EC:3.1.26.9 - FACTA Search

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Query: EC:3.1.26.9 (ribonuclease)
6,589 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This investigation was designed to characterize the immunoprotective antigen of ribosomal preparations from Haemophilus influenzae. The ribosomes that elicited 80 to 90% protection contained 25% protein and 75% ribonucleic acid but did not contain any detectable hexoses. The immunodiffusion and hemagglutination inhibition tests also failed to demonstrate that the capsular material (polyribose phosphate) was in ribosomal preparations. Treatment of ribosomes with ribonuclease degraded 78% ribonucleic acid but did not affect the immunogenicity of such preparations. The proteolytic enzymes reduced the immunogenicity of ribosomes corresponding to the amount of protein degraded. The protection elicited by ribosomal protein extracted with 2-chloroethanol was comparable to that induced by intact ribosomes. In contrast, the low levels of protection observed by immunization with phenol-extracted ribonucleic acid were dependent on the amounts of contaminating protein. Finally, immunogenicity of ribosomal ribonucleic acid and protein was abrogated by treatment with proteolytic enzymes. These results clearly indicate that the protein associated with Haemophilus ribosomes is the major immunoprotective antigen.
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PMID:Characterization of the immunoprotective antigen of ribosomal preparations from Haemophilus influenzae. 30 44

Ribonucleoproteins were prepared by ribonuclease digestion of a reconstitued complex of ribosomal protein L 1 and 23-S RNA from Escherichia coli. Three main ribonucleoproteins were identified. The largest was only obtained in an impure state at low ribonuclease concentration, whereas the two smaller ones, which were difficult to separate from one another electrophoretically, were stable over a range of enzyme concentrations. The two smaller ribonucleoproteins yielded a total of 13 RNA subfragments that were judged to be homogeneous electrophoretically. The latter were characterized for molecular weight and the subfragment composition of each of these ribonucleoproteins was established. Furthermore, the subfragments were shown to be maintained together in each ribonucleoprotein by RNA-RNA interactions. The primary and specific binding site of protein L1 was localized on one continuous RNA subfragment of about 110 nucleotides in length by two newly developed binding methods.
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PMID:The binding site of protein L1 on 23-S ribosomal RNA of Escherichia coli. 1. Isolation and characterization. 82 38

Ribonucleoproteins were obtained by T1 ribonuclease digestion of reconstitued complexes of ribosomal protein L1 AND 23-S RNA from Escherichia coli. The RNA region of the main ribonucleoprotein 2 was totally digested with T1 ribonuclease. The oligonucleotide products were characterised and they showed that this region comprises 148 nucleotides located between the 550th and 1000th necleotides from the 3' end of the 23-S RNA. Of the other two ribonucleoproteins, the largest ribonucleoprotein 1 contained an extra RNA sequence, of at least 15 nucleotides, that was located at the 5' end of the RNA region. The smallest ribonucleoprotein 3 lacked an RNA section towards the 3' end of the region. The order of the RNA subfragments and the enzymic cutting positions in the whole RNA region are given for the ribonucleoproteins. It is shown that protein L1 most strongly protects a continuous section of 115 nucleotides at the 5' end of the main RNA region. Finally, evidence is presented for a methylated base, and for two sequence heterogeneities, in this region of the 23-S RNA.
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PMID:The binding site of protein L1 ON 23-S ribosomal RNA of Escherichia coli. 2. Identification of the rna region contained in the L1 ribonucleoproteins and determination of the order of the RNA subfragments within this region. 82 39

A new transcription unit has been identified and characterized in the small single-copy region of tobacco chloroplast DNA. A primary transcript (1550 nucleotides) spanning the entire transcription unit contains no significant open reading frames (ORFs), other than ORF55, recently identified as the gene encoding the ribosomal protein CL32 (rpl32). The leader sequence extends 1101 nucleotides from the rpl32 initiation codon. Primer extension and in vitro capping experiments in combination with ribonuclease protection assays, revealed a promoter situated more than 322 bp inside the coding region of ndhF, which is divergently oriented with respect to rpl32. A canonical Pribnow-box is found just upstream of the transcription start site, but a typical -35 motif was not detected. This is the first internal divergent promoter to be characterized in the chloroplast genome.
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PMID:Active transcription from a promoter positioned within the coding region of a divergently oriented gene: the tobacco chloroplast rpl32 gene. 160 58

E. coli rnpA and rpmH genes encoding the protein portion of ribonuclease (RNase) P and L34 ribosomal protein were found to be homologous to the entire sequence of M1 RNA and virusoids. The resulting alignment strongly suggests that most primitive mRNAs must have emerged from virusoid-like ribo-organism.
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PMID:Possible evolutionary origin of primitive protein-encoding mRNAs as a virusoid-like ribo-organism. 171 69

A wheat germ protease is responsible for Mr 105,000 methionyl-tRNA synthetase hydrolysis, generating two fragments of Mr 82,000 (harbouring the catalytic domain) and 20,000, respectively. Specificity of the protease was sought for using different kinds of protein substrates. It turned out that charged peptides were preferentially cleaved and that no proteolysis occurred when proteins were replaced by small synthetic substrates, harbouring target sites similar to those cleaved in proteins. The protease could be a ribosomal protein, since it remained associated to ribosomal structure, even after treatment by deoxycholate, Triton X-100, 800 mM KC1 and puromycin. Nevertheless, it was still active after ribonuclease treatment of the ribosomes. An identical protease activity was found in rat liver, but not in E. coli.
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PMID:Evidence for a ribosome-associated thiol protease cleaving wheat germ methionyl-tRNA synthetase. 186 82

