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)

RNase G (rng) is an E. coli endoribonuclease that is homologous to the catalytic domain of RNase E (rne), an essential protein that is a major participant in tRNA maturation, mRNA decay, rRNA processing and M1 RNA processing. We demonstrate here that whereas RNase G inefficiently participates in the degradation of mRNAs and the processing of 9S rRNA, it is not involved in either tRNA or M1 RNA processing. This conclusion is supported by the fact that inactivation of RNase G alone does not affect 9S rRNA processing and only leads to minor changes in mRNA half-lives. However, in rng rne double mutants mRNA decay and 9S rRNA processing are more defective than in either single mutant. Conversely, increasing RNase G levels in an rne-1 rng::cat double mutant, proportionally increased the extent of 9S rRNA processing and decreased the half-lives of specific mRNAs. In contrast, variations in the amount of RNase G did not alter tRNA processing under any circumstances. Thus, the failure of RNase G to complement rne mutations, even when overproduced at high levels, apparently results from its inability to substitute for RNase E in the maturation of tRNAs.
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PMID:RNase G of Escherichia coli exhibits only limited functional overlap with its essential homologue, RNase E. 1286 47

RNase G is a homologue of the essential Escherichia coli ribonuclease RNase E. Whereas RNase E plays a key role in the degradation of mRNA and the processing of tRNA and rRNA in E. coli, the biological functions of RNase G appear more limited. We report here that this difference in function is not merely a consequence of the significantly lower cellular concentration of RNase G, but also reflects differences in the intrinsic properties of these ribonucleases, as overproducing wild-type RNase G at a level up to 20 times the usual cellular concentration of RNase E cannot normally compensate for the absence of RNase E in E. coli. Instead, RNase G can sustain significant growth of RNase E-deficient E. coli cells only when it bears an unnatural extension at its amino terminus (e.g. MRKGINM) or carboxyl terminus (e.g. GHHHHHH). These extensions presumably enable RNase G to cleave critically important cellular RNAs whose efficient processing or degradation ordinarily requires RNase E. That extending the amino terminus of RNase G restores growth to E. coli cells lacking RNase E without detectably improving tRNA processing suggests that RNase E is not essential for tRNA production and is required for cell growth because it plays an indispensable role in the maturation or decay of essential E. coli RNAs other than tRNA.
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PMID:The function of RNase G in Escherichia coli is constrained by its amino and carboxyl termini. 1476 91

The RNase E/G homologue from the thermophilic eubacterium Aquifex aeolicus has been overexpressed in Escherichia coli, purified, and characterized in vitro. We show that A. aeolicus RNase E/G has a temperature-dependent, endoribonucleolytic activity. The enzyme site-specifically cleaves oligonucleotides and structured RNAs at locations that are partly overlapping or completely different when compared to the positions of E. coli RNase E and RNase G cleavage sites. The efficiency of cleavage by A. aeolicus RNase E/G is dependent on the 5'-phosphorylation status of RNA suggesting differential susceptibility of primary transcripts and their degradative intermediates to the nuclease activity of this enzyme in vivo. Similar to E. coli RNase E, A. aeolicus RNase E/G is able to selectively cleave internucleotide bonds in the 3'-5' direction, and to cut in intercistronic regions of putative tRNA precursors, thus suggesting a common function for RNase E/G homologues in eubacteria.
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PMID:Characterization of Aquifex aeolicus RNase E/G. 1562 27

Colicin E5 specifically cleaves four tRNAs in Escherichia coli that contain the modified nucleotide queuosine (Q) at the wobble position, thereby preventing protein synthesis and ultimately resulting in cell death. Here, the crystal structure of the catalytic domain of colicin E5 (E5-CRD) from E. coli was determined at 1.5 A resolution. Unexpectedly, E5-CRD adopts a core folding with a four-stranded beta-sheet packed against an alpha-helix, seen in the well-studied ribonuclease T1 despite a lack of sequence similarity. Beyond the core catalytic domain, an N-terminal helix, a C-terminal beta-strand and loop, and an extended internal loop constitute an RNA binding cleft. Mutational analysis identified five amino acids that were important for tRNA substrate binding and cleavage by E5-CRD. The structure, together with the mutational study, allows us to propose a model of colicin E5-tRNA interactions, suggesting the molecular basis of tRNA substrate recognition and the mechanism of tRNA cleavage by colicin E5.
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PMID:Structural and mutational studies of the catalytic domain of colicin E5: a tRNA-specific ribonuclease. 1606 Jun 58

