from the C-terminal NOR1 was completely identical to that of TRA1, whereas the remaining N-terminal amino acids (33 amino acids) were longer than that (3 amino acids) of TRA1 and the N-terminus of NOR1 protein contained proline-rich sequence. A similarity search against current nucleotide and protein sequence databases indicated that the NOR1/TRA1 gene(s) is conserved in a wide range of eukaryotes, because apparently homologous genes were identified in Caenorhabditis elegans and Saccharomyces cerevisiae genomes. Northern blotting using TRA1-specific and NOR1-specific probes indicated that TRA1 mRNA is exclusively expressed in leukemogenic but not in nonleukemogenic Mm sublines and normal tissues and also indicated that NOR1 mRNA is expressed in normal tissues, especially in kidney, lung, liver, and bone marrow cells but not in any Mm sublines. After leukemogenic Mm-P cells were induced to differentiate into normal macrophages by sodium butyrate, the normal counterpart, NOR1, was expressed, whereas the TRA1 level decreased. Furthermore, transfection of TRA1 converted nonleukemogenic Mm-S1 cells into leukemogenic cells. These results indicate that the TRA1 gene is associated at least in part with the leukemogenesis of monocytic Mm sublines.

• Asano K, Vornlocher HP, Richter-Cook NJ, Merrick WC, Hinnebusch AG, Hershey JW
• Structure of cDNAs encoding human eukaryotic initiation factor 3 subunits. Possible roles in RNA binding and macromolecular assembly.
• J Biol Chem. 1997; 272: 27042-52
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• The mammalian translation initiation factor 3 (eIF3), is a multiprotein complex of approximately 600 kDa that binds to the 40 S ribosome and promotes the binding of methionyl-tRNAi and mRNA. cDNAs encoding 5 of the 10 subunits, namely eIF3-p170, -p116, -p110, -p48, and -p36, have been isolated previously. Here we report the cloning and characterization of human cDNAs encoding the major RNA binding subunit, eIF3-p66, and two additional subunits, eIF3-p47 and eIF3-p40. Each of these proteins is present in immunoprecipitates formed with affinity-purified anti-eIF3-p170 antibodies. Human eIF3-p66 shares 64% sequence identity with a hypothetical Caenorhabditis elegans protein, presumably the p66 homolog. Deletion analyses of recombinant derivatives of eIF3-p66 show that the RNA-binding domain lies within an N-terminal 71-amino acid region rich in lysine and arginine. The N-terminal regions of human eIF3-p40 and eIF3-p47 are related to each other and to 17 other eukaryotic proteins, including murine Mov-34, a subunit of the 26 S proteasome. Phylogenetic analyses of the 19 related protein sequences, called the Mov-34 family, distinguish five major subgroups, where eIF3-p40, eIF3-p47, and Mov-34 are each found in a different subgroup. The subunit composition of eIF3 appears to be highly conserved in Drosophila melanogaster, C. elegans, and Arabidopsis thaliana, whereas only 5 homologs of the 10 subunits of mammalian eIF3 are encoded in S. cerevisiae.

• Seither P, Grummt I
• Molecular cloning of RPA2, the gene encoding the second largest subunit of mouse RNA polymerase I.
• Genomics. 1996; 37: 135-9
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• We have cloned the cDNA encoding the second largest subunit of RNA polymerase I, termed RPA2, from mouse cells. The cDNA has a 3978-nucleotide open reading frame encoding a polypeptide of 1136 amino acids with a calculated molecular mass of 128 kDa. A sequence alignment of mouse RPA2 with the corresponding gene from Drosophila melanogaster and yeast reveals a much lower sequence similarity of this subunit of RNA polymerase I (Pol I) compared to the second largest subunit of other eukaryotic RNA polymerases. Four Pol I-specific regions, termed I alpha-I delta, are conserved in the N-terminal part of RPA2. The structural features of the different domains as well as the homology to essential functional domains found in other RNA polymerases are discussed.

