Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.30.1 (S1 nuclease)
 3,660 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

5 S RNA was isolated from Saccharomyces cerevisiae grown in the presence of 32P-phosphate and digested with nuclease S1, a single-strand specific nuclease. Two different procedures were employed to determine the sites of attack on the RNA. First, 5 S RNA was isolated from nuclease S1 digests, digested to completion with ribonuclease T1, and then 'fingerprinted' by two-dimensional electrophoresis. Quantitation of each of the characteristic RNAase T1-derived oligonucleotides was employed to determine the relative susceptibility of various regions of the molecule to nuclease S1. A second procedure to define nuclease S1-susceptible sites in the molecule employed polyacrylamide gel electrophoretic fractionation of nuclease S1 digests followed by identification of the nucleotide sequences of the released RNA fragments. Both procedures showed that the region of the molecule between residues 9 and 60 was most susceptible to nuclease S1, with preferential cleavage occurring between residues 12-25 and 50-60. These results are discussed in relation to a proposed model for the secondary structure of yeast 5 S RNA.
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PMID:S1 nuclease as a probe of yeast ribosomal 5 S RNA conformation. 37 85

Basal bodies, purified from Chlamydomonas and Tetrahymena, were exposed to various enzymatic treatments and then assayed for their ability to nucleate aster formation upon injection into eggs of Xenopus laevis. Untreated basal bodies injected into frog eggs act as centrioles and induce the formation of asters. The aster-inducing activity of basal bodies was eliminated by treatment with proteolytic enzymes and ribonucleases. Aster-inducing activity was not affected by DNAse and a number of other enzymes. The effect of proteolytic digestion on aster-inducing activity appeared to be directly correlated with the degree of structural damage to the basal body. Low concentrations of pancreatic ribonuclease A, ribonuclease T1, and S1 nuclease also completely abolished aster-inducing activity, although these enzymes had no effect on basal body structure. Ribonuclease-treated basal bodies remained capable of supporting microtubule elongation in vitro. Preliminary evidence indicates that basal bodies from Chlamydomonas and Tetrahymena contain about 5 x 10(-16) g of RNA which co-band with basal bodies and aster-inducing activity by equilibrium density gradient sedimentation. We conclude first, that centrioles contain RNA which is required for initiation of aster formation, and second, that the centriole activity or ability to assemble a mitotic aster is separable from the basal body activity, or ability to serve directly as a template for microtubule growth.
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PMID:Evidence for a functional role of RNA in centrioles. 40 9

The results of ribonuclease T1 oligonucleotide fingerprint analyses indicate that influenza virus messenger RNAs are incomplete transcripts of the corresponding genome RNAs and that in this respect they differ from the unpolyadenylated virus specific complementary RNAs obtained from infected cells. From the position of the untranscribed oligonucleotide in the virus RNA sequence and the ability or inability of the different transcripts to protect the 5' terminal nucleotide of virus RNAs against nuclease S1 digestion, it is concluded that whereas the unpolyadenylated cRNAs are complete transcripts, the polyadenylated messenger RNAs lack sequences complementary to the 5' end of the genome molecules.
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PMID:Influenza virus messenger RNAs are incomplete transcripts of the genome RNAs. 41 7

Ribosomal 5S 32 P-labelled RNA was isolated from imbibing wheat embryos and digested with nuclease S1, a single-strand specific nuclease. The products of enzymic digestion were separated by polyacrylamide gel electrophoresis and identified by fingerprint analysis of their RNase T1 digestion products. The results indicate that the most sensitive portion of the molecule, and hence, the region containing the least helical structure, is close to the 5'-terminus. Similarly, the most resistant portion of the molecule is close to, but does not include, the 3'-terminus. These findings are discussed in relation to proposed models for the secondary structure of 5S RNA.
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PMID:Conformational studies on wheat embryo 5S RNA using nuclease S1 as a probe. 66 86

