EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rat cells contain a DNA-binding polymerase I transcription factor, rUBF, with properties similar to UBF homologs that have been purified from both human (hUBF) and frog (xUBF) cells. In this note we report the affinity purification of rUBF to apparent homogeneity and show that UBFs from both rat and frog have identical footprinting characteristics on templates from either species. Furthermore, xUBF was able to stimulate transcription from rat RNA polymerase I promoters in a partially fractionated rat extract that was UBF dependent. These results strengthen the conclusion that all vertebrate cells contain a UBF homolog whose DNA-binding specificity and function have been strongly conserved.
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PMID:rUBF, an RNA polymerase I transcription factor from rats, produces DNase I footprints identical to those produced by xUBF, its homolog from frogs. 235 24

How can trans-activators with the same DNA binding specificity direct different transcriptional programs? The rRNA transcriptional apparatus offers a useful model system to address this question and to dissect the mechanisms that generate alternative transcription complexes. Here, we compare the mouse and human transcription factors that govern species-specific RNA polymerase I promoter recognition. We find that both human and mouse rRNA transcription is mediated by a specific multiprotein complex. One component of this complex is the DNA-binding transcription factor, UBF. Paradoxically, human and mouse UBF display identical DNA binding specificities even though transcription of rRNA is species specific. Promoter selectivity is conferred by a second essential factor, SL1, which, for humans, does not bind DNA independently but, instead, cooperates with UBF in the formation of high-affinity DNA-binding complexes. In contrast, mouse SL1 can selectively interact with DNA in the absence of UBF. Reconstituted transcription experiments establish that UBF and RNA polymerase I from the two species are functionally interchangeable, whereas mouse and human SL1 exhibit distinct DNA binding and transcription activities. Together, these results suggest a critical role for a specific multiprotein assembly in RNA polymerase I promoter recognition and reveal distinct mechanisms through which such complexes can generate functional diversity.
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PMID:Assembly of alternative multiprotein complexes directs rRNA promoter selectivity. 238 15

The intergenic spacer of the mouse ribosomal genes contains repetitive 140-base-pair (bp) elements which we show are enhancers for RNA polymerase I transcription analogous to the 60/81-bp repetitive enhancers (enhancers containing a 60-bp and an 81-bp element) previously characterized from Xenopus laevis. In rodent cell transfection assays, the 140-bp repeats stimulated an adjacent mouse polymerase I promoter when located in cis and competed with it when located in trans. Remarkably, in frog oocyte injection assays, the 140-bp repeats enhanced a frog ribosomal gene promoter as strongly as did the homologous 60/81-bp repeats. Mouse 140-bp repeats also competed against frog promoters in trans. The 140-bp repeats bound UBF, a DNA-binding protein we have purified from mouse extracts that is the mouse homolog of polymerase I transcription factors previously isolated from frogs and humans. The DNA-binding properties of UBF are conserved from the mouse to the frog. The same regulatory elements (terminators, gene and spacer promoters, and enhancers) have now been identified in both a mammalian and an amphibian spacer, and they are found in the same relative order. Therefore, this arrangement of elements probably is widespread in nature and has important functional consequences.
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PMID:Enhancers for RNA polymerase I in mouse ribosomal DNA. 238 26

Control of mouse ribosomal RNA synthesis in response to extracellular signals is mediated by TIF-IA, a regulatory factor whose amount or activity correlates with cell proliferation. Factor TIF-IA interacts with RNA polymerase I (pol I), thus converting it into a transcriptionally active holoenzyme, which is able to initiate specifically at the rDNA promoter in the presence of the other auxiliary transcription initiation factors, designated TIF-IB, TIF-IC and UBF. With regard to several criteria, the growth-dependent factor TIF-IA behaves like a bacterial sigma factor: (i) it associates physically with pol I, (ii) it is required for initiation of transcription, (iii) it is present in limiting amounts and (iv) under certain salt conditions, it is chromatographically separable from the polymerase. In addition, evidence is presented that dephosphorylation of pol I abolishes in vitro transcription initiation from the ribosomal gene promoter without significantly affecting the polymerizing activity of the enzyme at nonspecific templates. The involvement of both a regulatory factor and post-translational modification of the transcribing enzyme provides an efficient and versatile mechanism of rDNA transcription regulation which enables the cell to adapt ribosome synthesis rapidly to a variety of extracellular signals.
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PMID:A growth-dependent transcription initiation factor (TIF-IA) interacting with RNA polymerase I regulates mouse ribosomal RNA synthesis. 239 Sep 74

