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)

In a temperature-sensitive mutant of E. coli defective in tRNA biosynthesis, many tRNA precursors, including monomeric and multimeric forms, accumulate. Some of the multimeric precursors contain three or more tRNA sequences within a molecule. These large precursors were cleaved by cell extracts first into intermediate size pieces which were subsequently processed by RNase P. On the basis of heat stability of mutant cell extracts, the endonuclease responsible for the initial cleavage appears to be distinct from RNase P and is designated RNase O. One of the monomeric precursors was shown to be processed first by RNase P and the product subsequently cleaved further into a smaller molecule. The nuclease responsible for this second cleavage also appears to be distinct from RNase P and is designated RNase Q. The functions of these nucleases are sequential in the trimming process with respect to that of RNase P; RNase O works prior to RNase P and RNase Q after RNase P but in both cases, not vice versa.
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PMID:Sequential processing of precursor tRNA molecules in Escherichia coli. 110 44

Our results indicate that RNase P has a very general role in the processing of tRNA precursors in E. coli, being responsible for the cleavage of virtually all precursor molecules at a site corresponding to the 5' end of the mature tRNA, and that at least two other RNases play specific roles in precursor processing. One of these, which may be RNase II, is responsible for removing extra nucleotides from the 3' end of tRNA precursors. The other, which we call RNase P2, is an endonuclease that cleaves precursors in spacer regions between different tRNA sequences; this enzyme is involved in the processing of large multimeric precursors.
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PMID:Processing of E. coli tRNA precursors. 110

Replicating chromosomes, called intermediate DNA, have been extracted from the adenovirus replication complex. Compared to mature molecules, intermediate DNA had a greater buoyant density in CsCl gradients and ethidium bromide-cesium chloride gradients. Digestion of intermediate DNA with S1 endonuclease, but not with RNase, abolished the difference in densities. These properties suggest that replicating molecules contain extensive regions of parental single strands. Although intermediate DNA sedimented faster than marker viral DNA in neutral sucrose gradients, single strands longer than unit length could not be detected after alkaline denaturation. Integral size classes of nascent chains in intermediate DNA suggest a relationship between units of replication and the nucleoprotein structure of the virus chromosome. Adenovirus DNA was replicated at a rate of 0.7 x 10-6 daltons/min. Although newly synthesized molecules had the same sedimentation coefficient and buoyant density as mature chromosomes, they still contained single-strand interruptions. Complete joining of daughter strands required an additional 15 to 20 min.
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PMID:Intermediate in adenovirus type 2 replication. 113 77

A comparative study of ribonuclease activity of isolated rat liver nuclei, nuclear membranes with buoyant density rho 1,19 and rho 1,22 and pH 8 nuclear membrane extract showed high nuclear membranes activity with different affinity to RNA and synthetic polyribonucleotides. Chromatographic analysis of poly-U degradation products demonstrates that the nuclear membrane extract contains at least two ribonucleases: a 3'-endonuclease and a 5'-endonuclease.
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PMID:[Ribonucleases of rat liver nuclear membranes]. 120 59

A mitochondrial endonuclease from Drosophila melanogaster embryos was purified to near homogeneity by successive fractionation with DEAE-cellulose and heparin--avidgel-F, followed by FPLC chromatography on mono S, Superose 12 and a second mono S column. This enzyme digests double-stranded DNA more efficiently than heat-denatured DNA. The endonuclease activity has a molecular mass of 44 kDa, as determined under native conditions using a gel-filtration Superose 12 column. The prominent peptide detected by SDS/polyacrylamide gel electrophoresis likewise has a molecular mass of 44 kDa, suggesting a monomeric protein. The enzyme has an absolute requirement for divalent cations, preferring Mg2+ over Mn2+. No activity could be detected when these cations were replaced by Ca2+ or Zn2+. The pH optimum for this enzyme activity is 6.5-7.4 and its isoelectric point is 4.9. Both single-strand and double-strand breaks are introduced simultaneously into a supercoiled substrate in the presence of MgCl2 or MnCl2. Endonuclease-treated DNA serves as a substrate for DNA polymerase I from Escherichia coli, suggesting that 3'-OH termini are generated during cleavage. The enzyme is free from any detectable DNA exonuclease activity but not from RNase activity. Partial inhibition by antibodies raised against mitochondrial endonucleases derived from bovine heart and Saccharomyces cerevisiae have revealed a potential structural homology between these nucleases.
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PMID:Purification and characterization of a mitochondrial endonuclease from Drosophila melanogaster embryos. 133 52