1. The behaviour of the large ribosomal subunit from Rhodopseudomonas spheroides (45S) has been compared with the 50S ribosome from Escherichia coli M.R.E. 600 (and E. coli M.R.E. 162) during unfolding by removal of Mg(2+) and detachment of ribosomal proteins by high univalent cation concentrations. The extent to which these processes are reversible with these ribosomes has also been examined. 2. The R. spheroides 45S ribosome unfolds relatively slowly but then gives rise directly to two ribonucleoprotein particles (16.6S and 13.7S); the former contains the intact primary structure of the 16.25S rRNA species and the latter the 15.00S rRNA species of the original ribosome. No detectable protein loss occurs during unfolding. The E. coli ribosome unfolds via a series of discrete intermediates to a single, unfolded ribonucleoprotein unit (19.1S) containing the 23S rRNA and all the protein of the original ribosome. 3. The two unfolded R. spheroides ribonucleoproteins did not recombine when the original conditions were restored but each simply assumed a more compact configuration. Similar treatments reversed the unfolding of the E. coli 50S ribosomes; replacement of Mg(2+) caused the refolding of the initial products of unfolding and in the presence of Ni(2+) the completely unfolded species (19.1S) again sedimented at the same rate as the original ribosomes (44S). 4. Ribosomal proteins (25%) were dissociated from R. spheroides 45S ribosomes by dialysis against a solution with a Na(+)/Mg(2+) ratio of 250:1. During this process two core particles were formed (21.2S and 14.2S) and the primary structures of the two original rRNA species were conserved. This dissociation was not reversed. With E. coli 50S approximately 15% of the original ribosomal protein was dissociated, a single 37.6S core particle was formed, the 23S rRNA remained intact and the ribosomal proteins would reassociate with the core particle to give a 50S ribosome. 5. The ribonuclease activities in R. spheroides 45S and E. coli M.R.E. 600 and E. coli M.R.E. 162 50S ribosomes are compared. 6. The observations concerning unfolding and dissociation are consistent with previous reports showing the unusual rRNA complement of the mature R. spheroides 45S ribosome and show the dependence of these events upon the rRNA and the importance of protein-protein interactions in the structure of the R. spheroides ribosome.
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PMID:A comparison of the unfolding and dissociation of the large ribosome subunits from Rhodopseudomonas spheroides N.C.I.B. 8253 and Escherichia coli M.R.E. 600. 420 5

The distribution of ribosomal protein binding sites on the 16S ribosomal RNA molecule has been analyzed by limited ribonuclease hydrolysis of RNA-protein complexes, as well as by the interaction of individual proteins with RNA fragments purified from partial enzymatic digests. Of the six 30S subunit proteins known to interact directly with 16S RNA, proteins S4, S8, S15, S20, and, probably, S13 bind within a fragment produced by T(1) RNase (12S RNA) that comprises some 900 nucleotides and covers almost the entire 5'-terminal half of the 16S molecule. A fragment of 500-600 nucleotides (8S RNA) that is contiguous with 12S RNA and arises from the 3'-terminal portion of the 16S molecule is believed to contain the binding site for protein S7. Protein S15 interacts specifically with a sequence of about 135 nucleotides (4S RNA) that derives from 12S RNA after more extensive hydrolysis. Protein S4, but none of the other ribosomal proteins, binds to a 500-nucleotide fragment (9S RNA), generated by pancreatic RNase, that lies at the 5'-terminus of 16S RNA and is completely overlapped by the 12S fragment. A preliminary map of the binding sites is presented.
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PMID:Location of ribosomal protein binding sites on 16S ribosomal RNA. 455 59

A ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA has been crystallized. The space group is P6(1)22 or P6(5)22, with a = 59.5 A and C = 268 A. The crystals contain one molecule per asymmetric unit, and show diffraction to 4.0 A resolution. Also, a complex of this fragment with L25 ribosomal protein has been crystallized in the same space group, but with a = 119 A, c = 250 A and four molecules per asymmetric unit.
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PMID:Crystallization of a ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA and its complex with protein L25. 619 27

Ribosomal protein L1 from the prokaryote Escherichia coli has been shown to form a specific complex with 26S ribosomal RNA from the eukaryote Dictyostelium discoideum. The segment of Dictyostelium rRNA protected from ribonuclease digestion by L1 and the corresponding region in Dictyostelium rDNA were investigated by nucleotide sequence analysis, and an analogous section in rDNA from Xenopus laevis was identified. When the L1-specific segments from eukaryotic rRNA were compared with those from prokaryotic rRNA, striking similarities in both primary and secondary structure were apparent. These conserved features suggest a common structural basis for protein recognition and indicate that such regions became fixed at a very early stage in rRNA evolution. In addition, certain structural elements of the L1 binding sites in rRNA are also found in the initial segment of the polycistronic L11-L1 mRNA, providing support for the hypothesis that L1 participates in the regulation of ribosomal protein synthesis by specific interaction with its own mRNA.
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PMID:Specific binding of a prokaryotic ribosomal protein to a eukaryotic ribosomal RNA: implications for evolution and autoregulation. 626 4

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