UNIPROT:P06889 - FACTA Search

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A rapid method suitable for purifying large amounts of mitochondria from rat liver using isopycnic zonal centrifugation is described. The RNA polymerase isolated from the purified mitochrondria was found associated with one peak when resolved by DEAE Sephadex chromatography. The enzyme was next fractionated on a phosphocellulose column followed by glycerol gradient centrifugation. A 600-fold purification was achieved when the enzyme was finally filtered through agarose gel. This final enzyme fraction consisted of one polypeptide chain as shown by polyacrylamide gel electrophoresis profiles. The enzyme has a greater preference for poly [d(A-T)] templates than for rat liver mitochondrial DNA. Inhibition of the enzyme activity required high concentrations of the inhibitors. The resistance of the enzyme to alpha-amanitin indicated that there was no contamination from nuclear RNA polymerase II. The conclusion is drawn that the mitochondrial RAN polymerase activity is associated with a single polypeptide.
Mol Cell Biochem 1976 Dec 10
PMID:Some properties of rat liver mitochondrial RNA polymerase. 100 1

Three genes encoding U4 small nuclear RNA (U4 snRNA) in the higher plant Arabidopsis thaliana have been isolated and characterized. Two of the genes, AtU4.1 and AtU4.2, contain all the transcriptional signals known to be essential for U-snRNA gene activity in dicot plants: the Upstream Sequence Element (USE), the -30 TATA box and the downstream 3' end formation sequence. The USE and TATA elements are centered approximately four helical DNA turns apart, a feature characteristic of RNA polymerase II-transcribed U-snRNA genes of plants. The genes AtU4.1 and AtU4.2 are actively transcribed in transfected plant protoplasts and in Arabidopsis plants. Expression of the third gene, AtU4.3, could not be demonstrated. Since this gene is missing the downstream signal important for RNA 3' end formation, it probably represents a pseudogene. The genes AtU4.1 and AtU4.2 encode 152-153 nt long RNAs which show 85-89% sequence similarity with broad bean and pea U4 RNAs and 60-65% similarity with mammalian U4 RNAs. Arabidopsis U4 and U6 snRNAs can be folded into the base-paired Y-shaped model supporting the importance of the U4/U6 interaction during pre-mRNA splicing in plants as well as animals.
Mol Biol Rep 1992 Nov
PMID:Characterization of the genes encoding U4 small nuclear RNAs in Arabidopsis thaliana. 128 76

We have studied the initiation of transcription in vitro by RNA polymerase II on simian virus 40 (SV40) minichromosomal templates isolated from infected cells. The efficiency and pattern of transcription from the chromatin templates were compared with those from viral DNA templates by using two in vitro transcription systems, either HeLa whole-cell extract or basal transcription factors, RNA polymerase II, and one of two SV40 promoter-binding transcription factors, LSF and Sp1. Dramatic increases in numbers of transcripts upon addition of transcription extract and different patterns of usage of the multiple SV40 initiation sites upon addition of Sp1 versus LSF strongly suggested that transcripts were being initiated from the minichromosomal templates in vitro. That the majority of transcripts from the minichromosomes were due to initiation de novo was demonstrated by the efficient transcription observed in the presence of alpha-amanitin, which inhibited minichromosome-associated RNA polymerase II, and an alpha-amanitin-resistant RNA polymerase II, which initiated transcription in vitro. The pattern of transcription from the SV40 late and early promoters on the minichromosomal templates was similar to the in vivo pattern of transcription during the late stages of viral infection and was distinct from the pattern of transcription generated from viral DNA in vitro. In particular, the late promoter of the minichromosomal templates was transcribed with high efficiency, similar to viral DNA templates, while the early-early promoter of the minichromosomal templates was inhibited 10- to 15-fold. Finally, the number of minichromosomes competent to initiate transcription in vitro exceeded the amount actively being transcribed in vivo.
Mol Cell Biol 1992 Apr
PMID:In vitro initiation of transcription by RNA polymerase II on in vivo-assembled chromatin templates. 131 66

