EC:3.1.30.2 - FACTA Search

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Query: EC:3.1.30.2 (endonuclease)
18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A processing endonuclease acts to remove a short sequence from the 3' end of transcripts of the Saccharomyces cerevisiae 5S ribosomal RNA gene in generating the mature sequence of 5S RNA. Cells bearing the nuclear mutation rna82 .1 lack this activity and accumulate 5S forms with additional nucleotides at their 3' termini. 5S RNAs labelled during short pulse- labellings of the mutant are essentially primary transcripts that mostly have the sequence U-U-A-U-U-U-C[U-U-U-U(U-U)] added to the 3' end of normal yeast 5S RNA. They are subjected in vivo to a series of slow processing events whereby this sequence is ultimately replaced by: U-U(A)1-9 in a substantial proportion of the 5S RNA molecules of the mutant [Piper, P. W., Bellatin , J. A. and Lockheart , A. (1983) EMBO J. 2, 353-359]. In higher eukaryotes no endonuclease cleavage occurs during 5S RNA maturation, yet processing at the 3' ends of certain transcripts made by RNA polymerase III, most notably transfer RNA precursors, is still important. Since the enzymes involved in this processing have not been well characterised, we investigated how the additional sequences upon rna82 .1 yeast 5S RNA are processed in vitro in a system from a higher eukaryote that is often used for studying transcription by RNA polymerase III, the Xenopus laevis germinal vesicle extract. Our results are consistent with slow digestion of these 5S molecules by a 3'----5' exonuclease until they become 122-123 nucleotides in length, whereupon digestion ceases. This activity probably participates in the processing of certain Xenopus RNA polymerase III transcripts.
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PMID:Processing of the 3' sequence extensions upon the 5S rRNA of a mutant yeast in Xenopus laevis germinal vesicle extract. 632 1

The specificity of transcription of Euglena gracilis Z chloroplast DNA by chloroplast DNA-dependent RNA polymerase in a transcriptionally active chromosome (Hallick, R.B., Lipper, C., Richards, O.C., and Rutter, W.J. (1976) Biochemistry 15, 3039-3045) has been studied. RNA molecules are both initiated and elongated in vitro. The RNA transcripts have been characterized as to their size, nuclease sensitivity, 5'-terminal oligonucleotides, and coding locus on the chloroplast genome. RNA labeled in vitro at the 5' end with [gamma-32P]ATP was digested with RNase T1, RNase A, and S1 nuclease. The resulting 5'-gamma-32P-oligonucleotides were fractionated by gel electrophoresis. In each case, one or two discrete products were obtained, consistent with initiation in vitro only at defined loci. RNA labeled in vitro with [alpha-32P]ATP or CTP has been hybridized to Southern (Southern, E.M. (1975) J. Mol. Biol. 98, 503-517) transfers of restriction endonuclease fragments of chloroplast DNA. The most abundant in vitro transcripts hybridize to chloroplast DNA fragments coding for 23 S, 16 S, and 5 S rRNAs. Only the coding strands of the rRNA genes are transcribed. Non-rDNA sequences of chloroplast DNA are also selectively transcribed but at much lower levels. The transcriptionally active chromosome has proved to be an ideal biochemical preparation for the study of selective transcription of cell organelle DNA.
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PMID:Selective in vitro transcription of Euglena chloroplast ribosomal RNA genes by a transcriptionally active chromosome. 676 27

The DNA-dependent RNA polymerase activity and endonucleases in uraemic lymphocyte cells were investigated. It was found that the activity and quantity in three classes of polymerases are remarkably reduced. The reduction in enzyme activity is accompanied by increasing endonuclease activity. The relationship of polymerase enzymes with endonucleases is discussed.
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PMID:DNA-dependent RNA polymerase enzymes affected in uraemic lymphocyte cells. 839 Apr 14

