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)

We present evidence that the genes encoding U3 snRNA in plants are transcribed by RNA polymerase III (pol III) and not by RNA polymerase II (pol II) as in vertebrates or lower eukaryotes. The U3 gene is the only known example of a gene transcribed by different polymerases in different organisms. It is possible to convert the plant U3 gene into a functional pol II-transcribed gene by manipulating the spacing between the promoter elements and inserting a pol II-specific termination signal. Pol II-transcribed U3 RNA, containing the 5'-terminal cap different from that present in the wild-type counterpart, is packaged in transfected protoplasts into U3 snRNP precipitable with anti-fibrillarin antibodies. These findings provide further evidence for the common ancestry of the pol II and pol III transcription systems, and indicate that promoter diversification in some genes has occurred relatively recently.
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PMID:Alteration of the RNA polymerase specificity of U3 snRNA genes during evolution and in vitro. 182 60

The ability of series of U1 snRNAs and U6 snRNAs to migrate into the nucleus of Xenopus oocytes after injection into the cytoplasm was analyzed. The U snRNAs were made either by injecting U snRNA genes into the nucleus of oocytes or, synthetically, by T7 RNA polymerase, incorporating a variety of cap structures. The results indicate that nuclear targeting of U1 snRNA requires both a trimethylguanosine cap structure and binding of at least one common U snRNP protein. Using synthetic U6 snRNAs, it is further demonstrated that the trimethylguanosine cap structure can act in nuclear targeting in the absence of the common U snRNP proteins. These results imply that U snRNP nuclear targeting signals are of a modular nature.
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PMID:The trimethylguanosine cap structure of U1 snRNA is a component of a bipartite nuclear targeting signal. 214 5

Previously we showed that microinjection of purified U2 snRNA from HeLa cells into Xenopus laevis oocytes, depleted of their endogenous U2 snRNPs by oligonucleotide-targeted degradation, led to assembly of hybrid snRNPs that were fully functional for splicing of SV40 late pre-mRNA. We have extended these results by examining features of U2 RNA that are required for its role in splicing. Injection of Xenopus U2 snRNA transcribed in vitro by T7 RNA polymerase, differing in sequence from authentic U2 by only one nucleotide, although capable of efficient assembly into snRNP-like particles, did not complement U2-predepleted oocytes for splicing. However, when injected into pretargeted oocytes, a plasmid containing Xenopus U2 snRNA sequences resulted in synthesis of U2 snRNA that was assembled into snRNPs capable of mediating splicing of SV40 late pre-mRNA. This allowed us to test several U2 RNA mutants for their function in splicing. Mutants with sequences deleted within U2 stem-loops I and II, although efficiently assembled into snRNP-like particles upon injection, failed to restore splicing. Interestingly, however, injection of a mutant that lacks the binding site for the U2-specific proteins A' and B", restored pre-mRNA splicing. These data suggest that the direct binding of U2-specific proteins with snRNA is not essential for the function of U2 snRNPs in splicing of pre-mRNA.
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PMID:U2 snRNA sequences that bind U2-specific proteins are dispensable for the function of U2 snRNP in splicing. 255 72

The ability of purified U1 small nuclear RNA-protein complexes (U1 snRNPs) to bind in vitro to two RNAs transcribed from recombinant DNA clones by bacteriophage T7 RNA polymerase has been studied. A transcript which contains sequences corresponding to the small intron and flanking exons of the major mouse beta-globin gene is bound in marked preference to an RNA devoid of splice site sequences. The site of U1 snRNP binding to the globin RNA has been defined by T1 ribonuclease digestion of the RNA-U1 snRNP complex. A 15-17-nucleotide region, including the 5' splice site, remains undigested and complexed with the snRNP such that it can be co-precipitated by antibodies directed against the U1 snRNP. Partial proteinase K digestion of the U1 snRNP abolishes interaction with the globin RNA, indicating that the snRNP proteins contribute significantly to RNA binding. No RNA cleavage, splicing, or recognition of the 3' splice site by U1 snRNPs has been detected. Our results are discussed in terms of the probable role of U1 snRNPs in the messenger RNA splicing of eucaryotic cell nuclei.
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PMID:The U1 small nuclear RNA-protein complex selectively binds a 5' splice site in vitro. 619 May 73