Human ribosomal RNA synthesis by RNA polymerase I requires the activator UBF and the promoter selectivity factor SL1, which consists of the TATA binding protein (TBP) and three associated subunits, TAFI110, TAFI63, and TAFI48. Here it is shown that both TAFI110 and TAFI63 contact the promoter, whereas TAFI48 serves as a target for interaction with UBF and is required to form a transcriptionally active SL1 complex responsive to UBF in vitro. TAFI48 also alters the ability of TBP to interact with TATA box elements, and the resulting complex fails to support transcription by RNA polymerase II. Thus, TAFI48 may function both as a target to mediate UBF activation and as a class-specific promoter selectivity factor.
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PMID:Coactivator and promoter-selective properties of RNA polymerase I TAFs. 749

During mitosis, ribosomal genes are associated with a set of silver-stained nucleolar proteins designated Ag-nucleolar organizer region (NOR) proteins. The amount of Ag-NOR protein, estimated during interphase, may be used as marker of cell proliferation with a prognostic value for several human cancers. Our objective was to identify the Ag-NOR proteins in human transformed cell lines at specific phases of the cell cycle and in a hamster cell line that serves as model for active ribosomal transcription. During interphase, the major Ag-NOR proteins in both human and hamster cells were nucleolin and protein B23 and also proteins of 42, 40, and 29 kDa, which accounted for a small amount of the silver stain. The pIs of these proteins were between 4.5 and 5.6. During mitosis, the Ag-NOR proteins were either solubilized in the cytoplasm, distributed around the chromosomes, or associated with the ribosomal genes, i.e., in the NORs. The major Ag-NOR proteins associated with the ribosomal genes were the largest RNA polymerase I subunit, the 135-kDa NOR protein, the UBF transcription factor, and a 50-kDa protein. Less than 5% of the total nucleolin remained associated with ribosomal genes during mitosis. Using the purified RNA polymerase I complex from yeast, we demonstrate that the 190-, 43-, and 34.5-kDa subunits are Ag-NOR proteins in this species. This study demonstrates that the major Ag-NOR proteins in nucleoli during interphase are not the same as those associated with the ribosomal genes during mitosis. We conclude that the prognostic test for human cancer cell proliferation is largely based on the amount of the nucleolar proteins, nucleolin, and protein B23, which are not directly involved in ribosomal gene transcription. In contrast, the evaluation of active NORs in karyotypes during mitosis is based on the presence of some proteins of the ribosomal gene transcription machinery.
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PMID:Identification of Ag-NOR proteins, markers of proliferation related to ribosomal gene activity. 752 52

The organization of the U3, U8, and U13 small nucleolar ribonucleoproteins (snoRNPs) has been investigated in HeLa cells using antisense DNA and 2'-OMe RNA oligonucleotides. Oligomers corresponding to deoxynucleotides that target RNase H degradation of intact RNP particles were synthesized and used for fluorescence in situ hybridization. U3 and U13 are distributed throughout the nucleolus and colocalize with anti-fibrillarin antibodies. U8, however, is organized in discrete ring-like structures near the center of the nucleolus and surround bright punctate regions visualized with anti-RNA polymerase I and anti-UBF/NOR-90 antibodies. In decondensed nucleoli, a necklace of smaller ring-like structures of U8 RNA appear. A model for the recruitment of U8 (and presumably other processing factors) to the sites of rRNA transcription is discussed. Hybridization to mitotic cells showed that unlike pol I and NOR-90, U8 is dispersed into the cytoplasm during mitosis. The subnucleolar organization of U8 is consistent with its demonstrated participation in early intermediate steps in pre-rRNA processing. In contrast, the more dispersed intranucleolar distribution of U3 agrees with its putative involvement in both early and late steps of rRNA maturation. These studies illustrate the feasibility of mapping functional domains within the nucleolus by correlating the in vitro activities of small nuclear RNPs with their in situ locations.
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PMID:Organization of small nucleolar ribonucleoproteins (snoRNPs) by fluorescence in situ hybridization and immunocytochemistry. 753 31