DiSSU1 is an optional group I twintron present in the nuclear extrachromosomal ribosomal DNA of the myxomycete Didymium iridis. DiSSU1 appears to be complex both in structure and function. At the RNA level it has a twin-ribozyme organization composed of two group I ribozymes with different functions, separated by an open reading frame. Here, we show that DiSSU1 is mobile when haploid intron-containing and intron-less amoebae are mated. The mobility process is fast, being completed in 5-10 nuclear cycles after mating in the developing zygote and plasmodia. Analyses of progeny from genetic crosses confirm intron mobility. DiSSU1 is the first example of a mobile group I twintron. The intron-encoded protein was expressed in Escherichia coli and found to be an endonuclease, I-DirI, that cleaves an intron-less ribosomal DNA allele at the intron-insertion site, and is probably involved in intron homing. The endonuclease I-DirI seems to be a rare example of a protein that is expressed from a ribozyme-processed RNA polymerase I transcript in vivo.
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PMID:In vivo mobility of a group I twintron in nuclear ribosomal DNA of the myxomycete Didymium iridis. 919 1

Chilo iridescent virus (CIV), the type species of the genus Iridovirus within the family Iridoviridae, is highly pathogenic for larvae of important pest insects. The virions contain a single linear double-stranded DNA molecule (209 kbp) that is circularly permuted and terminally redundant. The nucleotide sequence of the viral genome between the genome coordinates 0.101 and 0.391 (60,170 bp) was determined by automated cycle sequencing. This particular region of the CIV genome contains 112 open reading frames (ORFs) with coding capacities for 50 to 1186 amino acids. The alignment of the deduced amino acid sequences with well-characterized proteins stored in protein databases led to the identification of several genes with significant homologies, such as the largest subunit of the DNA-dependent RNA polymerase, large subunit of the ribonucleoside-diphosphate reductase, endonuclease, protein-tyrosine phosphatase, helicase, global transactivator, two apoptosis inhibitor homologs, antibiotic peptide homolog, and others. The highest homologies were detected between putative viral gene products of CIV and the corresponding viral proteins of lymphocystis disease virus of fish (LCDV), which belongs to the genus Lymphocystivirus within the iridovirus family.
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PMID:The DNA sequence of Chilo iridescent virus between the genome coordinates 0.101 and 0.391; similarities in coding strategy between insect and vertebrate iridoviruses. 948 89

PpLSU3, a mobile group I intron in the rRNA genes of Physarum polycephalum, also can home into yeast chromosomal ribosomal DNA (rDNA) (D. E. Muscarella and V. M. Vogt, Mol. Cell. Biol. 13:1023-1033, 1993). By integrating PpLSU3 into the rDNA copies of a yeast strain temperature sensitive for RNA polymerase I, we have shown that the I-PpoI homing endonuclease encoded by PpLSU3 is expressed from an RNA polymerase I transcript. We have also developed a method to integrate mutant forms of PpLSU3 as well as the Tetrahymena intron TtLSU1 into rDNA, by expressing I-PpoI in trans. Analysis of I-PpoI expression levels in these mutants, along with subcellular fractionation of intron RNA, strongly suggests that the full-length excised intron RNA, but not RNAs that are further cleaved, serves as or gives rise to the mRNA.
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PMID:I-PpoI, the endonuclease encoded by the group I intron PpLSU3, is expressed from an RNA polymerase I transcript. 974 98

The Didymium iridis DiSSU1 intron is located in the nuclear SSU rDNA and has an unusual twin-ribozyme organization. One of the ribozymes (DiGIR2) catalyses intron excision and exon ligation. The other ribozyme (DiGIR1), which along with the endonuclease-encoding I-DirI open reading frame (ORF) is inserted in DiGIR2, carries out hydrolysis at internal processing sites (IPS1 and IPS2) located at its 3' end. Examination of the in vivo expression of DiSSU1 shows that after excision, DiSSU1 is matured further into the I-DirI mRNA by internal DiGIR1-catalysed cleavage upstream of the ORF 5' end, as well as truncation and polyadenylation downstream of the ORF 3' end. A spliceosomal intron, the first to be reported within a group I intron and the rDNA, is removed before the I-DirI mRNA associates with the polysomes. Taken together, our results imply that DiSSU1 uses a unique combination of intron-supplied ribozyme activity and adaptation to the general RNA polymerase II pathway of mRNA expression to allow a protein to be produced from the RNA polymerase I-transcribed rDNA.
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PMID:In vivo expression of the nucleolar group I intron-encoded I-dirI homing endonuclease involves the removal of a spliceosomal intron. 1002 42