• Prasartkaew S, Zijlstra NM, Wilairat P, Overdulve JP, de Vries E
• Molecular cloning of a Plasmodium falciparum gene interrupted by 15 introns encoding a functional primase 53 kDa subunit as demonstrated by expression in a baculovirus system.
• Nucleic Acids Res. 1996; 24: 3934-41
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• The gene encoding the primase small subunit was isolated from genomic DNA of strain K1 of the human malarial parasite Plasmodium falciparum. Isolation of a complete cDNA clone revealed the presence of 15 introns in the genomic sequence. This is unprecedented for Plasmodium genes, which usually contain no or only 1 or 2 introns. The gene is present as a single copy and the cDNA contains an open reading frame of 1356 nt encoding a protein of 452 amino acids. A single mRNA of 2.1 kb was identified by Northern blotting. Comparison of the amino acid sequence with five eukaryotic small primase subunits revealed the presence of eight conserved regions. Sequence alignments allowed the identification of putative motifs A, B and C that are essential features of the catalytic centre of DNA polymerases, RNA polymerases and reverse transcriptases. Also, similarity of a C-terminal region of approximately 100 amino acids to a conserved region in herpes virus primases, alpha-like DNA polymerases and RNA polymerase II was noted. The complete gene was expressed as a fusion product containing an N-terminal polyhistidine tag using a baculovirus expression vector. The protein was overproduced in insect cells and purified. Activity assays demonstrated the ability of the p53 subunit to initiate de novo primer formation.

• Nozaki M, Onishi Y, Togashi S, Miyamoto H
• Molecular characterization of the Drosophila Mo25 gene, which is conserved among Drosophila, mouse, and yeast.
• DNA Cell Biol. 1996; 15: 505-9
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• To study the general physiological role of the Mo25 gene, which has been cloned from mouse cleavage-stage embryos, we isolated a Drosophila equivalent, dMo25, cDNA from an embryo cDNA library. The 2,222 nucleotides contained a single open reading frame encoding a polypeptide of 339 amino acid residues with a calculated molecular mass of 39,278 daltons. The deduced amino acid sequence of the dMo25 cDNA had 69.3% identity with mouse Mo25. A homology search revealed that these were similar to a protein encoded in an open reading frame near the calcineurin B subunit gene on chromosome XI in Saccharomyces cerevisiae. In particular, the carboxy-terminal region was highly conserved in Drosophila, mouse, and yeast. The dMo25 gene was mapped to the left arm of the third chromosome at 73AB, and 2.3- and 1.8-kb mRNA bands were detected during development and in adult Drosophila. Conservation of the gene structure and the wide expression profile indicated that the function of the gene is likely to be fundamental in many cell types as well as during development.

• Inoue M et al.
• Isolation and characterization of a human cDNA clone (GCN5L1) homologous to GCN5, a yeast transcription activator.
• Cytogenet Cell Genet. 1996; 73: 134-6
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• We have isolated a novel human cDNA with a predicted amino acid sequence homologous to GCN5, a protein considered to be a regulator of transcriptional activation in yeast. This cDNA, termed GCN5L1 (GCN5-like 1), consists of 545 nucleotides including an open reading frame of 378 bp that encodes a 126-amino-acid peptide having 23.5% identity to yeast GCN5. Northern-blot analysis revealed transcription of this gene in all human tissues examined. We isolated a genomic clone corresponding to this cDNA from a human cosmid library and mapped it to chromosome 12q13 --> q14 by fluorescent in situ hybridization (FISH).

• Shpakovski GV, Acker J, Wintzerith M, Lacroix JF, Thuriaux P, Vigneron M
• Four subunits that are shared by the three classes of RNA polymerase are functionally interchangeable between Homo sapiens and Saccharomyces cerevisiae.
• Mol Cell Biol. 1995; 15: 4702-10
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• Four cDNAs encoding human polypeptides hRPB7.0, hRPB7.6, hRPB17, and hRPB14.4 (referred to as Hs10 alpha, Hs10 beta, Hs8, and Hs6, respectively), homologous to the ABC10 alpha, ABC10 beta, ABC14.5, and ABC23 RNA polymerase subunits (referred to as Sc10 alpha, Sc10 beta, Sc8, and Sc6, respectively) of Saccharomyces cerevisiae, were cloned and characterized for their ability to complement defective yeast mutants. Hs10 alpha and the corresponding Sp10 alpha of Schizosaccharomyces pombe can complement an S. cerevisiae mutant (rpc10-delta::HIS3) defective in Sc10 alpha. The peptide sequences are highly conserved in their carboxy-terminal halves, with an invariant motif CX2CX12RCX2CGXR corresponding to a canonical zinc-binding domain. Hs10 beta, Sc10 beta, and the N subunit of archaeal RNA polymerase are homologous. An invariant CX2CGXnCCR motif presumably forms an atypical zinc-binding domain. Hs10 beta, but not the archaeal subunit, complemented an S. cerevisiae mutant (rpb10-delta 1::HIS3) lacking Sc10 beta. Hs8 complemented a yeast mutant (rpb8-delta 1::LYS2) defective in the corresponding Sc8 subunit, although with a strong thermosensitive phenotype. Interspecific complementation also occurred with Hs6 and with the corresponding Dm6 cDNA of Drosophila melanogaster. Hs6 cDNA and the Sp6 cDNA of S. pombe are dosage-dependent suppressors of rpo21-4, a mutation generating a slowly growing yeast defective in the largest subunit of RNA polymerase II. Finally, a doubly chimeric S. cerevisiae strain bearing the Sp6 cDNA and the human Hs10 beta cDNA was also viable. No interspecific complementation was observed for the human hRPB25 (Hs5) homolog of the yeast ABC27 (Sc5) subunit.

