Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.27.5 (RNase)
 17,967 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

RNA cleaving molecules were synthesized by conjugating imidazole residues imitating the essential imidazoles in the active center of pancreatic ribonuclease to an intercalating compound, derivative of phenazine capable of binding to the double stranded regions of polynucleotides. Action of the molecules on tRNA was investigated. It was found, that some of the compounds bearing two imidazole residues cleave tRNA under physiological conditions. The cleavage reaction shows a bell-shaped pH dependence with a maximum at pH 7.0 indicating participation of protonated and non-protonated imidazole residues in the process. Under the conditions stabilizing the tRNA structure, a tRNAAsp transcript was cleaved preferentially at the junctions of the stem and loop regions of the cloverleaf tRNA fold, at the five positions C56, C43, C20.1, U13, and U8, with a marked preference for C56. This cleavage pattern is consistent with a hydrolysis mechanism involving non-covalent binding of the compounds to the double-stranded regions of tRNA followed by an attack of the imidazole residues at the juxtaposed flexible single-stranded regions of the molecule. The compounds provide new probes for the investigation of RNA structure in solution and potential reactive groups for antisense oligonucleotide derivatives.
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PMID:Synthetic RNA-cleaving molecules mimicking ribonuclease A active center. Design and cleavage of tRNA transcripts. 750 35

Drosophila RNase P and 3'-tRNase endonucleolytically process the 5' and 3' ends of tRNA precursors. We examined the processing kinetics of normal substrates and the inhibitory effect of the tRNA product on both processing reactions. The product is not a good RNase P inhibitor, with a KI approximately 7 times greater than the substrate KM of approximately 200 nM and is a better inhibitor of 3'-tRNase, with a KI approximately two times the KM of approximately 80 nM. We generated matrices of substitutions at positions G18/U55 and G19/C56 (two contiguous universally conserved D/T loop base pairs) in Drosophila tRNAHis precursors. More than half the variants display a significant reduction in their ability to be processed by RNase P and 3'-tRNase. Minimal substrates with deleted D and anticodon stems could be processed by RNase P and 3'-tRNase much like full-length substrates, indicating that D/T loop contacts and D arm/enzyme contacts are not required by either enzyme. Selected tRNAs that were poor substrates for one or both enzymes were further analyzed using Michaelis-Menten kinetics and by structure probing. Processing reductions arise principally due to an increase in KM with relatively little change in Vmax, consistent with the remote location of the sequence and structure changes from the processing site for both enzymes. Local changes in variant tRNA susceptibility to RNase T1 and RNase A did not coincide with processing disabilities.
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PMID:Matrices of paired substitutions show the effects of tRNA D/T loop sequence on Drosophila RNase P and 3'-tRNase processing. 942 63

A stable conformer of Escherichia coli tRNA(Glu), obtained in the absence of Mg(2+), is inactive in the aminoacylation reaction. Probing it with diethylpyrocarbonate, dimethyl sulfate and ribonuclease V1 revealed that it has a hairpin structure with two internal loops; the helical segments at both extremities have the same structure as the acceptor stem and the anticodon arm of the native conformer of tRNA(Glu)and the middle helix is formed of nucleotides from the D-loop (G15-C20:2) and parts of the T-loop and stem (G51-C56), with G19 bulging out. This model is consistent with other known properties of this inactive conformer, including its capacity to dimerize. Therefore, this tRNA requires magnesium to acquire a conformation that can be aminoacylated, as others require a post-transcriptional modification to reach this active conformation.
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PMID:Magnesium-dependent alternative foldings of active and inactive Escherichia coli tRNA(Glu) revealed by chemical probing. 1044 50