PpLSU3, a mobile group I intron found in the ribo-somal RNA genes of Physarum polycephalum, encodes the I-PpoI homing endonuclease. This enzyme represents one of the rare cases in nature where a protein is expressed from an RNA polymerase I transcript. Our previous results showed that the full length intron, but not a further processed species, is the messenger for I-PpoI, implying a role of the untranslated region (UTR) in gene expression. To study the function of the 3'-UTR in expression of the endonuclease and in splicing of the intron, we replaced the I-PpoI gene in PpLSU3 with the gene for the alpha-fragment of Escherichia coli beta-galactosidase, and then integrated this chimeric intron into all the chromosomal rDNA repeats of yeast. The resulting cells synthesized functional alpha-fragment, as evidenced by a complementation assay analogous to that used in E.coli. The beta-galactosidase activity thus provides an unusual and potentially valuable readout for Pol I transcription from chromosomal rDNA. This is the first example in which a eucaryotic homing endonuclease gene has been successfully replaced by a heterologous gene. Using deletion mutagenesis and a novel randomization approach with the alpha-fragment as a reporter, we found that a small segment of the 3'-UTR dramatically influences both splicing and protein expression.
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PMID:Functional alpha-fragment of beta-galactosidase can be expressed from the mobile group I intron PpLSU3 embedded in yeast pre-ribosomal RNA derived from the chromosomal rDNA locus. 1068 39

DNA repair by photolyase (photoreactivation) and nucleotide excision repair (NER) are the major pathways to remove UV-induced cyclobutane-pyrimidine dimers (CPDs). The nucleolus is a nuclear subcompartment containing the ribosomal RNA genes (rDNA) of which a fraction is transcribed by RNA polymerase I (RNAP-I), and the rest is silenced. Here yeast was used to investigate how photoreactivation and NER contribute to repair of active and inactive rDNA. Cells were irradiated with UV light and exposed to different repair conditions. Nuclei were isolated, and the active genes were separated from the inactive genes by restriction endonuclease digestion. CPDs were measured in total rDNA, in both fractions, and in the GAL10 gene. Repair in rDNA was as efficient as in GAL10 indicating that both pathways have unrestricted access to the nucleolus. Photoreactivation was much faster than NER and therefore was the predominant repair pathway. Active genes were faster repaired by photolyase than were silenced genes providing evidence for an open chromatin structure during repair. The transcribed strands of active genes, but not of inactive genes, were slightly faster repaired by NER providing evidence for transcription-coupled repair by RNAP-I. There was no pronounced inhibition of photoreactivation by RNAP-I in the transcribed strand, which is in contrast to genes transcribed by RNAP-II and suggests different stabilities of RNAP-I and RNAP-II stalled at CPDs.
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PMID:Repair of active and silenced rDNA in yeast: the contributions of photolyase and transcription-couples nucleotide excision repair. 1180 5

Alu elements are the most successful transposons in humans. They are 300-bp non-coding sequences transcribed by RNA polymerase III (Pol III) and are expected to retrotranspose with the aid of reverse transcriptases of cellular origin. We previously showed that human LINEs can generate cDNA copies of any mRNA transcript by means of a retroposition process involving reverse transcription and integration by the LINE-encoded endonuclease and reverse transcriptase. Here we show mobility of marked Alu sequences in human HeLa cells with the canonical features of a retrotransposition process, including splicing out of an autocatalytic intron introduced into the marked sequence, target site duplications of varying lengths and integrations into consensus A-rich sequences. We further show that the poly-A stretch at the Alu 3' end is essential for mobility, that LINEs are required for transposition and that the rate of retroposition is 100-1,000 times higher for Alu transcripts than for control mRNAs, thus accounting for the high mutational activity of these elements observed in humans.
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PMID:LINE-mediated retrotransposition of marked Alu sequences. 1294 4

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