Distinct sites of phosphorothioate substitution interfere with folding and splicing of the Anabaena group I intron

doi:10.1093/nar/gkh548

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Published online 23 April 2004

Nucleic Acids Research, 2004, Vol. 32, No. 7 2272-2280
© 2004 Oxford University Press

Distinct sites of phosphorothioate substitution interfere with folding and splicing of the Anabaena group I intron

Andrej Lupták¹ and Jennifer A. Doudna^*^,2^,3

¹ Department of Chemistry, ² Department of Molecular Biophysics and Biochemistry and ³ Howard Hughes Medical Institute, Yale University, New Haven, CT 06520, USA

*To whom correspondence should be addressed at present address: Department of Molecular and Cell Biology, 305 Hildebrandt Hall, Mail Stop 3206, University of California, Berkeley, CA 94720-3206, USA. Tel: +1 510 643 0225; Fax: +1 510 643 0080; Email: doudna{at}uclink.berkeley.edu
Present address:
Andrej Lupták, Department of Molecular Biology, Massachusetts General Hospital, Boston, MA, USA

Received February 26, 2004; Revised and Accepted March 26, 2004

Although the active site of group I introns is phylogeneticallyconserved, subclasses of introns have evolved different mechanismsof stabilizing the catalytic core. Large introns contain weaklyconserved ‘peripheral’ domains that buttress thecore through predicted interhelical contacts, while smallerintrons use loop–helix interactions for stability. Inall cases, specific and non-specific magnesium ion binding accompaniesfolding into the active structure. Whether similar RNA–RNAand RNA–magnesium ion contacts play related functionalroles in different introns is not clear, particularly sinceit can be difficult to distinguish interactions directly involvedin catalysis from those important for RNA folding. Using phosphorothioateinterference with RNA activity and structure in the small (249nt) group I intron from Anabaena, we used two independent assaysto detect backbone phosphates important for catalysis and thoseinvolved in intron folding. Comparison of the interference sitesidentified in each assay shows that positions affecting catalysiscluster primarily in the conserved core of the intron, consistentwith conservation of functionally important phosphates, manyof which are magnesium ion binding sites, in diverse group Iintrons, including those from Azoarcus and Tetrahymena. However,unique sites of folding interference located outside the catalyticcore imply that different group I introns, even within the samesubclass, use distinct sets of tertiary interactions to stabilizethe structure of the catalytic core.

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