• Pati UK
• Human RNA polymerase II subunit hRPB14 is homologous to yeast RNA polymerase I, II, and III subunits (AC19 and RPB11) and is similar to a portion of the bacterial RNA polymerase alpha subunit.
• Gene. 1994; 145: 289-92
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• The cDNA cloning of the human polII 14-kDa subunit, hRPB14, and the comparison of its aa sequence with those of other pol subunits are described. The aa sequence of hRPB14 has homology to yeast poIII subunit RPB11 (44%), to a common subunit of yeast polI and polIII AC19 (24%) and to a Caenorhabditis elegans sequence (33%). hRPB14 contains a 19-aa motif, located in its N terminus, which was also found in human polII 33-kDa subunit hRPB33, yeast pol subunits (AC40, AC19, RPB3 and RPB11), and in the bacterial pol alpha subunit, which was involved in subunit assembly. This motif was also conserved in the conjugation-specific gene products of Tetrahymena (CnjC), Merchantia polymorpha chloroplast DNA (RNLVA) and C. elegans DNA (CEF58A4; deduced from the nucleotide sequence and of unknown function). The evolutionary emergence of a probable eukaryotic heterodimer, hRPB14/hRPB33, from a prokaryotic homodimer, alpha 2, is hypothesized.

• Takagaki Y, Manley JL
• A polyadenylation factor subunit is the human homologue of the Drosophila suppressor of forked protein.
• Nature. 1994; 372: 471-4
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• Polyadenylation of messenger RNA precursors is a complex process that requires multiple protein factors (for reviews, see refs 1, 2). Cleavage stimulation factor (CstF) is one of these, functioning together with cleavage-polyadenylation specificity factor, two cleavage factors, and poly(A)+ polymerase. CstF is composed of three subunits of M(r) 77, 64 and 50K. The 64K and 50K subunits contain, respectively, an RNP-type RNA-binding domain that contacts the pre-mRNA and transducin repeats characteristic of G-protein beta-subunits. Here we report the cloning and characterization of the 77K subunit of human CstF (referred to as 77K). We show that the 77K subunit is required for formation of active CstF and bridges the 64K and 50K subunits. Sequence analyses indicate that the 77K subunit is the homologue of the protein encoded by the Drosophila melanogaster suppressor of forked (su(f)) gene. Mutations in su(f) can enhance or suppress the effects of transposable element insertions, and our data indicate that this is due to changes in polyadenylation. Both the 77K subunit and the su(f) protein share homology with Saccharomyces cerevisiae RNA14, previously shown to be involved in mRNA metabolism. Our results thus also indicate that components of the complex polyadenylation machinery are conserved from yeast to man.

• McKune K, Woychik NA
• Halobacterial S9 operon contains two genes encoding proteins homologous to subunits shared by eukaryotic RNA polymerases I, II, and III.
• J Bacteriol. 1994; 176: 4754-6
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• One key component of the eukaryotic transcriptional apparatus is the multisubunit enzyme RNA polymerase II. We have discovered that two of the subunits shared by the three nuclear RNA polymerases in the yeast Saccharomyces cerevisiae, RPB6 and RPB10, have counterparts among the Archaea.

