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Query: EC:3.1.27.1 (
RNase
)
16,360
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Translational initiation factor 3 (IF3) is an RNA helix destabilizing protein which interacts with strongly conserved sequences in 16S rRNA, one at the 3' terminus and one in the central domain. It was therefore of interest to identify particular residues whose exposure changes upon IF3 binding. Chemical and enzymatic probing of central domain nucleotides of 16S rRNA in 30S ribosomal subunits was carried out in the presence and absence of IF3. Bases were probed with dimethyl sulfate (DMS), at A(N-1), C(N-3), and G(N-7), and with N-cyclohexyl-N'-[2-(N-methyl-4-morpholinio)ethyl] carbodiimide p-toluenesulfonate (
CMCT
), at G(N-1) and U(N-3). RNase T1 and nuclease S1 were used to probe unpaired nucleotides, and
RNase
V1 was used to monitor base-paired or stacked nucleotides. 30S subunits in physiological buffers were probed in the presence and absence of IF3. The sites of cleavage and modification were detected by primer extension. IF3 binding to 30S subunits was found to reduce the chemical reactivity and enzymatic accessibility of some sites and to enhance attack at other sites in the conserved central domain of 16S rRNA, residues 690-850. IF3 decreased
CMCT
attack at U701 and U793 and V1 attack at G722, G737, and C764; IF3 enhanced DMS attack at A814 and V1 attack at U697, G833, G847, and G849. Many of these central domain sites are strongly conserved and with the conserved 3'-terminal site define a binding domain for IF3 which correlates with a predicted cleft in two independent models of the 30S ribosomal subunit.
...
PMID:Escherichia coli initiation factor 3 protein binding to 30S ribosomal subunits alters the accessibility of nucleotides within the conserved central region of 16S rRNA. 251 87
The higher order structure of the functionally important 530 loop in Escherichia coli 16S rRNA was studied in mutants with single base changes at position 517, which significantly impair translational fidelity. The 530 loop has been proposed to interact with the EF-Tu-GTP-aatRNA ternary complex during decoding. The reactivity at G530, U531 and A532 to the chemical probes kethoxal,
CMCT
and DMS respectively was increased in the mutant 16S rRNA compared with the wild-type, suggesting a more open 530 loop structure in the mutant ribosomes. This was supported by oligonucleotide binding experiments in which probes complementary to positions 520-526 and 527-533, but not control probes, showed increased binding to the 517C mutant 70S ribosomes compared with the non-mutant control. Furthermore, enzymatic digestion of 70S ribosomes with RNase T1, specific for single-stranded RNA, substantially cleaved both wild-type and mutant rRNAs between G524 and C525, two of the nucleotides involved in the 530 loop pseudoknot. This site was also cleaved in the 517C mutant, but not wild-type rRNA, by
RNase
V1. Such a result is still consistent with a more open 530 loop structure in the mutant ribosomes, since
RNase
V1 can cut at appropriately stacked single-stranded regions of RNA. Together these data indicate that the 517C mutant rRNA has a rather extensively unfolded 530 loop structure. Less extensive structural changes were found in mutants 517A and 517U, which caused less misreading. A correlation between the structural changes in the 530 loop and impaired translational accuracy is proposed.
...
PMID:Structural changes in the 530 loop of Escherichia coli 16S rRNA in mutants with impaired translational fidelity. 756 70
We describe the construction and testing of a structural model at the nucleotide level for conformation CH of the central hairpin of genomic RNA from coliphage Q beta. The model was developed with the computer program MFOLD using both optimal and suboptimal predictions. Structural information obtained by electron microscopic analysis of Kleinschmidt spreadings of Q beta RNA was used to guide the modeling. The model was tested in solution with three enzymatic probes: RNase T1,
RNase T2
, and
RNase
V1, as well as four chemical probes: dimethylsulfate, diethylpyrocarbonate, kethoxal and 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluene sulfonate (
CMCT
). The structural analyses in solution are consistent with the predicted structural model. The model is also supported by comparative structural analysis with the related coliphage SP. The model provides a structural basis for published biochemical and genetic studies implicating large, long-range structural features in the co-regulation of viral coat and replicase expression. In addition, we show that the read-through region of the viral protein A1 forms a separate structural domain, and we suggest that it functions as a nucleation site that participates in the folding and refolding of the molecule during replication and translation. In addition to the central hairpin, we have analyzed the structure of the viral coat initiation region. Our studies show that the entire region consists of small local hairpins and that 26 nucleotides immediately surrounding the coat initiation codon are single-stranded.