Sequence placement of post-transcriptionally modified nucleosides in tRNA can be experimentally difficult, particularly in cases involving new or unexpected modifications or sequence sites. We describe a mass spectrometry-based approach to this problem, involving the following steps: crude isolations of one or several tRNAs by HPLC from an unfractionated tRNA mixture; digestion to oligonucleotide mixtures by RNase T1; analysis by combined HPLC/electrospray ionization-MS for recognition of modifications; and direct gas-phase sequencing of selected targets in the mixture by LC/MS/MS. Isoacceptor identity can be established in favorable cases when tRNA gene sequences are available.
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PMID:A novel method for sequence placement of modified nucleotides in mixtures of transfer RNA. 1715 May 79

tRNA is best known for its function as amino acid carrier in the translation process, using the anticodon loop in the recognition process with mRNA. However, the impact of tRNA on cell function is much wider, and mutations in tRNA can lead to a broad range of diseases. Although the cloverleaf structure of tRNA is well-known based on X-ray-diffraction studies, little is known about the dynamics of this fold, the way structural dynamics of tRNA is influenced by the modified nucleotides present in tRNA, and their influence on the recognition of tRNA by synthetases, ribosomes, and other biomolecules. One of the reasons for this is the lack of good synthetic methods to incorporate modified nucleotides in tRNA so that larger amounts become available for NMR studies. Except of 2'-O-methylated nucleosides, only one other sugar-modified nucleoside is present in tRNA, i.e., 2'-O-beta-D-ribofuranosyl nucleosides. The T loop of tRNA often contains charged modified nucleosides, of which 1-methyladenosine and phosphorylated disaccharide nucleosides are striking examples. A protecting-group strategy was developed to introduce 1-methyladenosine and 5''-O-phosphorylated 2'-O-(beta-D-ribofuranosyl)-beta-D-ribofuranosyladenine in the same RNA fragment. The phosphorylation of the disaccharide nucleoside was performed after the assembly of the RNA on solid support. The modified RNA was characterized by mass-spectrometry analysis from the RNase T1 digestion fragments. The successful synthesis of this T loop of the tRNA of Schizosaccharomyces pombe initiator tRNA(Met) will be followed by its structural analysis by NMR and by studies on the influence of these modified nucleotides on dynamic interactions within the complete tRNA.
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PMID:Synthesis of RNA containing O-beta-D-ribofuranosyl-(1''-2')-adenosine-5''-phosphate and 1-methyladenosine, minor components of tRNA. 1719 97

The separation of biologically active, pure, and specific tRNAs is difficult due to the overall similarity in secondary and tertiary structures of different tRNAs. Because prior methods do not facilitate high-resolution separations of the extremely complex mixture represented by a cellular tRNA population, global studies of tRNA identity and/or abundance are difficult. We have discovered that the enzymatic digestion of an individual tRNA by a ribonuclease (e.g., RNase T1) will generate digestion products unique to that particular tRNA, and we show that a comparison of an organism's complete complement of tRNA RNase digestion products yields a set of unique or "signature" digestion product(s) that ultimately enable the detection of individual tRNAs from a total tRNA pool. Detection is facilitated by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) and proof-of-principle is demonstrated on the whole tRNA pool from Escherichia coli. This method will enable the individual identification of tRNA isoacceptors without requiring specific affinity purification or extensive chromatographic and/or electrophoretic purification. Further, experimental identifications of tRNAs or other RNAs will now be possible using this signature digestion product approach in a manner similar to peptide mass fingerprinting used in proteomics, allowing RNomic studies of RNA at the post-transcriptional level.
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PMID:Mass spectrometry-based detection of transfer RNAs by their signature endonuclease digestion products. 1719 20