• McKune K, Woychik NA
• Functional substitution of an essential yeast RNA polymerase subunit by a highly conserved mammalian counterpart.
• Mol Cell Biol. 1994; 14: 4155-9
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• We isolated the cDNA encoding the homolog of the Saccharomyces cerevisiae nuclear RNA polymerase common subunit RPB6 from hamster CHO cells. Alignment of yeast RPB6 with its mammalian counterpart revealed that the subunits have nearly identical carboxy-terminal halves and a short acidic region at the amino terminus. Remarkably, the length and amino acid sequence of the hamster RPB6 are identical to those of the human RPB6 subunit. The conservation in sequence from lower to higher eukaryotes also reflects conservation of function in vivo, since hamster RPB6 supports normal wild-type yeast cell growth in the absence of the essential gene encoding RPB6.

• Azuma Y, Yamagishi M, Ishihama A
• Subunits of the Schizosaccharomyces pombe RNA polymerase II: enzyme purification and structure of the subunit 3 gene.
• Nucleic Acids Res. 1993; 21: 3749-54
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• To improve our understanding of the structure and function of eukaryotic RNA polymerase II, we purified the enzyme from the fission yeast Schizosaccharomyces pombe. The highly purified RNA polymerase II contained more than eleven polypeptides. The sizes of the largest the second-, and the third-largest polypeptides as measured by SDS-polyacrylamide gel electrophoresis were about 210, 150, and 40 kilodaltons (kDa), respectively, and are similar to those of RPB1, 2, and 3 subunits of Saccharomyces cerevisiae RNA polymerase II. Using the degenerated primers designed after amino acid micro-sequencing of the 40 kDa third-largest polypeptide (subunit 3), we cloned the subunit 3 gene (rpb3) and determined its DNA sequence. Taken together with the sequence of parts of PCR-amplified cDNA, the predicted coding sequence of rpb3, interrupted by two introns, was found to encode a polypeptide of 297 amino acid residues in length with a molecular weight of 34 kDa. The S. pombe subunit 3 contains four structural domains conserved for the alpha-subunit family of RNA polymerase from both eukaryotes and prokaryotes. A putative leucine zipper motif was found to exist in the C-terminal proximal conserved region (domain D). Possible functions of the conserved domains are discussed.

• Woychik NA, McKune K, Lane WS, Young RA
• Yeast RNA polymerase II subunit RPB11 is related to a subunit shared by RNA polymerase I and III.
• Gene Expr. 1993; 3: 77-82
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• The characterization of RNA polymerase subunit genes has revealed that some subunits are shared by the three nuclear enzymes, some are homologous, and some are unique to RNA polymerases I, II, or III. We report here the isolation and characterization of the yeast RNA polymerase II subunit RPB11, which is encoded by a single copy RPB11 gene located directly upstream of the topoisomerase I gene, TOPI, on chromosome XV. The sequence of the gene predicts an RPB11 subunit of 120 amino acids (13,600 daltons), only two amino acids shorter than the RPB9 polypeptide, that co-migrates with RPB11 under most SDS-PAGE conditions, RPB11 was found to be an essential gene that encodes a protein closely related to an essential subunit shared by RNA polymerases I and III, AC19. RPB11 contains a 19 amino acid segment found in three other yeast RNA polymerase subunits and the bacterial RNA polymerase subunit alpha. Some mutations that affect RNA polymerase assembly map within this segment, suggesting that this region may play a role in subunit interactions. As the isolation of RPB11 completes the isolation of known yeast RNA polymerase II subunit genes, we briefly summarize the salient features of these twelve genes and the polypeptides that they encode.

• Archambault J, Friesen JD
• Genetics of eukaryotic RNA polymerases I, II, and III.
• Microbiol Rev. 1993; 57: 703-24
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• The transcription of nucleus-encoded genes in eukaryotes is performed by three distinct RNA polymerases termed I, II, and III, each of which is a complex enzyme composed of more than 10 subunits. The isolation of genes encoding subunits of eukaryotic RNA polymerases from a wide spectrum of organisms has confirmed previous biochemical and immunological data indicating that all three enzymes are closely related in structures that have been conserved in evolution. Each RNA polymerase is an enzyme complex composed of two large subunits that are homologous to the two largest subunits of prokaryotic RNA polymerases and are associated with smaller polypeptides, some of which are common to two or to all three eukaryotic enzymes. This remarkable conservation of structure most probably underlies a conservation of function and emphasizes the likelihood that information gained from the study of RNA polymerases from one organism will be applicable to others. The recent isolation of many mutations affecting the structure and/or function of eukaryotic and prokaryotic RNA polymerases now makes it feasible to begin integrating genetic and biochemical information from various species in order to develop a picture of these enzymes. The picture of eukaryotic RNA polymerases depicted in this article emphasizes the role(s) of different polypeptide regions in interaction with other subunits, cofactors, substrates, inhibitors, or accessory transcription factors, as well as the requirement for these interactions in transcription initiation, elongation, pausing, termination, and/or enzyme assembly. Most mutations described here have been isolated in eukaryotic organisms that have well-developed experimental genetic systems as well as amenable biochemistry, such as Saccharomyces cerevisiae, Drosophila melanogaster, and Caenorhabditis elegans. When relevant, mutations affecting regions of Escherichia coli RNA polymerase that are conserved among eukaryotes and prokaryotes are also presented. In addition to providing information about the structure and function of eukaryotic RNA polymerases, the study of mutations and of the pleiotropic phenotypes they imposed has underscored the central role played by these enzymes in many fundamental processes such as development and cellular differentiation.