...
PMID:A two-dimensional model at the nucleotide level for the central hairpin of coliphage Q beta RNA. 837 1
The expansion segments in eukaryotic ribosomal RNAs are additional RNA sequences not found in the RNA core common to both prokaryotes and eukaryotes. These regions show large species-dependent variations in sequence and size. This makes it difficult to create secondary structure models for the expansion segments exclusively based on phylogenetic sequence comparison. Here we have used a combination of experimental data and computational methods to generate secondary structure models for expansion segment 15 in 28S rRNA in mice, rats, and rabbits. The experimental data were collected using the structure sensitive reagents DMS,
CMCT
, kethoxal, micrococcal nuclease,
RNase
T(1),
RNase
CL3,
RNase
V(1), and lead(II) acetate. ES15 was folded with the computer program RNAStructure 3.5 using modification data and phylogenetic similarities between different ES15 sequences. This program uses energy minimization to find the most stable secondary structure of an RNA sequence. The presented secondary structure models include several common structural motifs, but they also have characteristics unique to each organism. Overall, the secondary structure models showed indications of an energetically stable but dynamic structure, easily accessible from the solution by the modification reagents, suggesting that the expansion segment is located on the ribosomal surface.
...
PMID:Proposed secondary structure of eukaryote specific expansion segment 15 in 28S rRNA from mice, rats, and rabbits. 1125 39
The 18S rRNA of the small eukaryotic ribosomal subunit contains several expansion segments. Electron microscopy data indicate that two of the largest expansion segments are juxtaposed in intact 40S subunits, and data from phylogenetic sequence comparisons indicate that these two expansion segments contain complementary sequences that could form a direct tertiary interaction on the ribosome. We have investigated the secondary structure of the two expansion segments in the region around the putative tertiary interaction. Ribosomes from yeast, wheat, and mouse-three organisms representing separate eukaryotic kingdoms-were isolated, and the structure of ES3 and part of the ES6 region were analyzed using the single-strand-specific chemical reagents
CMCT
and DMS and the double-strand-specific
ribonuclease
V1. The modification patterns were analyzed by primer extension and gel electrophoresis on an ABI 377 automated DNA sequencer. The investigated sequences were relatively exposed to chemical and enzymatic modification. This is in line with their indicated location on the surface at the solvent side of the subunit. The complementary ES3 and ES6 sequences were clearly inaccessible to single-strand modification, but available for cleavage by double-strand-specific
RNase
V1. The results are compatible with a direct helical interaction between bases in ES3 and ES6. Almost identical results were obtained with ribosomes from the three organisms investigated.
...
PMID:Secondary structure of two regions in expansion segments ES3 and ES6 with the potential of forming a tertiary interaction in eukaryotic 40S ribosomal subunits. 1497 Mar 86
Pseudouridine, the so-called fifth nucleoside due to its ubiquitous presence in ribonucleic acids (RNAs), remains among the most challenging modified nucleosides to characterize. As an isomer of the major nucleoside uridine, pseudouridine cannot be detected by standard reverse-transcriptase-based DNA sequencing or
RNase
mapping approaches. Thus, over the past 15 years, investigators have focused on the unique structural properties of pseudouridine to develop selective derivatization or fragmentation strategies for its determination. While the N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide p-tosylate (
CMCT
)-reverse transcriptase assay remains both a popular and powerful approach to screen for pseudouridine in larger RNAs, mass-spectrometry-based approaches are poised to play an increasingly important role in either confirming the findings of the
CMCT
-reverse transcriptase assay or in characterizing pseudouridine sequence placement and abundance in smaller RNAs. This review includes a brief discussion of pseudouridine including a summary of its biosynthesis and known importance within various RNAs. The review then focuses on chemical derivatization approaches that can be used to selectively modify pseudouridine to improve its detection, and the development of mass-spectrometry-based assays for the identification and sequencing of pseudouridine in various RNAs.
...
PMID:Mass spectrometry of the fifth nucleoside: a review of the identification of pseudouridine in nucleic acids. 1862 Sep 15