We show that nuclear extract from Drosophila Kc cells supports efficient elongation by RNA polymerase II initiated from the actin 5C promoter. The addition of 0.3% Sarkosyl, 1 mg of heparin per ml, or 250 mM KCl immediately after initiation has two effects. First, the elongation rate is reduced 80 to 90% as a result of the inhibition of elongation factors. Second, there is an increase in the amount of long runoff RNA, suggesting that there is an early block to elongation that is relieved by the disruptive reagents. Consistent with the first effect, we find that the ability of factor 5 (TFIIF) to stimulate the elongation rate is inhibited by the disruptive agents when assayed in a defined system containing pure RNA polymerase II and a dC-tailed template. The disruptive agents also inhibit the ability of DmS-II to suppress transcriptional pausing but only slightly reduce the ability of DmS-II to increase the elongation rate twofold. The pause sites encountered by RNA polymerase II after initiation at a promoter and subsequent treatment with the disruptive reagents are also recognized by pure polymerase transcribing a dC-tailed template. It has been suggested that 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole inhibits RNA polymerase II during elongation, but we find that the purine nucleoside analog has no effect on elongation complexes containing RNA over 500 nucleotides in length or on the action of factor 5 or DmS-II in the defined system.
Mol Cell Biol 1992 May
PMID:Stability of Drosophila RNA polymerase II elongation complexes in vitro. 137 6

The insulin-like growth factor-binding proteins (IGFBPs) are a family of proteins that specifically bind IGF-I and IGF-II, determine their bioavailability to tissues, and modulate their actions in target tissues. Levels of IGFBPs in plasma and IGFBP mRNAs in liver are highly regulated with developmental age and metabolic status. We now demonstrate that the increase in IGFBP-2 mRNA in fasted adult rat liver and in the liver of normal neonatal rats reflects an increased rate of transcription. When adult rats were fasted for 2-3 days, IGFBP-2 mRNA was increased in liver, but not in brain or kidney. The increase in hepatic IGFBP-2 mRNA was observed after only 1 day of fasting. Levels decreased by half after 6 h of refeeding and returned to their low starting values after 2 days of refeeding. Transcription-elongation experiments indicated that transcription of the IGFBP-2 gene was increased in fasted liver. The rate of transcription increased 9.2- +/- 3.5-fold for transcripts labeled in exon 1 and 6.6- +/- 2.4-fold for transcripts labeled in exons 2, 3, and 4, suggesting that fasting causes a uniform increase in the number of RNA polymerase II molecules along the length of the IGFBP-2 gene. We infer from these results that the regulation of IGFBP-2 gene transcription in fasting occurs at the level of initiation rather than elongation. IGFBP-2 gene transcription also was increased 3.8- +/- 1.2-fold (exon 1) and 2.9- +/- 0.9-fold (exons 2, 3, and 4) in nuclei from 2-day postnatal rat liver compared with adult rat liver, consistent with the greater abundance of IGFBP-2 mRNA in neonatal rat liver.
Mol Endocrinol 1992 Aug
PMID:Transcription of the insulin-like growth factor-binding protein-2 gene is increased in neonatal and fasted adult rat liver. 138 92

The assembly of an RNA polymerase II initiation complex at a promoter is associated with the melting of the DNA template to allow the polymerase to read the DNA sequence and synthesize the corresponding RNA. Using the specific single-stranded modifying reagent KMnO4 and a new genomic sequencing technique, we have explored the melted regions of specific genes in genomic DNA of whole cells or of isolated nuclei. We have demonstrated for the first time in vivo the melting in the promoter proximal transcribed region that is associated with the presence of RNA polymerase II complexes. An interferon-inducible gene, ISG-54, exhibited KMnO4 sensitivity over approximately 300 nucleotides downstream of the RNA initiation site in interferon-treated cells when the gene was actively transcribed but not in untreated cells where the gene was not transcribed. The extent of KMnO4 modification was proportional to transcription levels. The KMnO4 sensitivity was retained when nuclei were isolated from induced cells but was lost if the engaged polymerases were further allowed to elongate the nascent RNA chains ("run-on"). The sensitivity to KMnO4 in isolated nuclei was retained if the run-on incubation was performed in the presence of alpha-amanitin, which blocks progress of engaged polymerases. A similar analysis identified an open sequence of only approximately 30 bases just downstream of the start site of the transthyretin (TTR) gene in nuclei isolated from mouse liver, a tissue where TTR is actively transcribed. This abrupt boundary of KMnO4 sensitivity, which was removed completely by allowing engaged polymerases to elongate RNA chains, suggests that most polymerases transcribing this gene paused at about position +20. The possibility of mapping at the nucleotide level the position of actively transcribing RNA polymerases in whole cells or isolated nuclei opens new prospects in the study of transcription initiation and elongation.
Mol Biol Cell 1992 Oct
PMID:Mapping of RNA polymerase on mammalian genes in cells and nuclei. 138 13