• Harrison DA, Mortin MA, Corces VG
• The RNA polymerase II 15-kilodalton subunit is essential for viability in Drosophila melanogaster.
• Mol Cell Biol. 1992; 12: 928-35
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• A small, divergently transcribed gene is located 500 bp upstream of the suppressor of Hairy-wing locus of Drosophila melanogaster. Sequencing of a full-length cDNA clone of the predominant 850-nucleotide transcript reveals that this gene encodes a 15,100-Da protein with high homology to a subunit of RNA polymerase II. The RpII15 protein is 46% identical to the RPB9 protein of Saccharomyces cerevisiae, one of the smallest subunits of RNA polymerase II from that species. Among those identical residues are four pairs of cysteines whose spacing is suggestive of two metal-binding "finger" domains. The gene is expressed at all developmental stages and in all tissues. Two deletions within the RpII15 gene are multiphasic lethal deletions, with accumulation of dead animals commencing at the second larval instar. Ovary transplantation experiments indicate that survival of mutant animals to this stage is due to the persistence of maternal gene product throughout embryogenesis and early larval development. The RpII15 gene product is thus necessary for viability of D. melanogaster.

• Seifarth W, Petersen G, Kontermann R, Riva M, Huet J, Bautz EK
• Identification of the genes coding for the second-largest subunits of RNA polymerases I and III of Drosophila melanogaster.
• Mol Gen Genet. 1991; 228: 424-32
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• 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)

• Woychik NA, Young RA
• RNA polymerase II: subunit structure and function.
• Trends Biochem Sci. 1990; 15: 347-51
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• RNA polymerase II is the core of the complex apparatus that is responsible for the regulated synthesis of mRNA. A comprehensive knowledge of RNA polymerase II is essential to our understanding of the molecular mechanisms through which a variety of transcription factors regulate eukaryotic gene expression. The recent cloning of genes for all ten subunits of yeast RNA polymerase II has revealed intriguing similarities and differences between the eukaryotic RNA polymerase and its simpler prokaryotic counterpart. Epitope tagging and other experiments made possible by the cloning of these genes have provided a clearer picture of RNA polymerase II subunit composition, stoichiometry and function, and set the stage for further investigating the dialogue between RNA polymerase II and transcription factors.

• Pati UK, Weissman SM
• The amino acid sequence of the human RNA polymerase II 33-kDa subunit hRPB 33 is highly conserved among eukaryotes.
• J Biol Chem. 1990; 265: 8400-3
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• We have cloned and sequenced a cDNA of 1766 base pairs in length encoding the 275 amino acids of hRPB 33, the third largest subunit of human RNA polymerase II. The DNA was isolated by screening of a human lambda gt11 cDNA library with oligonucleotides designed on the basis of the amino acid residue analysis of the bovine material. The hRPB 33 amino acid sequence is highly conserved between Saccharomyces cerevisiae and human. Overall, 45% of the amino acid residues are identical with the yeast homologue RPB 3, and 65% of the amino acids are identical in the two major conserved regions at residues 0-103 and 151-197. hRPB 33 is also homologous to yeast RPC 5. The amino acid sequence of hRPB 33 showed no obvious homology with bacterial RNA polymerase or with any of its sigma factors.