The Xenopus egg and embryo, throughout the transcriptionally inactive early cleavage period, were found to contain a store of approximately 8 X 10(8) molecules of the small nuclear RNA (snRNA) U1, sufficient for 4,000-8,000 nuclei. In addition, when transcription is activated at the twelfth cleavage (4,000 cell-stage), the snRNAs U1, U2, U4, U5, and U6 are major RNA polymerase II products. From the twelfth cleavage to gastrulation, U1 RNA increases sevenfold in 4 h, paralleling a similar increase in nuclear number. This level of snRNA transcription is much greater than that typical of somatic cells, implying a higher rate of U1 transcription or a greater number of U1 genes active in the embryo. The Xenopus egg also contains snRNP proteins, since it has the capacity to package exogenously added snRNA into immunoprecipitable snRNP particles, which resemble endogenous particles in both sedimentation coefficient and T1 RNase digestibility. SnRNP proteins may recognize conserved secondary structure of U1 snRNA since efficient packaging of both mouse and Drosophila U1 RNAs, differing 30% in sequence, occurs. The Xenopus egg and embryo can be used to pose a number of interesting questions about the transcription, assembly, and function of snRNA.
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PMID:Small nuclear RNA transcription and ribonucleoprotein assembly in early Xenopus development. 619 Aug 22

As they are transcribed, RNA polymerase II transcripts (hnRNAs or pre-mRNAs) associate with hnRNP proteins and snRNP particles, and the processing of pre-mRNA occurs within these ribonucleoprotein complexes. To better understand the relationship between hnRNP proteins and snRNP particles and their roles in mRNA formation, we have visualized them as they associate with nascent transcripts on the polytene chromosomes of Drosophila melanogaster salivary glands. Simultaneous pairwise detection of the abundant hnRNP proteins hrp36, hrp40, and hrp48 by direct double-label immunofluorescence microscopy reveals all of these proteins are bound to most transcripts, but their relative amounts on different transcripts are not fixed. Numerous differences in the relative amounts of snRNP particles and hnRNP proteins on nascent transcripts are also observed. These observations directly demonstrate that individual hnRNP proteins and snRNP particles are differentially associated with nascent transcripts and suggest that different pre-mRNAs bind different combinations of these factors to form transcript-specific, rather than a single type of, hnRNA-hnRNP-snRNP complexes. The distinct and specific constellation of hnRNP proteins and snRNP particles that assembles on different pre-mRNAs is likely to affect the fate and pathway of processing of these transcripts.
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PMID:Association of individual hnRNP proteins and snRNPs with nascent transcripts. 846 43

The mechanism by which intron-containing RNAs are recognized by the splicing machinery is only partly understood. A nuclear cap-binding complex (CBC), which specifically recognizes the monomethyl guanosine cap structure carried by RNA polymerase II transcripts, has previously been shown to play a role in pre-mRNA splicing. Using a combination of splicing complex and psoralen cross-linking analysis we demonstrate that CBC is required for efficient recognition of the 5' splice site by U1 snRNP during formation of E (early) complex on a pre-mRNA containing a single intron. However, in a pre-mRNA containing two introns, CBC is not required for splicing of the cap distal intron. In this case, the presence of an intact polypyrimidine tract in the cap-proximal intron renders splicing of the cap-distal intron independent of CBC. These results support models in which the splice sites in a pre-mRNA are originally recognized by interactions spanning exons. The defects in splicing and U1 snRNP binding caused by CBC depletion can be specifically reversed by recombinant CBC. In summary, efficient recognition of the cap-proximal 5' splice site by U1 snRNP is facilitated by CBC in what may be one of the earliest steps in pre-mRNA recognition. Data in Colot et al. (this issue) indicate that this function of CBC is conserved in humans and yeast.
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PMID:A nuclear cap-binding complex facilitates association of U1 snRNP with the cap-proximal 5' splice site. 868 98

