EC:3.1.26.4 - FACTA Search

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Query: EC:3.1.26.4 (RNase H)
2,751 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An RNase A protection assay was employed to investigate the interaction of nuclear components with a precursor-mRNA derived from the adenovirus 2 major late transcription unit in a splicing extract from HeLa cells. Upon incubation in the extract, two regions in the precursor-RNA become resistant to digestion with RNase A. After short incubation times (5 min) at 30 degrees C, fragments mapping upstream from the branch point in the intron are obtained. After ten minutes or more, additional oligonucleotides, derived from the 5' splice site, are protected. RNase A protection of different RNA substrates demonstrates that a 5' splice site is not required for the binding of components to the branch point region. For interaction with this site, the polypyrimidine stretch just upstream from the 3' splice site is essential. Binding to the 5' splice site occurs only in the presence of an intact 3' end of the intron. Preincubation of the extract with excess unlabelled RNA containing only a 3' splice site leads to efficient competition of binding, both in the branch point region and at the 5' splice site, whereas an RNA that contains only 5'-splice-site sequences has no effect on the interaction with the mRNA precursor. This indicates that stable association with the 5' splice site requires prior binding of components in the branch point region. When splicing complexes are digested with RNase A, it becomes apparent that only the branch point region is sequestered into a ribonucleoprotein (RNP) structure in the 35 S complex. The 5' splice site becomes resistant to RNase A only when a 50 S splicing complex has been assembled. Degradation of specific regions in U1, U2 and U4 RNA with complementary oligodeoxynucleotides and RNase H has been used to analyse involvement of the U small nuclear RNPs (snRNPs) in the protection reaction. The 5' end of U2 RNA is essential for protection of the branch point region. RNA sequences in a loop of U2 RNA (nucleotides 65 to 78) are required for the formation of an RNase-A-resistant structure at the 5' splice site. Taken together, these results suggest that U2 snRNP participates in the formation of a pre-splicing complex, the 5' end of its RNA being involved in the observed binding. Conversion to a 50 S splicing complex is obtained after the binding of U1 and U4/U6 snRNPs, which also requires sequences in a loop of U2 RNA. Possible interactions between the individual snRNPs and between snRNPs and precursor-mRNA are discussed.
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PMID:Analysis of RNase-A-resistant regions of adenovirus 2 major late precursor-mRNA in splicing extracts reveals an ordered interaction of nuclear components with the substrate RNA. 368 67

The poly(A) sequence of 30 to 40S Rous sarcoma virus RNA, prepared by digestion of the RNA with RNase T(1), showed a rather homogenous electrophoretic distribution in formamide-polyacrylamide gels. Its size was estimated to be about 200 AMP residues. The poly(A) appears to be located at or near the 3' end of the 30 to 40S RNA because: (i) it contained one adenosine per 180 AMP residues, and because (ii) incubation of 30 to 40S RNA with bacterial RNase H in the presence of poly(dT) removed its poly(A) without significantly affecting its hydrodynamic or electrophoretic properties in denaturing solvents. The viral 60 to 70S RNA complex was found to consist of 30 to 40S subunits both with (65%) and without (approximately 30%) poly(A). The heteropolymeric sequences of these two species of 30 to 40S subunits have the same RNase T(1)-resistant oligonucleotide composition. Some, perhaps all, RNase T(1)-resistant oligonucleotides of 30 to 40S Rous sarcoma virus RNA appear to have a unique location relative to the poly(A) sequence, because the complexity of poly(A)-tagged fragments of 30 to 40S RNA decreased with decreasing size of the fragment. Two RNase T(1)-resistant oligonucleotides which distinguish sarcoma virus Prague B RNA from that of a transformation-defective deletion mutant of the same virus appear to be associated with an 11S poly(A)-tagged fragment of Prague B RNA. Thus RNA sequences concerned with cell transformation seem to be located within 5 to 10% of the 3' terminus of Prague B RNA.
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PMID:Properties and location of poly(A) in Rous sarcoma virus RNA. 437 9