• Pati UK, Weissman SM
• Isolation and molecular characterization of a cDNA encoding the 23-kDa subunit of human RNA polymerase II.
• J Biol Chem. 1989; 264: 13114-21
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• We have shown that antibodies against native calf thymus RNA polymerase II and antibodies against its 23-kDa subunit cross-reacted with the 23-kDa subunit of human RNA polymerase II. Immunoglobin G (IgG) against the 23-kDa subunit of calf thymus RNA polymerase II inhibited transcription in vitro from the adenovirus major late promoter. By immunoscreening of a human placenta lambda gt11 cDNA library with IgG against native CT RNA polymerase II and with IgG against its 23-kDa subunit, we isolated and characterized a full length 1.2-kilobase cDNA. We also generated oligonucleotide probes from a sequence of amino acid residues obtained by a modified peptide microsequencing procedure. The cDNAs isolated both from oligoscreening and immunoscreening were identical. The amino acid sequence deduced from the nucleotide sequence analysis indicates a polypeptide of 197 amino acid (23 kDa). The in vitro translation product of human cDNA HP-23 was precipitated by IgG against the 23-kDa subunit of CT RNA polymerase II. The amino acid sequence deduced from HP-23 showed no obvious homology with Escherichia coli RNA polymerase subunits or with any of its sigma factors.

• Smale ST, Baltimore D
• The "initiator" as a transcription control element.
• Cell. 1989; 57: 103-13
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• Transcription of the lymphocyte-specific terminal deoxynucleotidyltransferase gene begins at a single nucleotide, but no TATA box is present. We have identified a 17 bp element that is sufficient for accurate basal transcription of this gene both in vitro and in vivo. This motif, the initiator (Inr), contains within itself the transcription start site. Homology to the Inr is found in many TATA-containing genes, and specific mutagenesis influences both the efficiency and accuracy of initiation. Moreover, in the presence of either a TATA box or the SV40 21 bp repeats, a greatly increased level of transcription initiates specifically at the Inr. Thus, the Inr constitutes the simplest functional promoter that has been identified and provides one explanation for how promoters that lack TATA elements direct transcription initiation.

• Smith JL, Levin JR, Ingles CJ, Agabian N
• 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.
• Cell. 1989; 56: 815-27
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• 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.

• Kontermann R, Sitzler S, Seifarth W, Petersen G, Bautz EK
• Primary structure and functional aspects of the gene coding for the second-largest subunit of RNA polymerase III of Drosophila.
• Mol Gen Genet. 1989; 219: 373-80
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• We have cloned and sequenced the gene coding for the second-largest subunit of RNA polymerase III of Drosophila melanogaster (DmRP135). The gene, interrupted by two introns of 62 and 59 bp, respectively, codes for an mRNA of 3.6 kb. As for other housekeeping genes transcription initiates at several sites (between positions -98 and -76) none of which is preceded by a clear TATA sequence. The deduced polypeptide consists of 1129 amino acids with an aggregate molecular weight of 128 kDa. The protein sequence features the same regions of similarity as observed for the corresponding subunits of RNA polymerase II of Drosophila and yeast and the Escherichia coli beta subunit. As in the second-largest subunit of RNA polymerase II there is a zinc-binding motif which is absent in the beta subunit of E. coli. Antibodies directed against a fusion protein expressing 164 amino acids of the DmRP135 polypeptide cross-react with the second-largest subunit of RNA polymerase III of yeast and generate a distinct banding pattern on Drosophila polytene chromosomes distinguishable from that obtained with anti-RNA polymerase II antibodies.

• Cho KW, Khalili K, Zandomeni R, Weinmann R
• The gene encoding the large subunit of human RNA polymerase II.
• J Biol Chem. 1985; 260: 15204-10
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• As a first step to approach the structural and functional analysis of DNA-dependent RNA polymerase II (EC 2.7.7.8), we have isolated genomic sequences for the large subunit of the human enzyme. The sequences homologous to Drosophila RNA polymerase II large subunit sequences are present in the genome as single copy genes, when assayed at high stringency. The polypeptide information is encoded in a mRNA of 7.35 kilobases, as determined by Northern blot analysis. In vitro translation reveals a polypeptide of 220 kDa, similar in electrophoretic mobility to the largest subunit of the enzyme. A fusion-polypeptide synthesized in bacteria contains a region that cross-reacts with anti-RNA polymerase II antiserum. Antiserum directed against the purified fusion protein reacts with the large subunit of RNA polymerase II, whether in the intact IIA (220 kDa) or in the degraded IIB (180 kDa) forms. Moreover, the antifusion protein antibody inhibits not only the purified calf thymus RNA polymerase II activity but also specific RNA polymerase II transcription in a HeLa cell extract. Thus, the DNA fragment isolated contains structural and functional domains of the human RNA polymerase II large subunit.