EC:3.1.27.3 - FACTA Search

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Query: EC:3.1.27.3 (RNase T1)
1,228 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The conformation of Escherichia coli 5 S rRNA was investigated using chemical and enzymatic probes. The four bases were monitored at one of their Watson-Crick positions with dimethylsulfate (at C(N-3) and A(N-1], with a carbodiimide derivative (at G(N-1) and U(N-3] and with kethoxal (at G(N-1, N-2]. Position N-7 of purine was probed with diethylpyrocarbonate (at A(N-7] and dimethylsulfate (at G(N-7]. Double-stranded or stacked regions were tested with RNase V1 and unpaired guanine residues with RNase T1. We also used lead(II) that has a preferential affinity for interhelical and loop regions and a high sensitivity for flexible regions. Particular care was taken to use uniform conditions of salt, magnesium, pH and temperature for the different enzymatic chemical probes. Derived from these experimental data, a three dimensional model of the 5 S rRNA was built using computer modeling which integrates stereochemical constraints and phylogenetic data. The three domains of 5 S rRNA secondary structure fold into a Y-shaped structure that does not accommodate long-range tertiary interactions between domains. The three domains have distinct structural and dynamic features as revealed by the chemical reactivity and the lead(II)-induced hydrolysis: domain 2 (loop B/helix III/loop C) displays a rather weak structure and possesses dynamic properties while domain 3 (helix V/region E/helix IV/loop D) adopts a highly structured and overall helical conformation. Conserved nucleotides are not crucial for the tertiary folding but maintain an intrinsic structure in the loop regions, especially via non-canonical pairing (A.G, G.U, G.G, A.C, C.C), which can close the loops in a highly specific fashion. In particular, nucleotides in the large external loop C fold into an organized conformation leading to the formation of a five-membered loop motif. Finally, nucleotides at the hinge region of the Y-shape are involved in a precise array of hydrogen bonds based on a triple interaction between U14, G69 and G107 stabilizing the quasi-colinearity of helices II and V. The proposed tertiary model is consistent with the localization of the ribosomal protein binding sites and possesses strong analogy with the model proposed for Xenopus laevis 5 S rRNA, indicating that the Y-shape model can be generalized to all 5 S rRNAs.
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PMID:Three-dimensional model of Escherichia coli ribosomal 5 S RNA as deduced from structure probing in solution and computer modeling. 171 95

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

The interaction of ribosomal protein EL23 from E. coli and L25 from yeast with yeast 26S rRNA was analysed by nitrocellulose filter binding and RNase protection experiments using both intact rRNA and various fragments prepared by in vitro transcription of cloned yeast rDNA regions in the SP6 system. The results show that EL23 efficiently and specifically interacts with the region of 26S rRNA previously identified as the binding site for the yeast ribosomal protein L25. A comparison of the oligonucleotides resulting from limited RNase T1 digestion of the heterologous EL23/26S rRNA complex with those obtained by the same treatment of the homologous L25/26S rRNA complex showed that the molecular details of the two r-protein/rRNA interactions are highly similar if not identical. Using the synthetic 26S rRNA fragments we could demonstrate that all information for the formation of a biologically active binding site is located within the region of the rRNA delimited by the sequences protected by L25 against RNase T1 digestion. Part of the sequence at the 3' end of the 5'-distal protected region, however, was found not to be essential for r-protein binding although it does enhance the efficiency of this binding. Binding experiments using synthetic mouse 28S rRNA fragments showed that neither EL23 nor L25 interact with the structural equivalent of their respective cognate binding sites present in this mammalian rRNA. We argue that the structure of the expansion sequence present in this region of mouse 28S rRNA is a major cause of this failure.
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PMID:Interaction of ribosomal proteins L25 from yeast and EL23 from E. coli with yeast 26S and mouse 28S rRNA. 312 31