The 3' terminus of TYMV RNA, which possesses tRNA-like properties, has been studied. A 3' terminal fragment of 112 nucleotides was obtained by cleavage with RNase H after hybridization of a synthetic oligodeoxynucleotide to the viral RNA. The accessibility of cytidine and adenosine residues was probed with chemical modification. Enzymatic digestion studies were performed with RNase T1, nuclease S1 and the double-strand specific RNase from the venom of the cobra Naja naja oxiana. A model is proposed for the secondary structure of the 3' terminal region of TYMV RNA comprising 86 nucleotides. The main feature of this secondary structure is the absence of a conventional acceptor stem as present in canonical tRNA. However, the terminal 42 nucleotides can be folded in a tertiary structure which bears strong resemblance with the acceptor arm of canonical tRNA. Comparison of this region of TYMV RNA with that of other RNAs from both the tymovirus group and the tobamovirus group gives support to our proposal for such a three-dimensional arrangement. The consequences for the recognition by TYMV RNA of tRNA-specific enzymes is discussed.
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PMID:The tRNA-like structure at the 3' terminus of turnip yellow mosaic virus RNA. Differences and similarities with canonical tRNA. 707 75

Eukaryotic ribonucleases H of known sequence are composed of an RNase H domain similar in size and sequence to that of Escherichia coli RNase HI and additional domains of unknown function. The RNase H1 of Saccharomyces cerevisiae has such an RNase H domain at its C-terminus. Here we show that the N-terminal non-RNase H portion of the yeast RNase H1 binds tightly to double-stranded RNA (dsRNA) and RNA-DNA hybrids even in the absence of the RNase H domain. Two copies of a sequence with limited similarity to the dsRNA-binding motif are present in this N-terminus. When the first of these sequences is altered, the protein no longer binds tightly to dsRNA and exhibits an increase in RNase H activity. Unlike other dsRNA-binding proteins, increasing the Mg2+ concentration from 0.5 mM to 5 mM inhibits binding of RNase H1 to dsRNA; yet a protein missing the RNase H domain binds strongly to dsRNA even at the higher Mg2+ concentration. These results suggest that binding to dsRNA and RNase H activity are mutually exclusive, and the Mg2+ concentration is critical for switching between the activities. Changes in the Mg2+ concentration or proteolytic severing of the dsRNA-binding domain could alter the activity or location of the RNase H and may govern access of the enzyme to the substrate. Sequences similar to the dsRNA-binding motif are present in other eukaryotic RNases H and the transactivating protein of cauliflower mosaic virus, suggesting that these proteins may also bind to dsRNA.
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PMID:The non-RNase H domain of Saccharomyces cerevisiae RNase H1 binds double-stranded RNA: magnesium modulates the switch between double-stranded RNA binding and RNase H activity. 748 97

Activity gel analysis of cell extracts from slow- and fast-growing mycobacteria confirmed the presence of several RNase H activities in both classes of organism. The rnhA gene from Mycobacterium smegmatis (Ms) was subsequently cloned using an internal gene segment probe [Mizrahi et al., Gene 136 (1993) 287-290]. The gene encodes a polypeptide of 159 amino acids that shares 50% identity with the RNase HI from Escherichia coli (Ec). However, unlike its counterparts from Gram- bacteria, Ms rnhA does not form an overlapping divergent transcriptional unit with dnaQ (encoding the epsilon (proofreading) subunit of DNA polymerase III). Ms RNase HI was overproduced in Ec as an enzymatically active maltose-binding protein (MBP) fusion protein which cleaved the RNA strand of an RNA.DNA hybrid with a similar site selectivity to that of its Ec homologue.
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PMID:Cloning, sequence analysis, overproduction in Escherichia coli and enzymatic characterization of the RNase HI from Mycobacterium smegmatis. 748 19

In the presence of Mn2+, reverse transcriptase of both human immunodeficiency virus and murine leukemia virus hydrolyzes duplex RNA. However, designating this novel activity RNase D conflicts with Escherichia coli RNase D, which participates in tRNA processing. On the basis of its location in the RNase H domain, we propose that this novel retroviral activity be redesignated RNase H*.
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PMID:Redesignation of the RNase D activity associated with retroviral reverse transcriptase as RNase H. 750 4