The single-strand specific nuclease S1 from Aspergillus oryzae (EC 3.1.4.21) was purified 600-fold in 16% yield from dried mycelia. Determination of the isoelectric point of S1 nuclease as 4.3-4.4 allowed adjustment of chromatographic conditions such that the enzyme was isolated free of contaminating ribonucleases T1 and T2. S1 nuclease so purified was used for removal of single-stranded portions from the RNA of the Escherichia coli phage MS2, which has a helical content of about 65% in vitro. At 23 degrees, increasing amounts of enzyme converted the RNA to mononucleotides in about equimolar base ratios. No small intermediates of chain length 2-8 were found. At 0 degrees, MS2 RNA hydrolysis was slower and reached, in exhaustive digests, a plateau where 70% of the substrate RNA remained insoluble in 66% EtOH. With [32P]MS2 RNA, strip chart counting of 6% acrylamide-6 M urea electrophoresis patterns of such digests gave recoveries of 80-91% in the form of defined oligomer bands. On 2.5% acrylamide-0.5% agarose gels, the molecular weights of the major oligomers were found to range from 25,000 to 41,000. Similar to purified tRNAArg used as a control, these oligomers were not resistant to pancreatic RNase-RNase T1 hydrolysis at 37 degrees, and were not bound on hydroxylapatite at 50 degrees in 0.14 M sodium phosphate (pH 6.8). Melting of the oligomers gave complex profiles without a clear Tm and showed an increase in A260 of 35% at 93 degrees over that at 28 degrees. Upon formaldehyde denaturation of MS2 RNA prior to S1 nuclease hydrolysis, no resistant oligomers were found.
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PMID:S1 nuclease hydrolysis of single-stranded nucleic acids with partial double-stranded configuration. 118 98

We have used photoaffinity labelling to examine the chloroplast RNA polymerase components which come into contact with nascent transcripts during the in vitro transcription of plastid DNA. The transcripts were synthesized in the presence of a photoactive analogue (4-thio UTP) and alpha-32P-ATP, using enriched pea chloroplast RNA polymerase preparation and a recombinant plasmid containing the plastid 16S rRNA promoter. Brief irradiation of the transcriptional complex crosslinked the photoactive nascent RNA to proximal proteins. Labelling of the transcriptional complex was dependent on 4-thio UTP and template DNA. Two polypeptides of 51 and 54 kDa were consistently crosslinked to the nascent transcripts; about 60% of the total radioactivity of the crosslinked RNA was associated with these polypeptides. In some experiments, two additional polypeptides of 38 and 75 kDa were also found to be associated with about 13% and 17% of the total crosslinked RNA radioactivity, respectively. The UV-crosslinked transcriptional complexes were stable to either DNase or S1 nuclease hydrolysis but partially sensitive to RNase T1. Insensitivity of the complex to hydrolysis with RNase H suggested that the nascent transcripts were not crosslinked to the template. The complexes could also be hydrolysed by proteinase K and thermolysin. No crosslinkage was observed when labelled RNA molecules containing 4-thio UMP residues were added after synthesis to the polymerase preparation. This suggested that the method identified only those polypeptides which came into close contact with the transcript during its synthesis. Antibodies raised against the RNA-protein complex confirmed the presence of the polypeptides in the chloroplast RNA polymerase preparation on Western blots. Preincubation of these antibodies with the chloroplast RNA polymerase inhibited plastid DNA transcription. These data showed that the transcript-binding polypeptides were functional components of the chloroplast transcriptional complex.
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PMID:Photoaffinity labelling of the pea chloroplast transcriptional complex by nascent RNA in vitro. 171 36

Site-directed mutations were introduced in the connecting loops and one of the two stem regions of the RNA pseudoknot in the tRNA-like structure of turnip yellow mosaic virus RNA. The kinetic parameters of valylation for each mutated RNA were determined in a cell-free extract from wheat germ. Structure mapping was performed on most mutants with enzymic probes, like RNase T1, nuclease S1 and cobra venom ribonuclease. An insertion of four A residues in the four-membered connecting loop L1 that crosses the deep groove of the pseudoknot reduces aminoacylation efficiency. Deletions up to three nucleotides do not affect aminoacylation or RNA pseudoknot formation. Deletion of the entire loop abolishes aminoacylation. Although elimination of the pseudoknot is presumed, this could not be demonstrated. Unlike the mutations in loop L1, all mutations in the three-membered connecting loop L2 that crosses the shallow groove of the RNA pseudoknot decrease the aminoacylation efficiency considerably. Nonetheless, the RNA pseudoknot is still present in most mutated RNAs. These results indicate that a number of mutations can be introduced in both loops without abolishing aminoacylation. Results obtained with the introduction of mismatches and A.U base-pairs in stem S1 of the pseudoknot, containing three G.C base-pairs in wild-type RNA, indicate that the pseudoknot is only marginally stable. Our estimation of the gain of free energy due to the pseudoknot formation is at most 2.0 kcal/mol. The pseudoknot structure can, however, be stabilized upon binding the valyl-tRNA synthetase.
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PMID:Mutational analysis of the pseudoknot in the tRNA-like structure of turnip yellow mosaic virus RNA. Aminoacylation efficiency and RNA pseudoknot stability. 173 Oct 70