The heterologous interaction of Escherichia coli ribosomal protein EL11 with yeast 26 S and mouse 28 S rRNA was studied by analysing the ability of this protein to form a specific complex with various synthetic rRNA fragments that span the structural equivalent of the EL11 binding site present in these eukaryotic rRNAs. The fragments were obtained by SP6 polymerase-directed in-vitro run-off transcription of parts of the yeast or mouse large rRNA gene cloned behind the SP6 promoter. EL11 was found to protect an oligonucleotide fragment of 63 nucleotides from both the yeast and mouse transcripts against digestion by RNase T1. In both cases, the position of this fragment in the L-rRNA sequence coincides almost exactly with that of the fragment previously found to be protected by EL11 in E. coli 23 S rRNA. Moreover, the protected yeast fragment was shown to be able to re-bind to EL11 by a nitrocellulose filter binding assay. A ribosomal protein preparation from Saccharomyces cerevisiae containing L15 (YL23) as well as the acidic proteins L44', L44 and L45 protects exactly the same oligonucleotide fragment as does EL11 in both the yeast and mouse transcripts. Evidence is provided that L15, which is known to be structurally and functionally equivalent to EL11, is the rRNA-binding protein in this preparation. Thus the structural equivalent of the EL11 binding site present in yeast 26 S rRNA constitutes the second example of functional conservation of a ribosomal protein-binding site on rRNA between prokaryotes and eukaryotes.
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PMID:Ribosomal proteins EL11 from Escherichia coli and L15 from Saccharomyces cerevisiae bind to the same site in both yeast 26 S and mouse 28 S rRNA. 330 45

70S ribosomes from E. coli were chemically cross-linked under conditions of in vitro protein biosynthesis. The ribosomal RNAs were extracted from reacted ribosomes and separated on sucrose gradients. The 5S RNA was shown to contain the ribosomal protein L25 covalently bound. After total RNase T1 hydrolysis of the covalent RNA-protein complex several high molecular weight RNA fragments were obtained and identified by sequencing. One fragment, sequence region U103 to U120, was shown to be directly linked to the protein first by protein specific staining of the particular fragment and second by phosphor cellulose chromatography of the covalent RNA-protein complex. The other two fragments, U89 to G106 and A34 to G51, could not be shown to be directly linked to L25 but were only formed under cross-linking conditions. While the fragment U89 to G106 may be protected from RNase T1 digestion because of a strong interaction with the covalent RNA-protein complex, the formation of the fragment A34 to G51 is very likely the result of a double monovalent modification of two neighbouring guanosines in the 5S RNA. The RNA sequences U103 to U120 established to be in direct contact to the protein L25 within the ribosome falls into the sequence region previously proposed as L25 binding site from studies with isolated 5S RNA-protein complexes.
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PMID:Analysis of a sequence region of 5S RNA from E. coli cross-linked in situ to the ribosomal protein L25. 389 85

The ribosomal protein complex L8 of Escherichia coli consists of two dimers of protein L7/L12 and one monomer of protein L10. This pentameric complex and ribosomal protein L11 bind in mutually cooperative fashion to 23 S rRNA and protect specific fragments of the latter from digestion with ribonuclease T1. Oligonucleotides protected either by the L8 complex alone or by the complex plus protein L11 were isolated from such digests and shown to rebind specifically to these proteins. They were also subjected to nucleotide sequence analysis. The longest oligonucleotide, protected by the L8 complex alone, consisted of residues 1028-1124 of 23 S rRNA and included all the other RNA fragments produced in this study. Previously, protein L11 had been shown to protect residues 1052-1112 of 23 S rRNA. It is concluded that the binding sites for the L8 protein complex and for protein L11 are immediately adjacent within 23 S rRNA of E. coli.
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PMID:The binding site for ribosomal protein complex L8 within 23 s ribosomal RNA of Escherichia coli. 637 61

Escherichia coli 16S, 23S, and 5S ribosomal RNAs (rRNAs) are transcribed as a single primary transcript, which is subsequently processed into mature rRNAs by several RNases. Three RNases (RNase III, RNase E, and RNase G) were reported to function in processing the 5'-leader of precursor 16S rRNA (pre-16S rRNA). Previously, we showed that a novel essential YqgF is involved in that processing. Here we investigated the ribosome subunits of the yqgFts mutant by LC-MS/MS. The mutant ribosome had decreased copy numbers of ribosome protein S1, suggesting that the yqgF gene enables incorporation of ribosomal protein S1 into ribosome by processing of the 5'-end of pre-16S rRNA. The ribosome protein S1 is essential for translation in E. coli; therefore, our results suggest that YqgF converts the inactive form of newly synthesized ribosome into the active form at the final step of ribosome assembly.
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PMID:Subunit Composition of Ribosome in the yqgF Mutant Is Deficient in pre-16S rRNA Processing of Escherichia coli. 3056 52