The chemical basis of adenosine conservation throughout the Tetrahymena ribozyme

Ortoleva-Donnelly, Lori; Szewczak, Alexander A.; Gutell, Robin R.; Strobel, Scott A.

doi:10.1017/s1355838298980086

Cited by 108 publications

(106 citation statements)

References 77 publications

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“…The unreactive fractions of all mutant ribozymes were equally small (Ͻ15%), eliminating misfolding as a potential cause for the difference in reaction rates. To further confirm that k cat is This set of mutations restores the predicted base triple with an isomorphous triple that is the next most phylogenetically conserved sequence in the IC1 and IC2 intron subgroups (11). In every case that U300 is changed to a C within these subgroups, the A97-U277 base pair co-varies as a G-C pair.…”

Section: Resultsmentioning

confidence: 98%

“…Wild-type and mutant L-21 G414 and L-21 ScaI ribozyme RNAs were synthesized by T7 RNA polymerase transcription of EarI-and ScaI-digested plasmid DNA, respectively, and were purified on denaturing polyacrylamide gels (11). For NAIM and NAIS experiments, A␣S, 7dA␣S, m 6 A␣S, G␣S, 7dG␣S, C␣S, and dC␣S were randomly incorporated at low levels (Յ5%) into wild-type and mutant ribozymes as described (11).…”

Section: Methodsmentioning

confidence: 99%

“…Recently, the results of NAIM and NAIS experiments to identify the array of hydrogen bonding interactions that stabilize the interaction between the P1 substrate helix and the highly conserved J8͞7 strand within the intron core were reported (7,11). These data, along with other biochemical structural information (4-6, 12, 13), were used as restraints in building a model of a large section of the ribozyme active site.…”

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confidence: 99%

“…At the 5Ј end of J8͞7, phylogenetic evidence suggests that U300 may form a triple with the A97-U277 base pair in the P3 helix (Figs. 1 and 2) (11,16), although this has not been tested biochemically.…”

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confidence: 99%

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An important base triple anchors the substrate helix recognition surface within the Tetrahymena ribozyme active site

Szewczak

Ortoleva-Donnelly

Zivarts

et al. 1999

Proc. Natl. Acad. Sci. U.S.A.

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Key to understanding the structural biology of catalytic RNA is determining the underlying networks of interactions that stabilize RNA folding, substrate binding, and catalysis. Here we demonstrate the existence and functional importance of a Hoogsteen base triple (U300⅐A97-U277), which anchors the substrate helix recognition surface within the Tetrahymena group I ribozyme active site. Nucleotide analog interference suppression analysis of the interacting functional groups shows that the U300⅐A97-U277 triple forms part of a network of hydrogen bonds that connect the P3 helix, the J8͞7 strand, and the P1 substrate helix. Product binding and substrate cleavage kinetics experiments performed on mutant ribozymes that lack this base triple (C A-U, U G-C) or replace it with the isomorphous C ؉ ⅐G-C triple show that the A97 Hoogsteen triple contributes to the stabilization of both substrate helix docking and the conformation of the ribozyme's active site. To accomplish substrate helix docking and catalysis (1, 2), the Tetrahymena ribozyme ( Fig. 1) must fold into a complex tertiary structure with a close-packed catalytic core (3) in which several structural elements come together to jointly recognize and interact with the P1 substrate helix. These elements include the J4͞5 internal loop (4, 5), the J8͞7 strand (6, 7), and the attacking guanosine nucleophile bound within the P7 helix (8). This complex interaction of multiple closepacked helical and single-stranded RNA elements (9) requires several layers of interactions to create the active site of the molecule. The molecular details of these interactions and the underlying principles of RNA tertiary structure stabilization and substrate recognition within the Tetrahymena ribozyme can be readily investigated from a functional perspective by using the techniques of nucleotide analog interference mapping (NAIM) and nucleotide analog interference suppression (NAIS) (7, 10).Recently, the results of NAIM and NAIS experiments to identify the array of hydrogen bonding interactions that stabilize the interaction between the P1 substrate helix and the highly conserved J8͞7 strand within the intron core were reported (7, 11). These data, along with other biochemical structural information (4-6, 12, 13), were used as restraints in building a model of a large section of the ribozyme active site.In conjunction with a G⅐U wobble receptor in the J4͞5 region (4, 5), the J8͞7 strand creates a complementary surface for recognition of the P1 substrate helix (6, 7). The data indicate that the J8͞7 strand forms an extended minor groove triple helical interaction with four 2Ј-OH groups within the 5Ј-exon (P1) helix of the intron. This docking interface includes a tertiary interaction between the 2Ј-oxygen of U300 at the 5Ј-end of J8͞7 and the 2Ј-OH of G26 within the P1 helix. However, the details of the interactions between J8͞7 and the rest of the intron's core remain largely unknown.The single-stranded J8͞7 segment is a particularly critical element of the group I active site. Its ...

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Section: Resultsmentioning

confidence: 98%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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An important base triple anchors the substrate helix recognition surface within the Tetrahymena ribozyme active site

Szewczak

Ortoleva-Donnelly

Zivarts

et al. 1999

Proc. Natl. Acad. Sci. U.S.A.

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“…By offering a biochemical signature of C29-endo sugar puckers, nucleotide analog interference mapping using 29-fluoro and 29-deoxy derivatives could provide that distinction (Ortoleva-Donnelly et al 1998).…”

Section: Shape Mapping In Solution and In Crystalmentioning

confidence: 99%

Local RNA structural changes induced by crystallization are revealed by SHAPE

Vicens¹,

Gooding²,

Laederach³

et al. 2007

RNA

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We present a simple approach to locate sites that undergo conformational changes upon crystallization by comparative structural mapping of the same RNA in three different environments. As a proof of principle, we probed the readily crystallized P4-P6DC209 domain from the Tetrahymena thermophila group I intron in a native solution, in a solution mimicking the crystallization drop, and in crystals. We chose the selective 29-hydroxyl acylation analyzed by primer extension (SHAPE) chemistry, which monitors the flexibility and the conformation of each nucleotide. First, SHAPE successfully revealed the structural changes that occur during the crystallization process. Specifically, 64% of the nucleotides implicated in packing contacts and present in the portion of the molecule analyzed were identified. Second, reactivity differences for some of these nucleotides were already observed in the crystallization solution, suggesting that the crystallization buffer locked down a particular structure that was favorable to crystal formation. Third, the probing of a known structure extends our understanding of the structural basis for the SHAPE reaction by suggesting that reactivity is enhanced by a C29-endo sugar pucker. Furthermore, by identifying local conformational changes of the RNA that take place during crystallization, SHAPE could be combined with the in vitro selection of stable mutants to rationalize the design of RNA candidates for crystallization.

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Ribozyme chemogenetics

Strobel

1998

Biopolymers

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The chemical basis of adenosine conservation throughout the Tetrahymena ribozyme

Cited by 108 publications

References 77 publications

An important base triple anchors the substrate helix recognition surface within the Tetrahymena ribozyme active site

An important base triple anchors the substrate helix recognition surface within the Tetrahymena ribozyme active site

Local RNA structural changes induced by crystallization are revealed by SHAPE

Ribozyme chemogenetics

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