The highly expressed mouse histone H2a-614 gene is located 800 nt 5' of the histone H3-614 gene. There is a 140 nt sequence located 500 nt from the end of the H2-614 mRNA which has been defined as a transcription termination site for RNA polymerase II. We established an in vitro transcription system in which both 3' end processing and transcription termination occur. A template containing the adenovirus major late promoter, a portion of the histone H2a-614 coding region, its 3' processing signal, followed by the transcription termination site was transcribed in a nuclear extract prepared from mouse myeloma cells. Some of the transcripts synthesized in the extract were cleaved at the histone processing site in a reaction which was dependent both on the hairpin binding factor and the U7 snRNP. The efficiency of histone 3' end formation was similar both on synthetic transcripts and transcripts synthesized by RNA polymerase II. Defined transcripts, which were not processed and which mapped to the transcription termination site, were released from the template, suggesting that they were formed by transcription termination. Termination in vitro was dependent on a functional histone processing signal.
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PMID:3' Processing and termination of mouse histone transcripts synthesized in vitro by RNA polymerase II. 887 61

The carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II (Pol II) contains multiple tandem copies of the consensus heptapeptide, TyrSerProThrSerProSer. Concomitant with transcription initiation the CTD is phosphorylated. Elongating polymerase has a hyperphosphorylated CTD, but the role of this modification is poorly understood. A recent study revealed that some hyperphosphorylated polymerase molecules (Pol IIo) are nonchromosomal, and hence transcriptionally unengaged (Bregman, D.B., L. Du, S. van der Zee, S.L. Warren. 1995. J. Cell Biol. 129: 287-298). Pol IIo was concentrated in discrete splicing factor domains, suggesting a possible relationship between CTD phosphorylation and splicing factors, but no evidence beyond immunolocalization data was provided to support this idea. Here, we show that Pol IIo co-immunoprecipitates with members of two classes of splicing factors, the Sm snRNPs and non-snRNP SerArg (SR) family proteins. Significantly, Pol IIo's association with splicing factors is maintained in the absence of pre-mRNA, and the polymerase need not be transcriptionally engaged. We also provide definitive evidence that hyperphosphorylation of Pol II's CTD is poorly correlated with its transcriptional activity. Using monoclonal antibodies (mAbs) H5 and H14, which are shown here to recognize phosphoepitopes on Pol II's CTD, we have quantitated the level of Pol IIo at different stages of the cell cycle. The level of Pol IIo is similar in interphase and mitotic cells, which are transcriptionally active and inactive, respectively. Finally, complexes containing Pol IIo and splicing factors can be prepared from mitotic as well as interphase cells. The experiments reported here establish that hyperphosphorylation of the CTD is a good indicator of polymerase's association with snRNP and SR splicing factors, but not of its transcriptional activity. Most importantly, the present study suggests that splicing factors may associate with the polymerase via the hyperphosphorylated CTD.
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PMID:Splicing factors associate with hyperphosphorylated RNA polymerase II in the absence of pre-mRNA. 900

The first protein that binds to all newly synthesized RNA polymerase III transcripts is a highly conserved phosphoprotein known as the La autoantigen. Although binding by the yeast La protein Lhp1p to pre-tRNAs is required for the normal pathway of tRNA maturation, the role of the La protein in the biogenesis of other polymerase III transcripts has been unclear. We identified a mutation in a novel component of the U6 snRNP that causes yeast cells to require Lhp1p for growth. This protein, Lsm8p, is a member of a family of proteins, known as Sm-like proteins, that shares two conserved motifs with the core Sm proteins of the U1, U2, U4 and U5 snRNPs. The lsm8-1 cells have drastically reduced levels of the mature U6 snRNP, consistent with a defect in U6 snRNP assembly. In these cells, Lhp1p stabilizes newly synthesized U6 RNA, thus facilitating assembly of the RNA into the U6 snRNP. These results provide evidence that Lhp1p is a molecular chaperone for polymerase III-transcribed RNAs and implicate Lsm8p as a key component in the very early steps of U6 snRNP assembly.
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PMID:A role for the yeast La protein in U6 snRNP assembly: evidence that the La protein is a molecular chaperone for RNA polymerase III transcripts. 985 99

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