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Target Concepts:
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Query: EC:3.1.26.3 (
RNase III
)
1,015
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The translation of reverse transcriptase and other essential viral proteins from the HIV-1 Pol mRNA requires a programmed -1 ribosomal frameshift. This frameshift is induced by two highly conserved elements within the HIV-1 mRNA: a slippery sequence comprised of a UUUUUUA heptamer, and a downstream stem-loop structure. We have determined the structure of the HIV-1 frameshift inducing RNA stem-loop, using multidimensional heteronuclear nuclear magnetic resonance (NMR) methods. The 22 nucleotide RNA solution structure [root mean squared deviation (r.m.s.d.) = 1.2 A] was determined from 475 nuclear Overhauser effect (NOE)-derived distance restrains, 20 residual dipolar couplings and direct detection of
hydrogen
bonds via scalar couplings. We find that the frameshift inducing stem-loop is an A-form helix capped by a structured ACAA tetraloop. The ACAA tetraloop is stabilized by an equilateral 5' and 3' stacking pattern, a sheared A-A pair and a cross-strand
hydrogen
bond. Unexpectedly, the ACAA tetraloop structure is nearly identical to a known tetraloop fold, previously identified in the
RNase III
recognition site from Saccharomyces cerevisiae.
...
PMID:Solution structure of the HIV-1 frameshift inducing stem-loop RNA. 1288 91
Specific recognition of double-stranded RNA (dsRNA) by dsRNA-binding domains (dsRBDs) is involved in a large number of biological and regulatory processes. Although structures of dsRBDs in complex with dsRNA have revealed how they can bind to dsRNA in general, these do not explain how a dsRBD can recognize specific RNAs. Rnt1p, a member of the
RNase III
family of dsRNA endonucleases, is a key component of the Saccharomyces cerevisiae RNA-processing machinery. The Rnt1p dsRBD has been implicated in targeting this endonuclease to its RNA substrates, by recognizing hairpins closed by AGNN tetraloops. We report the solution structure of Rnt1p dsRBD complexed to the 5' terminal hairpin of one of its small nucleolar RNA substrates, the snR47 precursor. The conserved AGNN tetraloop fold is retained in the protein-RNA complex. The dsRBD contacts the RNA at successive minor, major, and tetraloop minor grooves on one face of the helix. Surprisingly, neither the universally conserved G nor the highly conserved A are recognized by specific
hydrogen
bonds to the bases. Rather, the N-terminal helix fits snugly into the minor groove of the RNA tetraloop and top of the stem, interacting in a non-sequence-specific manner with the sugar-phosphate backbone and the two nonconserved tetraloop bases. Mutational analysis of residues that contact the tetraloop region show that they are functionally important for RNA processing in the context of the entire protein in vivo. These results show how a single dsRBD can convey specificity for particular RNA targets, by structure specific recognition of a conserved tetraloop fold.
...
PMID:Structural basis for recognition of the AGNN tetraloop RNA fold by the double-stranded RNA-binding domain of Rnt1p RNase III. 1515 Apr 9
Members of the bacterial
RNase III
family recognize a variety of short structured RNAs with few common features. It is not clear how this group of enzymes supports high cleavage fidelity while maintaining a broad base of substrates. Here we show that the yeast orthologue of
RNase III
(Rnt1p) uses a network of 2'-OH-dependent interactions to recognize substrates with different structures. We designed a series of bipartite substrates permitting the distinction between binding and cleavage defects. Each substrate was engineered to carry a single or multiple 2'- O-methyl or 2'-fluoro ribonucleotide substitutions to prevent the formation of
hydrogen
bonds with a specific nucleotide or group of nucleotides. Interestingly, introduction of 2'- O-methyl ribonucleotides near the cleavage site increased the rate of catalysis, indicating that 2'-OH are not required for cleavage. Substitution of nucleotides in known Rnt1p binding site with 2'- O-methyl ribonucleotides inhibited cleavage while single 2'-fluoro ribonucleotide substitutions did not. This indicates that while no single 2'-OH is essential for Rnt1p cleavage, small changes in the substrate structure are not tolerated. Strikingly, several nucleotide substitutions greatly increased the substrate dissociation constant with little or no effect on the Michaelis-Menten constant or rate of catalysis. Together, the results indicate that Rnt1p uses a network of nucleotide interactions to identify its substrate and support two distinct modes of binding. One mode is primarily mediated by the dsRNA binding domain and leads to the formation of stable RNA/protein complex, while the other requires the presence of the nuclease and N-terminal domains and leads to RNA cleavage.
...
PMID:Yeast ribonuclease III uses a network of multiple hydrogen bonds for RNA binding and cleavage. 1864 67
RNA hairpins are the most commonly occurring secondary structural elements in RNAs and serve as nucleation sites for RNA folding, RNA-RNA, and RNA-protein interactions. RNA hairpins are frequently capped by tetraloops, and based on sequence similarity, three broad classes of RNA tetraloops have been defined: GNRA, UNCG, and CUYG. Other classes such as the UYUN tetraloop in histone mRNAs, the UGAA in 16S rRNA, the AUUA tetraloop from the MS2 bacteriophage, and the AGNN tetraloop that binds
RNase III
have also been characterized. The tetraloop structure is compact and is usually characterized by a paired interaction between the first and fourth nucleotides. The two unpaired nucleotides in the loop are usually involved in base-stacking or base-phosphate
hydrogen
bonding interactions. Several structures of RNA tetraloops, free and complexed to other RNAs or proteins, are now available and these studies have increased our understanding of the diverse mechanisms by which this motif is recognized. RNA tetraloops can mediate RNA-RNA contacts via the tetraloop-receptor motif, kissing hairpin loops, A-minor interactions, and pseudoknots. While these RNA-RNA interactions are fairly well understood, how RNA-binding proteins recognize RNA tetraloops and tetraloop-like motifs remains unclear. In this review, we summarize the structures of RNA tetraloop-protein complexes and the general themes that have emerged on sequence- and structure-specific recognition of RNA tetraloops. We highlight how proteins achieve molecular recognition of this nucleic acid motif, the structural adaptations observed in the tetraloop to accommodate the protein-binding partner, and the role of dynamics in recognition.
...
PMID:Recognition modes of RNA tetraloops and tetraloop-like motifs by RNA-binding proteins. 2412 96