Serum P419 from a patient with rheumatoid arthritis with a high specificity immunolabeling nucleoli in various mammalian cells has been identified. On the Western blots of total cellular proteins or proteins extracted from isolated nucleoli it cross-reacted with a doublet of polypeptides of 97 and 94 kDa. That is why this serum has been concluded to recognize UBF, or RNA polymerase I-specific transcription initiation factor. It was shown that UBF remained bound to the nucleoli or nucleolus organizing regions (NORs) of mitotic chromosomes despite the level of rDNA transcription. Nevertheless, intranucleolar localization of UBF was dramatically changed after partial or complete block of rRNA synthesis. In pycnotic cells positive labeling was found within the whole nucleus and cytoplasm instead of nucleolus. In metaphase UBF molecules are unequally distributed between the particular NORs, whereas in anaphase they are uniformly allocated between the daughter cells.
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PMID:[The immunolocalization of the ribosomal gene transcription initiation factor UBF in the interphase and mitosis]. 757 Oct 17

Ribosomal DNA transcription is important to the regulation of cardiomyocyte ribosome content and, as a consequence, the rate of protein synthesis and accumulation during cardiac hypertrophy. We studied the regulation of ribosomal RNA synthesis and the levels of RNA polymerase I and the ribosomal DNA transcription factor, UBF, during norepinephrine-induced hypertrophy of contraction-arrested neonatal cardiomyocytes in culture. Nuclear run-on assays and Western blots demonstrated that, concomitant with hypertrophy, norepinephrine (1 microM) increased the rate of ribosomal DNA transcription, without causing an increase in the amount of RNA polymerase I. However, the elevated rate of rRNA synthesis was accompanied by an increased cellular content of UBF protein as determined by Western analysis. Northern blots demonstrated norepinephrine-induced increases in UBF mRNA in neonatal cardiomyocytes indicating that the response was regulated, at least in part, at the pretranslational stage. Both alpha- and beta-adrenergic agents increased the level of UBF mRNA. The beta-adrenergic response was mimicked by forskolin (1 microM) and the cyclic AMP analog dibutyryl cAMP (10 microM). However, activation of protein kinase C by phorbol 12-myristate 13-acetate (0.1 microM) did not increase expression of UBF. These results implicate UBF as a possible regulatory factor of the accelerated rDNA transcription observed during norepinephrine-mediated cardiomyocyte hypertrophy.
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PMID:Regulation of rDNA transcription factors during cardiomyocyte hypertrophy induced by adrenergic agents. 771 37

The abundant and highly-conserved nucleoproteins comprising the high mobility group-1/2 (HMG-1/2) family contains two homologous basic domains of about 75 amino acids. These basic domains, termed HMG-1 boxes, are highly structured and facilitate HMG-DNA interactions. Many proteins that regulate various cellular functions involving DNA binding and whose target DNA sequences share common structural characteristics have been identified as having an HMG-1 box; these proteins include the RNA polymerase I transcription factor UBF, the mammalian testis-determining factor SRY and the mitochondrial transcription factors ABF2 and mtTF1, among others. The sequences of 121 HMG-1 boxes have been compiled and aligned in accordance with thermodynamic results from homology model building (threading) experiments, basing the alignment on structure rather than by using traditional sequence homology methods. The classification of a representative subset of these proteins was then determined using standard least-squares distance methods. The proteins segregate into two groups, the first consisting of HMG-1/2 proteins and the second consisting of proteins containing the HMG-1 box but which are not canonical HMG proteins. The proteins in the second group further segregate based on their function, their ability to bind specific sequences of DNA, or their ability to recognize discrete non-B-DNA structures. The HMG-1 box provides an excellent example of how a specific protein motif, with slight alteration, can be used to recognize DNA in a variety of functional contexts.
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PMID:The HMG-1 box protein family: classification and functional relationships. 778 17

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