A synthetic RNA transcript containing the entire sequence of one of the two natural mRNAs for Escherichia coli ribosomal protein S20 is a substrate for specific cleavage by an endonuclease which is or depends on ribonuclease E (Mackie, G. A. (1991) J. Bacteriol. 173, 2488-2497). Partial cleavage with ribonucleases T1 or CL3 and limited modification with dimethyl sulfate have been employed to identify residues that are likely to be single stranded in the S20 mRNA's native state. The data show that the 5' one-third of the mRNA is relatively unstructured whereas the 3' one-third is extensively folded. The latter property can account for the previously observed accumulation of a 147-residue product co-terminal with the 3' end of the S20 mRNA (Mackie, G. A. (1989) J. Bacteriol. 171, 4112-4120). Sites of cleavage by the ribonuclease E-dependent activity map to single-stranded regions of the RNA. In addition, denaturation of the RNA substrate results in loss of susceptibility to the ribonuclease E-dependent activity and simultaneous loss of the single-stranded character of the two most prominent cleavage sites. It is proposed that ribonuclease E is a single-strand-specific enzyme with few primary structural constraints but a preference for an AU dinucleotide 3' to the site of cleavage.
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PMID:Secondary structure of the mRNA for ribosomal protein S20. Implications for cleavage by ribonuclease E. 137 Apr 57

U14 small nuclear RNA (snRNA) is an evolutionarily conserved RNA species that plays a role in rRNA processing. The conserved ability of fungal, amphibian and mammalian U14 snRNAs to hybridize with both homologous and heterologous eukaryotic 18S rRNAs indicates a potential role for this intermolecular RNA/RNA interaction in U14 snRNA function. To understand better the possible role of this intermolecular base-pairing in rRNA processing, we have defined those nucleotide sequences in mouse U14 snRNA and 18S rRNA responsible for the observed in vitro hybridization. We have constructed, using synthetic DNA oligonucleotides, a U14 snRNA gene which has been positioned behind a T7 RNA polymerase promoter site and then inserted into a plasmid. The presence of natural or engineered restriction endonuclease sites within this construct has permitted the in vitro transcription of full-length mouse U14 snRNA transcripts (an 87-nucleotide mouse U14 snRNA minus 5' or 3' leader sequences) or 3' terminally truncated U14 snRNA fragments. Hybridization of full-length or truncated fragments of U14 snRNA to mouse 18S rRNA demonstrated the utilization of a previously proposed 18S rRNA complementary sequence located near the 3' end of mouse U14 snRNA (nucleotides 65-78) for intermolecular hybridization. Conversely, RNase-T1-generated fragments of 18S rRNA capable of hybrid-selection by U14 snRNA have been isolated and sequenced. A nested set of hybrid-selected 18S rRNA fragments define a mouse 18S rRNA sequence (nucleotides 459-472) which exhibits perfect complementarity to the defined U14 snRNA sequence 65-78. Primer-extension/chain-termination mapping of mouse U14-snRNA.18S-rRNA hybrids has confirmed the formation of the proposed hybrid structure. A second set of observed complementary sequences in mouse U14 snRNA (nucleotides 25-38) and mouse 18S rRNA (nucleotides 82-95) are not used for the in vitro hybridization of these two RNAs. Presumably the involvement of this second 18S-rRNA-complementary sequence in the secondary/tertiary folding of mouse U14 snRNA prevents its base-pairing with 18S rRNA. However, the strong evolutionary conservation of both U14-snRNA.18S-rRNA hybrid structures and their juxtapositioning within the folded secondary structure of 18S rRNAs argues for a biological role for each in U14 snRNA function.
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PMID:Determination of the nucleotide sequences in mouse U14 small nuclear RNA and 18S ribosomal RNA responsible for in vitro intermolecular base-pairing. 137 13

