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)

The 30S nuclear RNP particles from rat liver have been shown to split the double-stranded- (ds) and single-stranded (ss) sequences of nuclear pre-mRNA. Experiments performed in vitro have demonstrated that 1) a 5'-exonuclease and an endonuclease specific for double-stranded pre-mRNA sequences exist in the 30S pre-mRNP particles; 2) in dsRNA monophosphorylated 5'-termini arose in the course of incubation with 30S RNP and most of the products remained double-stranded. The analysis of terminal pNp nucleotides revealed a relatively high ratio of pPyp in the cleaved dsRNA, whereas the nucleosides in 5'-terminal pNp of ssRNA showed nearly random distribution. Our results provide a possible explanation for the appearance of pNp termini during the processing of nuclear pre-mRNA of mammalian cells.
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PMID:Cleavage of pre-mRNA sequences by ribonucleases bound to nuclear RNP particles of rat liver. 73 82

The hyperthermophilic archaeon Sulfolobus acidocaldarius uses a novel RNA-containing endonuclease to excise and mature 16S rRNA from the precursor (pre) rRNA transcript. A cell-free processing system has been developed using an in vitro transcribed RNA substrate containing the entire 144 nucleotide 5' external transcribed spacer (5'ETS) and the first 72 nucleotides of 16S rRNA. The cell-free extract cleaves in the 5'ETS at positions -99, -31, and +1 (i.e., the 5'ETS-16S junction). These positions are at or near the positions cleaved in vivo during processing of the pre rRNA transcript. The processing activity has been purified between 100 and 200-fold and appears to contain five or six polypeptide components and perhaps as many as 10 different small RNA components. Using combined reverse transcription-PCR amplification, full or partial cDNA copies of two of the RNA components have been obtained. One of the RNAs exhibits sequence and structural similarities to eukaryotic U3 snoRNA. The processing activity has been shown to be inactivated by micrococcal nuclease. It can be reactivated by reconstituting using bulk RNA from S.acidocaldarius but not bulk RNA from distantly related organisms. The activity is also abolished by RNase H digestion in the presence of oligonucleotides complementary to the U3-like RNA. These results demonstrate that the U3-like RNA is an essential component of the pre rRNA processing RNP endonuclease. Furthermore, this RNP endonuclease is not a derived eukaryotic feature, instead its existence predates the divergence of archaea and eukaryotes.
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PMID:Preribosomal RNA processing in archaea: characterization of the RNP endonuclease mediated processing of precursor 16S rRNA in the thermoacidophile Sulfolobus acidocaldarius. 872 97

The Lactococcus lactis group II intron Ll.ltrB is similar to mobile yeast mtDNA group II introns, which encode reverse transcriptase, RNA maturase, and DNA endonuclease activities for site-specific DNA insertion. Here, we show that the Lactococcal intron can be expressed and spliced efficiently in Escherichia coli. The intron-encoded protein LtrA has reverse transcriptase and RNA maturase activities, with the latter activity shown both in vivo and in vitro, a first for any group II intron-encoded protein. As for the yeast mtDNA introns, the DNA endonuclease activity of the Lactococcal intron is associated with RNP particles containing both the intron-encoded protein and the excised intron RNA. Also, the intron RNA cleaves the sense-strand of the recipient DNA by a reverse splicing reaction, whereas the intron-encoded protein cleaves the antisense strand. The Lactococcal intron endonuclease can be obtained in large quantities by coexpression of the LtrA protein with the intron RNA in E. coli or reconstituted in vitro by incubating the expressed LtrA protein with in vitro-synthesized intron RNA. Furthermore, the specificity of the endonuclease and reverse splicing reactions can be changed predictably by modifying the RNA component. Expression in E. coli facilitates the use of group II introns for the targeting of specific foreign sequences to a desired site in DNA.
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PMID:A bacterial group II intron encoding reverse transcriptase, maturase, and DNA endonuclease activities: biochemical demonstration of maturase activity and insertion of new genetic information within the intron. 935 59

For the first time small nuclear ribonucleoprotein particles (alpha-RNP) tightly bound to chromatin as well as cytoplasmic alpha-RNP are shown to possess strong and regulated endonuclease activity specific for mRNAs and hnRNAs. The enzymatic nature of this activity is confirmed, and the optimal conditions detected. This RNase activity is controlled by the action of a differentiating stimulus, dimethylsulfoxide, in human K562 cells. Small alpha-RNP involvement in the coordinated control of stability of pre-messenger RNA and messenger RNA molecules is suggested.
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PMID:The specific endoribonuclease activity of small nuclear and cytoplasmic alpha-RNPs. 1062 35

