Gene/Protein
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Enzyme
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Pivot Concepts:
Gene/Protein
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Drug
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Target Concepts:
Gene/Protein
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Enzyme
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Query: EC:3.1.27.5 (
RNase
)
17,967
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The way in which a single-base bulge might affect the structure of an RNA helix has been examined by preparing a series of six RNA hairpins, all with seven base pairs and a four-nucleotide loop. Five of the hairpins have single-base bulges at different positions. The intercalating cleavage reagent (methidiumpropyl)-EDTA-Fe(II) [
MPE
-Fe(II)] binds preferentially at a CpG sequence in the helix lacking a bulge and in four of the five hairpins with bulges. Hairpins with a bulge one or two bases to the 3' side of the CpG sequence bind ethidium 4-5-fold more strongly than the others. V1
RNase
, which is sensitive to RNA backbone conformation in helices, detects a conformational change in all of the helices when ethidium binds; the most dramatic changes, involving the entire hairpin stem, are in one of the two hairpins with enhanced ethidium affinity. Only a slight conformational change is detected in the hairpin lacking a bulge. A bulge adjacent to a CpG sequence in a 100-nucleotide ribosomal RNA fragment enhances
MPE
-Fe(II) binding by an order of magnitude. These results extend our previous observations of bulges at a single position in an RNA hairpin [White, S. A., & Draper, D.E. (1987) Nucleic Acids Res. 15, 4049] and show that (1) a structural change in an RNA helix may be propagated for several base pairs, (2) bulges tend to increase the number of conformations available to a helix, and (3) the effects observed in small RNA hairpins are relevant to larger RNAs with more extensive structure. A bulge in a DNA hairpin identical in sequence with the RNA hairpins does not enhance
MPE
-Fe(II) binding affinity, relative to a control DNA hairpin. The effects of bulges on ethidium intercalation are evidently modulated by helix structure.
...
PMID:Effects of single-base bulges on intercalator binding to small RNA and DNA hairpins and a ribosomal RNA fragment. 265 98
Methidiumpropyl-EDTA.Fe(II) [
MPE
.Fe(II)] in the presence of dithiothreitol, is shown to cleave phenylalanine-accepting tRNA (tRNAPhe) in a structure-specific fashion. Molar ratios of
MPE
.Fe(II) to tRNAPhe of less than 1 preferentially cleave phosphodiester bonds known to occur in double-stranded regions of the tRNAPhe molecule. Microdensitometric analysis of autoradiograms of
MPE
.Fe(II) cleavage products following gel electrophoresis reveals a correspondence between preferred sites of
MPE
.Fe(II) cleavage and sites in tRNAPhe most sensitive to cobra venom
ribonuclease
, a double-strand-specific endoribonuclease. Conversely, sites of cleavage by the single-strand-specific S1 nuclease correspond to those nucleotides that are least susceptible to
MPE
.Fe(II) hydrolysis. Sensitive helical regions in tRNAPhe include the dihydrouracil and the "T psi C" stems, which cannot be detected by cobra venom
ribonuclease
because of steric constraints. Phosphodiester bonds within the T psi C and dihydrouracil loop regions, which are not detected by S1 nuclease under rigorously controlled digestion conditions, are revealed by inference from their relative insensitivity to
MPE
.Fe(II). These results demonstrate the utility of
MPE
.Fe(II) as a general small molecular weight probe of RNA structure, having a greater accessibility to base-paired regions than do the more bulky enzymic probes.
...
PMID:RNA structure analysis using methidiumpropyl-EDTA.Fe(II): a base-pair-specific RNA structure probe. 620 9
