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Phylogenetic and genetic evidence for base-triples in the catalytic domain of group I introns

Nature volume 347pages 578–580 (1990)Cite this article

Abstract

UNDERSTANDING the mechanisms by which ribozymes catalyse chemical reactions requires a detailed knowledge of their structure. The secondary structure of the group I introns has been confirmed by comparison of over 70 published sequences1–4, by chemical protection studies5, and by genetic experiments involving compensatory mutations2,6,7. Phylogenetic data can also be used to identify tertiary interactions in RNA molecules. This was first done by Levitt8, who predicted tertiary interactions in transfer RNA, which were subsequently confirmed by X-ray crystallography9. More recently, sequence comparison data have been used to predict tertiary interactions in ribosomal RNA10. We have searched a complete alignment of the core regions of group I introns1,2 for evolutionary covariations that could not be ascribed to classical Watson–Crick or wobble base pairings. Here we describe two examples of phylogenetic covariation that are most simply explained by postulating hydrogen-bonded base-triples similar to those found in tRNA. Genetic experiments with the Tetrahymena and sunY introns confirm the importance of these interactions for the structure of the ribozyme.

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Authors and Affiliations

  1. Department of Molecular Biology, Massachusetts General Hospital, Boston, Massachusetts, 02114, USA

    François Michel, Andrew D. Ellington, Sandra Couture & Jack W. Szostak

  2. Centre de Génétique Moléculaire du CNRS, 91190, Gif-sur-Yvette, France

    François Michel

Authors
  1. François Michel
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  2. Andrew D. Ellington
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  3. Sandra Couture
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  4. Jack W. Szostak
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Michel, F., Ellington, A., Couture, S. et al. Phylogenetic and genetic evidence for base-triples in the catalytic domain of group I introns. Nature 347, 578–580 (1990). https://doi.org/10.1038/347578a0

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