Processing of 9 S precursor RNA in Escherichia coli requires the endoribonuclease RNase E, which makes two cleavages to liberate p5, the immature form of 5 S rRNA. The contributions of primary and secondary structure to RNase E-mediated cleavage of 9 S RNA were investigated. The structure of the 5' domain of 9 S RNA was probed by partial ribonuclease digestion and chemical modification. Our structural analysis of 9 S RNA supports a model in which the 5' spacer domain folds into tandem hairpins so that the first processing cleavage site 5' to the 5 S moiety resides in a stretch of single-stranded residues. Site-directed mutagenesis of a cloned 9 S RNA sequence was performed and synthetic transcripts derived from a variety of such mutant templates were assayed as substrates for RNase E-dependent endonuclease activity in fractionated extracts. Partial or complete deletion of the 5 S sequence did not eliminate site-specific processing of 9 S RNA. Mutations affecting the 5' domain revealed that secondary structure upstream from the first cleavage site is important in maintaining efficient processing. However, secondary structure downstream from either cleavage site is dispensable. Our results suggest that RNase E specifically recognizes and cleaves single-stranded RNA sequences only when presented in a proper conformational context. Adjacent secondary structures appear to play a direct and critical role in the enzyme's recognition of its substrate. Additionally, it may serve to anchor single-stranded regions to ensure the availability of the RNase E cleavage sites.
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PMID:Structural requirements for the processing of Escherichia coli 5 S ribosomal RNA by RNase E in vitro. 147 79

The oligonucleotide ppp5'A2'p5'A2'p5'A, known as 2-5A, is a potent translational inhibitor involved in some aspects of interferon action. To explore the specific function of the charged 5'-triphosphate moiety, we prepared a series of congeners in which the 5' region was hypermodified. Thus, uronic acid derivatives were substituted for the 5' terminal adenosine residue of 2-5A. Compounds 9, 10, 11 and 12 carried adenosine 5'-uronic acid, ethyl adenosine 5'-uronate, adenosine 5'-uronamide, and adenosine 5'-(N-ethyl)uronamide, respectively, in place of the 5' terminal adenosine triphosphate moiety of 2-5A. While all the analogues showed some weak interaction with the 2-5A-dependent endonuclease (RNase L), compound 9 showed the strongest binding ability, and while unable to activate the mouse RNase L, could activate human RNase at a concentration 100-fold greater than that required for the parent 2-5A. This result suggests that the function of the 5'(poly)phosphate moiety of 2-5A may be fulfilled by some other anionic moiety.
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PMID:Synthesis and biological activity of uronic acid analogues of 2-5A[5'-O-triphosphoryladenylyl(2----5')adenylyl-(2'----5')adenosine]. 152 4

Yeast mitochondrial DNA contains multiple promoters that sponsor different levels of transcription. Several promoters are individually located immediately adjacent to presumed origins of replication and have been suggested to play a role in priming of DNA replication. Although yeast mitochondrial DNA replication origins have not been extensively characterized at the primary sequence level, a common feature of these putative origins is the occurrence of a short guanosine-rich region in the priming strand downstream of the transcriptional start site. This situation is reminiscent of vertebrate mitochondrial DNA origins and raises the possibility of common features of origin function. In the case of human and mouse cells, there exists an RNA processing activity with the capacity to cleave at a guanosine-rich mitochondrial RNA sequence at an origin; we therefore sought the existence of a yeast endoribonuclease that had such a specificity. Whole cell and mitochondrial extracts of Saccharomyces cerevisiae contain an RNase that cleaves yeast mitochondrial RNA in a site-specific manner similar to that of the human and mouse RNA processing activity RNase MRP. The exact location of cleavage within yeast mitochondrial RNA corresponds to a mapped site of transition from RNA to DNA synthesis. The yeast activity also cleaved mammalian mitochondrial RNA in a fashion similar to that of the mammalian RNase MRPs. The yeast endonuclease is a ribonucleoprotein, as judged by its sensitivity to nucleases and proteinase, and it was present in yeast strains lacking mitochondrial DNA, which demonstrated that all components required for in vitro cleavage are encoded by nuclear genes. We conclude that this RNase is the yeast RNase MRP.
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PMID:Saccharomyces cerevisiae contains an RNase MRP that cleaves at a conserved mitochondrial RNA sequence implicated in replication priming. 158 58

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