Group II intron homing occurs primarily by a mechanism in which the intron RNA reverse splices into a DNA target site and is then reverse transcribed by the intron-encoded protein. The DNA target site is recognized by an RNP complex containing the intron-encoded protein and the excised intron RNA. Here, we analyzed DNA target-site requirements for the Lactococcus lactis Ll.LtrB group II intron in vitro and in vivo. Our results suggest a model similar to yeast mtDNA introns, in which the intron-encoded protein first recognizes a small number of nucleotide residues in double-stranded DNA and causes DNA unwinding, enabling the intron RNA to base-pair with the DNA for reverse splicing. Antisense-strand cleavage requires additional interactions between the protein and 3' exon. Key nucleotide residues are recognized directly by the intron-encoded protein independent of sequence context, and there is a stringent requirement for fixed spacing between target site elements recognized by the protein and RNA components of the endonuclease. Experiments with DNA substrates containing GC-clamps or "bubbles" indicate a requirement for DNA unwinding in the 3' exon but not the distal 5' exon region. Finally, by applying the target-site recognition rules, we show that the L1.LtrB intron can be modified to insert at new sites in a plasmid-borne thyA gene in Escherichia coli. This strategy should be generally applicable to retargeting group II introns and to delivering foreign sequences to specific sites in heterologous genomes.
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PMID:Rules for DNA target-site recognition by a lactococcal group II intron enable retargeting of the intron to specific DNA sequences. 1071 44

Almost all small eukaryotic RNAs are processed from transiently stabilized 3'-extended forms. A key question is how and why such intermediates are stabilized and how they can then be processed to the mature RNA. Here we report that yeast U3 is also processed from a 3'-extended precursor. The major 3'-extended forms of U3 (U3-3'I and -II) lack the cap trimethylation present in mature U3 and are not associated with small nucleolar RNP (snoRNP) proteins that bind mature U3, i.e., Nop1p, Nop56p, and Nop58p. Depletion of Nop58p leads to the loss of mature U3 but increases the level of U3-3'I and -II, indicating a requirement for the snoRNP proteins for final maturation. Pre-U3 is cleaved by the endonuclease Rnt1p, but U3-3'I and -II do not extend to the Rnt1p cleavage sites. Rather, they terminate at poly(U) tracts, suggesting that they might be bound by Lhp1p (the yeast homologue of La). Immunoprecipitation of Lhp1p fused to Staphylococcus aureus protein A resulted in coprecipitation of both U3-3'I and -II. Deletion of LHP1, which is nonessential, led to the loss of U3-3'I and -II. We conclude that pre-U3 is cleaved by Rnt1p, followed by exonuclease digestion to U3-3'I and -II. These species are stabilized against continued degradation by binding of Lhp1p. Displacement of Lhp1p by binding of the snoRNP proteins allows final maturation, which involves the exosome complex of 3'-->5' exonucleases.
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PMID:Precursors to the U3 small nucleolar RNA lack small nucleolar RNP proteins but are stabilized by La binding. 1089 82

Group II intron mobility occurs by a target DNA-primed reverse transcription mechanism in which the intron RNA reverse splices directly into one strand of a double-stranded DNA target site, while the intron-encoded protein cleaves the opposite strand and uses it as a primer to reverse transcribe the inserted intron RNA. The group II intron endonuclease, which mediates this process, is an RNP particle that contains the intron-encoded protein and the excised intron RNA and uses both cooperatively to recognize DNA target sequences. Here, we analyzed the interaction of the Lactococcus lactis Ll.LtrB group II intron endonuclease with its DNA target site by DNA footprinting and modification-interference approaches. In agreement with previous mutagenesis experiments showing a relatively large target site, DNase I protection extends from position -25 to +19 from the intron-insertion site on the top strand and from -28 to +16 on the bottom strand. Our results suggest that the protein first recognizes a small number of specific bases in the distal 5'-exon region of the DNA target site via major-groove interactions. These base interactions together with additional phosphodiester-backbone interactions along one face of the helix promote DNA unwinding, enabling the intron RNA to base-pair to DNA top-strand positions -12 to +3 for reverse splicing. Notably, DNA unwinding extends to at least position +6, somewhat beyond the region that base-pairs with the intron RNA, but is not dependent on interaction of the conserved endonuclease domain with the 3' exon. Bottom-strand cleavage occurs after reverse splicing and requires recognition of a small number of additional bases in the 3' exon, the most critical being T+5 in the now single-stranded downstream region of the target site. Our results provide the first detailed view of the interaction of a group II intron endonuclease with its DNA target site.
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PMID:Interaction of a group II intron ribonucleoprotein endonuclease with its DNA target site investigated by DNA footprinting and modification interference. 1137 Nov 59