The widely accepted model for the processing of tRNAs in Escherichia coli involves essential initial cleavages by RNase E within polycistronic transcripts to generate pre-tRNAs that subsequently become substrates for RNase P. However, recently we identified two polycistronic tRNA transcripts whose endonucleolytic processing was solely dependent on RNase P. Here we show that the processing of the secG leuU and metT leuW glnU glnW metU glnV glnX polycistronic transcripts takes place through a different type of maturation pathway. Specifically, RNase P separates the tRNA units within each operon following the endonucleolytic removal of the distal Rho-independent transcription terminator, primarily by RNase E. Failure to remove the Rho-independent transcription terminator inhibits RNase P processing of both transcripts leading to a decrease in mature tRNA levels and dramatically increased levels of full-length transcripts in an RNase E deletion strain. Furthermore, we show for the first time that RNase G also removes the Rho-independent transcription terminator associated with the secG leuU operon. Our data also demonstrate that the Rne-1 protein retains significant activity on tRNA substrates at the non-permissive temperature. Taken together it is clear that there are multiple pathways involved in the maturation of tRNAs in E. coli.
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PMID:Rho-independent transcription terminators inhibit RNase P processing of the secG leuU and metT tRNA polycistronic transcripts in Escherichia coli. 1803

We present here a method to correlate tandem mass spectra of sample RNA nucleolytic fragments with an RNA nucleotide sequence in a DNA/RNA sequence database, thereby allowing tandem mass spectrometry (MS/MS)-based identification of RNA in biological samples. Ariadne, a unique web-based database search engine, identifies RNA by two probability-based evaluation steps of MS/MS data. In the first step, the software evaluates the matches between the masses of product ions generated by MS/MS of an RNase digest of sample RNA and those calculated from a candidate nucleotide sequence in a DNA/RNA sequence database, which then predicts the nucleotide sequences of these RNase fragments. In the second step, the candidate sequences are mapped for all RNA entries in the database, and each entry is scored for a function of occurrences of the candidate sequences to identify a particular RNA. Ariadne can also predict post-transcriptional modifications of RNA, such as methylation of nucleotide bases and/or ribose, by estimating mass shifts from the theoretical mass values. The method was validated with MS/MS data of RNase T1 digests of in vitro transcripts. It was applied successfully to identify an unknown RNA component in a tRNA mixture and to analyze post-transcriptional modification in yeast tRNA(Phe-1).
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PMID:Ariadne: a database search engine for identification and chemical analysis of RNA using tandem mass spectrometry data. 1927 66

Bacterial RNases are promising tools for the development of anticancer drugs. Neoplastic transformation leads to enhanced accumulation of rRNA and tRNA, and altered expression of regulatory noncoding RNAs. Cleavage of RNA in cancer cells is the main reason for the cytotoxic effects of exogenic RNases. We have shown that binase, a cytotoxic ribonuclease from Bacillus intermedius, affects the total amount of intracellular RNA and the expression of proapoptotic and antiapoptotic mRNAs. For four cell lines, we visualized cellular RNA by fluorescence microscopy, and determined RNA levels, viability and apoptosis by flow cytometry. We found that the level of cellular RNA was decreased in cells that were sensitive to the cytotoxic effects of binase. The RNA level was lowered by 44% in HEK cells transfected with the hSK4 gene of the Ca(2+)-activated potassium channels (HEKhSK4) and by 20% in kit-transformed myeloid progenitor FDC-P1iR1171 cells. The most significant decrease in RNA levels was registered in the subpopulations of apoptotic cells. However, the binase-induced RNA decrease did not correlate with apoptosis. Kit-transformed cells with binase-induced RNA decrease retained viability if the interleukin-dependent proliferation pathway was activated. Using quantitative RT-PCR with RNA samples isolated from the binase-treated HEKhSK4 cells, we found that the amount of mRNA of the antiapoptotic bcl-2 gene in vivo was reduced about two-fold. In contrast, expression of the proapoptotic genes p53 and hSK4 was increased 1.5-fold and 4.3-fold, respectively. These results show that binase is a regulator of RNA-dependent processes of cell proliferation and apoptosis.
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PMID:Binase cleaves cellular noncoding RNAs and affects coding mRNAs. 1996 15

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