Stabilization and analysis of intron lariats in vivo.

The analysis of lariats produced in vivo during pre-mRNA splicing is a powerful tool for elucidation of regulatory mechanisms and identification of natural recursive splicing events. Nevertheless, this analysis is technically challenging because lariats normally have short half-lives. With appropriate controls, RT-PCR amplification and sequencing of the region spanning the 2'-5' phosophodiester bond at the branch junction can be a sensitive and versatile method for lariat analysis. This approach can be facilitated and enhanced by reducing the activity of debranching enzyme (DBR) in order to stabilize lariats. We have generated a set of plasmids for dsRNA-mediated knockdown of DBR under diverse conditions in transgenic Drosophila and in cultured cells. We describe the use of these plasmids and protocols for lariat analysis. We have generated transgenic Drosophila strains carrying a GAL4-regulated RNAi construct that allows selective knockdown of DBR in specific tissues or developmental stages, using the large collection of available GAL4 expression lines. These strains should prove useful for detailed developmental analyses of alternative and recursive splicing and for genetic analyses of splicing factors. Similar approaches should be readily adaptable to other organisms.</p

Subdivision of large introns in Drosophila by recursive splicing at nonexonic elements.

Many genes with important roles in development and disease contain exceptionally long introns, but special mechanisms for their expression have not been investigated. We present bioinformatic, phylogenetic, and experimental evidence in Drosophila for a mechanism that subdivides many large introns by recursive splicing at nonexonic elements and alternative exons. Recursive splice sites predicted with highly stringent criteria are found at much higher frequency than expected in the sense strands of introns >20 kb, but they are found only at the expected frequency on the antisense strands, and they are underrepresented within intronspseudoobscura, despite extensive divergence of other sequences within the same introns. These patterns of enrichment and conservation indicate that recursive splice sites are advantageous in the context of long introns. Experimental analyses of in vivo processing intermediates and lariat products from four large introns in the unrelated genes kuzbanian, outspread, and Ultrabithorax confirmed that these introns are removed by a series of recursive splicing steps using the predicted nonexonic sites. Mutation of nonexonic site RP3 within Ultrabithorax also confirmed that recursive splicing is the predominant processing pathway even with a shortened version of the intron. We discuss currently known and potential roles for recursive splicing.</p