Complementation of U4 snRNA in S. cerevisiae Splicing Extracts for Biochemical Studies of snRNP Assembly and Function [chapter]

Martha R. Stark, Stephen D. Rader
2014 Msphere  
Pre-messenger RNA splicing is a surprisingly complex and dynamic process, the details of which remain largely unknown. One important method for studying splicing involves the replacement of endogenous splicing components with their synthetic counterparts. This enables changes in protein or nucleic acid sequence to be tested for functional effects, as well as the introduction of chemical moieties such as crosslinking groups and fl uorescent dyes. To introduce the modifi ed component, the
more » ... us one must be removed and a method found to reconstitute the active splicing machinery. In extracts prepared from S. cerevisiae , reconstitution has been accomplished with the small, nuclear RNAs U6, U2, and U5. We describe a comparable method to reconstitute active U4 small, nuclear RNA (snRNA) into a splicing extract. In order to remove the endogenous U4 it is necessary to target it for oligo-directed RNase H degradation while active splicing is under way, i.e., in the presence of a splicing transcript and ATP. This allows complete degradation of endogenous U4 and subsequent replacement with an exogenous version. In contrast to the procedures described for depletion of U6, U2, or U5 snRNAs, depletion of U4 requires concurrent active splicing. The ability to reconstitute U4 in yeast extract allows a variety of structural and functional studies to be carried out.
doi:10.1007/978-1-62703-980-2_15 pmid:24549666 fatcat:tajtqb24vbbg3ikq2ajlegcl2y