RNP particles containing 20S prosomes (alpha RNP) isolated from human epidermoid carcinoma cell line A-431 are shown to posses strong and regulated endonuclease activity specific for high-molecular-weight RNA, particularly, specific mRNAs. Furthermore, alpha-RNP destabilize the 3'-untranslated regions of c-myc mRNA, creating a specific cleavage pattern. Cleavage point within Alu sequence in high-molecular-weight RNA has been localized by primer-extension method. This RNase activity is induced under the action of EGF. alpha-RNP involvement in the coordinated control of processing and stability of specific messenger RNA molecules is suggested. The endoribonuclease activity of alpha-RNP can represent a link between EGF signalling pathway and RNA processing and degradation.
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PMID:[Re-expression of various i-antigens in Dileptus anser after temporary transformation of serotype]. 1153 82

Mobile group II introns encode multidomain proteins with maturase activity involved in splicing and reverse transcriptase (RT) and (often) endonuclease activities involved in intron mobility. These activities are present in a ribonucleoprotein complex that contains the excised intron RNA and the intron-encoded protein. Here, we report biochemical studies of the protein encoded by the group IIA1 intron in the cob gene of fission yeast Schizosaccharomyces pombe mitochondria (cobI1). RNP particle fractions from the wild-type fission yeast strain with cobI1 in its mtDNA have RT activity even without adding an exogenous primer. Characterization of the cDNA products of such reactions showed a strong preference for excised intron RNA as template. Two main regions for initiation of cDNA synthesis were mapped within the intron, one near the DIVa putative high-affinity binding site for the intron-encoded protein and the other near domain VI. Adding exogenous primers complementary to cob exon 2 sequences near the intron/exon boundary stimulated RT activity but mainly for pre-mRNA rather than mRNA templates. Further in vitro experiments demonstrated that cobI1 RNA in RNP particle fractions can reverse splice into double-stranded DNA substrates containing the intron homing site. Target DNA primed reverse transcription was not detected unless a DNA target was used that was already nicked in the antisense strand of exon 2. This study shows that S.pombe cobI1 encodes RNP particles that have most of the biochemical activities needed for it to be a retroelement. Interestingly, it appears to lack an endonuclease activity, suggesting that the active homing exhibited by this intron in crosses may differ somewhat from that of the better-characterized introns.
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PMID:Reverse transcriptase and reverse splicing activities encoded by the mobile group II intron cobI1 of fission yeast mitochondrial DNA. 1275 69

Nearly all eukaryotic mRNAs end with a poly(A) tail that is added to their 3' end by the ubiquitous cleavage/polyadenylation machinery. The only known exceptions to this rule are metazoan replication-dependent histone mRNAs, which end with a highly conserved stem-loop structure. This distinct 3' end is generated by specialized 3' end processing machinery that cleaves histone pre-mRNAs 4-5 nucleotides downstream of the stem-loop and consists of the U7 small nuclear RNP (snRNP) and number of protein factors. Recently, the U7 snRNP has been shown to contain a unique Sm core that differs from that of the spliceosomal snRNPs, and an essential heat labile processing factor has been identified as symplekin. In addition, cross-linking studies have pinpointed CPSF-73 as the endonuclease, which catalyzes the cleavage reaction. Thus, many of the critical components of the 3' end processing machinery are now identified. Strikingly, this machinery is not as unique as initially thought but contains at least two factors involved in cleavage/polyadenylation, suggesting that the two mechanisms have a common evolutionary origin. The greatest challenge that lies ahead is to determine how all these factors interact with each other to form a catalytically competent processing complex capable of cleaving histone pre-mRNAs.
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PMID:Formation of the 3' end of histone mRNA: getting closer to the end. 1753 5

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