The initiation of RNA polymerase II transcription is controlled by DNA sequence-specific activator proteins, in combination with cofactor polypeptides whose function is poorly understood. Transcriptional cofactors of the CTF-1 activator were purified on the basis of their affinity for the regulatory protein. These purified cofactors were found to be required for CTF-1-regulated transcription, and they counteracted squelching by an excess of activator in in vitro reconstitution experiments. Interestingly, the cofactors possessed an inhibitory activity for basal transcription, which was relieved by the further addition of the activator. Histone H1 also contributes to the regulation of transcription by CTF-1, whereby the activator prevents repression of the basal transcription machinery by the histone. However, histone H1 could not replace the cofactors for CTF-1-regulated transcription, indicating that they possess distinct transcriptional properties. Furthermore, the purified cofactors were found to be required, together with the activator, in order to antagonize the histone-mediated repression of transcription. These results suggest that CTF-1 and its cofactors function by regulating the assembly of the basal transcription machinery onto the promoter when the latter is in competition with DNA-binding inhibitory proteins such as histone H1.
Mol Cell Biol 1992 Nov
PMID:Purified cofactors and histone H1 mediate transcriptional regulation by CTF/NF-I. 140 93

The ability of the c-Jun protein, the main component of the transcription factor AP1, to interact directly or indirectly with the RNA polymerase II-initiation complex to activate transcription was investigated by in vivo transcription interference ("squelching") experiments. Coexpression of a Jun mutant lacking its DNA binding domain strongly represses the activity of wild-type c-Jun. Repression depends on the presence of the transactivation domains (TADs), suggesting that a limiting factor interacting with the TADs is essential to link Jun and the components of the transcriptional machinery. The activity of this intermediary factor(s) is restricted to TADs characterized by an abundance of negatively charged amino acids, as demonstrated by the abilities of the TADs of JunB, GAL4, and VP16 to repress c-Jun activity. Depending on the presence of the TADs of Jun, we found physical interaction between Jun and a cluster of three proteins with molecular masses of 52, 53, and 54 kDa (p52/54). Association between Jun and p52/54 is strongly reduced in the presence of VP16, suggesting that the two proteins compete for binding to p52/54. Transcription factors containing a different type of TAD (e.g., GHF1, estrogen receptor, or serum response factor) fail to inhibit Jun activity, suggesting that these proteins act through a different mechanism. We consider the requirement of Jun to interact with p52/54 utilized by other transcription factors a new mechanism in the regulation of transcription of Jun-dependent target genes.
Mol Cell Biol 1992 Dec
PMID:A common intermediary factor (p52/54) recognizing "acidic blob"-type domains is required for transcriptional activation by the Jun proteins. 144 82

We have previously shown that transcription of the Xenopus U6 snRNA gene by RNA polymerase III is stimulated in injected Xenopus oocytes by an activator element termed the DSE, which contains an octamer sequence. Data presented here reveal that the DSE contains, in addition, a GC-rich sequence capable of binding Sp1. Both elements are required to obtain wild-type levels of U6 transcription in vivo. The Xenopus U6 DSE exhibits optimal activation properties only when positioned at its normal location upstream from the start site. The U6 Sp1 motif binds the mammalian Sp1 transcriptional activator independently of the Oct-1 protein in vitro. Those mutations that lead to a reduced transcription level in vivo abolish the binding of Sp1 in vitro. Thus, transcriptional stimulation through the Xenopus U6 Sp1 motif is likely to be mediated by a protein with DNA-binding specificity identical to mammalian Sp1. These findings support the notion that RNA polymerase II and III transcription complexes share transactivators.
J Mol Biol 1992 Nov 20
PMID:A factor with Sp1 DNA-binding specificity stimulates Xenopus U6 snRNA in vivo transcription by RNA polymerase III. 145 50

We have isolated and sequenced a portion of the gene encoding the carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II from three mammals. These mammalian sequences include one rodent and two primate CTDs. Comparisons of the new sequences to mouse and Chinese hamster show a high degree of conservation among the mammalian CTDs. Due to synonymous codon usage, the nucleotide differences between hamster, rat, ape, and human result in no amino acid changes. The amino acid sequence for the mouse CTD appears to have one different amino acid when compared to the other four sequences. Therefore, except for the one variation in mouse, all of the known mammalian CTDs have identical amino acid sequences. This is in marked contrast to the situation among more divergent species. The present study suggests that there is a strong evolutionary pressure to maintain the primary structure of the mammalian CTD.
J Mol Evol 1992 Nov
PMID:Conservation of the mammalian RNA polymerase II largest-subunit C-terminal domain. 148 24

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