Using purified proteins from calf and a synthetic substrate, we have reconstituted the enzymatic reactions required for mammalian Okazaki fragment processing in vitro. The required reactions are removal of initiator RNA, synthesis from an upstream fragment to generate a nick, and then ligation. With our substrate, RNase H type I (RNase HI) makes a single cut in the initiator RNA, one nucleotide 5' of the RNA-DNA junction. The double strand specific 5' to 3' exonuclease removes the remaining monoribonucleotide. After dissociation of cleaved RNA, synthesis by DNA polymerase generates a nick, which is then sealed by DNA ligase I. The unique specificities of the two nucleases for primers with initiator RNA strongly suggest that they perform the same reactions in vivo.
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PMID:Enzymatic completion of mammalian lagging-strand DNA replication. 752 89

Ribonuclease H (RNase H) recognizes a DNA-RNA hybrid duplex and catalyzes the hydrolysis of the phosphodiester linkages in only the RNA strand. Previously, we developed a method to cleave RNA in a sequence-dependent manner using RNase H and a complementary oligonucleotide containing 2'-O-methylribonucleosides. Since cleavage is restricted to a single site by the modified complementary strand, this system allows kinetic analysis of the RNase H reaction. We describe an investigation of the interactions between RNase HI from Escherichia coli and its substrate, and between the substrate and a metal ion using synthetic oligonucleotide duplexes modified at the cleavage site in combination with the 2'-O-methylribonucleotides. Firstly, the base moiety was changed to interfere with enzyme binding in either the major or minor groove. When 2-N-methylguanine was incorporated into the cleavage site, the Km value for this substrate, containing a methyl group in the minor groove, was 20-fold larger than that for the unmodified substrate, whereas 5-phenyluracil, with a phenyl group residing in the major groove of the duplex, did not affect the affinity. Secondly, the phosphodiester linkage at the cleavage site was changed into a phosphorothioate with a defined configuration. Only the Rp isomer was cleaved at this site in the presence of Mg2+ or Cd2+. These results suggest that the enzyme, but not the metal ion, interacts with the phosphate residue at the cleavage site. Thirdly, the 2'-position of the nucleoside on the 5'-side of the scissile phosphodiester was modified. Alteration of the 2'-hydroxyl function into an amino, fluoro or methoxy group, or removal of this 2'-hydroxyl group, did not affect the affinity for the enzyme, but reduced the reaction rate. An outer sphere interaction of a metal ion with the 2'-hydroxyl group is suggested.
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PMID:Studies of the interactions between Escherichia coli ribonuclease HI and its substrate. 752 71

Bacterial reverse transcriptase is responsible for the synthesis of multicopy single-stranded DNA (msDNA). Reverse transcriptases from retron-Ec73 and retron-Ec107 do not contain an RNase H domain. Cellular RNase H is therefore considered to be required to make the mature form of msDNA. We found that RNase HI, but not RNase HII, is required for the production of the mature form of both msDNAs.
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PMID:The role of ribonuclease H in multicopy single-stranded DNA synthesis in retron-Ec73 and retron-Ec107 of Escherichia coli. 752 2

The reverse transcriptase of retroviruses contains an RNase H activity essential for the proper synthesis of the viral DNA copy of the RNA genome. We have previously characterized a number of point mutations altering the RNase domain of the Moloney murine leukemia virus reverse transcriptase (S. W. Blain and S. P. Goff, J. Biol. Chem. 268:23585-23592, 1993). One such mutation, Y586F (a Y-to-F change at position 586), reduced RNase H activity, as assayed by in situ gel analysis, to about 5% of the wild-type level and prevented viral replication. We have now recovered a revertant virus with near-normal infectivity and in vitro enzymatic activity. The revertant contains a single substitution, N613H, distant in the primary sequence of the protein, but modeling with the Escherichia coli RNase H structure suggests that the reverted residue is close in space to the original substituted residue. Examination of the structure permits some suggestions as to how this second-site revertant restores enzyme activity.
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PMID:Reversion of a Moloney murine leukemia virus RNase H mutant at a second site restores enzyme function and infectivity. 754 47

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