We have investigated the transcription patterns at the inter-operon regions between the S10 and spc, and spc and alpha ribosomal protein operons of Escherichia coli. Newly synthesized transcripts were characterized by RNase T1 protection experiments, and accumulated transcripts were mapped with S1 nuclease. With both techniques we found that about 75% of the RNA polymerases transcribing the S10 operon terminated at the position of a typical rho-independent terminator. In contrast, most or all RNA polymerases transcribing the spc operon continued into the alpha operon. Nevertheless, we observed that about 30% of the transcripts of the alpha operon were initiated at the alpha operon promoter.
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PMID:Transcriptional organization of the S10, spc and alpha operons of Escherichia coli. 220 63

We have investigated in detail the secondary and tertiary structures of E. coli 16S rRNA binding site of protein S15 using a variety of enzymatic and chemical probes. RNase T1 and nuclease S1 were used to probe unpaired nucleotides and RNase V1 to monitor base-paired or stacked nucleotides. Bases were probed with dimethylsulfate (at A(N-1), C(N-3) and G(N-7)), with 1-cyclohexyl-3 (2-(1-methylmorpholino)-ethyl)-carboiimide-p- toluenesulfonate (at U(N-3) and G(N-1)) and with diethylpyrocarbonate (at A(N-7)). The RNA region corresponding to nucleotides 652 to 753 was tested within: (1) the complete 16S rRNA molecule; (2) a 16S rRNA fragment corresponding to nucleotides 578 to 756 obtained by transcription in vitro; (3) the S15-16S rRNA complex; (4) the S15-fragment complex. Cleavage and modification sites were detected by primer extension with reverse transcriptase. Our results show that: (1) The synthetized fragment folds into the same overall secondary structure as in the complete 16S rRNA, with the exception of the large asymmetrical internal loop (nucleotides 673-676/714-733) which is fully accessible in the fragment while it appears conformationally heterogeneous in the 16S rRNA; (2) the reactivity patterns of the S15-16S rRNA and S15-fragment complexes are identical; (3) the protein protects defined RNA regions, located in the large interior loop and in the 3'-end strand of helix [655-672]-[734-751]; (4) the protein also causes enhanced chemical reactivity and enzyme accessibility interpreted as resulting from a local conformational rearrangement, induced by S15 binding.
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PMID:The E. coli 16S rRNA binding site of ribosomal protein S15: higher-order structure in the absence and in the presence of the protein. 245 25

Translational initiation factor 3 (IF3) is an RNA helix destabilizing protein which interacts with strongly conserved sequences in 16S rRNA, one at the 3' terminus and one in the central domain. It was therefore of interest to identify particular residues whose exposure changes upon IF3 binding. Chemical and enzymatic probing of central domain nucleotides of 16S rRNA in 30S ribosomal subunits was carried out in the presence and absence of IF3. Bases were probed with dimethyl sulfate (DMS), at A(N-1), C(N-3), and G(N-7), and with N-cyclohexyl-N'-[2-(N-methyl-4-morpholinio)ethyl] carbodiimide p-toluenesulfonate (CMCT), at G(N-1) and U(N-3). RNase T1 and nuclease S1 were used to probe unpaired nucleotides, and RNase V1 was used to monitor base-paired or stacked nucleotides. 30S subunits in physiological buffers were probed in the presence and absence of IF3. The sites of cleavage and modification were detected by primer extension. IF3 binding to 30S subunits was found to reduce the chemical reactivity and enzymatic accessibility of some sites and to enhance attack at other sites in the conserved central domain of 16S rRNA, residues 690-850. IF3 decreased CMCT attack at U701 and U793 and V1 attack at G722, G737, and C764; IF3 enhanced DMS attack at A814 and V1 attack at U697, G833, G847, and G849. Many of these central domain sites are strongly conserved and with the conserved 3'-terminal site define a binding domain for IF3 which correlates with a predicted cleft in two independent models of the 30S ribosomal subunit.
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PMID:Escherichia coli initiation factor 3 protein binding to 30S ribosomal subunits alters the accessibility of nucleotides within the conserved central region of 16S rRNA. 251 87


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