Gregory M. Landes

Increased exon-trapping efficiency through modifications to the pSPL3 splicing vector.

Exon trapping allows for the rapid identification and cloning of coding regions from cloned eukaryotic DNA. In preliminary experiments, we observed two phenomena which limited the exon-trapping efficiency of pSPL3-based systems. The first factor that affected performance was revealed when we found that up to 50% of the putative trapped exons contained sequences derived from the intron of the pSPL3 trapping vector. Removal of the DNA sequences responsible for the cryptic splice event from the original splicing vector resulted in a new vector, pSPL3B. We demonstrate that pSPL3B virtually eliminates pSPL3-only spliced products while maximizing the proportion of exon traps containing genomic DNA (> 98%). The other step which impacted performance was our observation that a majority of the ampicillin-resistant (APR) clones produced after shotgun subcloning from ApR cosmids into pSPL3 were untrappable, pSPL3-deficient, recircularized cosmid vector fragments. Replacement of the pSPL3 ApR gene with the CmR cassette encoding chloramphenicol (Cm) acetyltransferase enabled selection for only pSPL3-containing CmR clones. We show a 30-40-fold increase in the initial subcloning efficiency of cosmid-derived fragments with pSPL3-CAM, when compared to pSPL3. The collective vector alterations described improve the overall exon-trapping efficiency of the pSPL3-based trapping system.

Molecular analysis of human Chromosome 16 cosmid clones containing NotI sites

To test the feasibility of using cloned NotI sites as markers for physical mapping, we have screened for cosmid clones spanning the NotI sites on human Chromosome (Chr) 16. Fluorescence in situ hybridization analysis of these clones confirms the previously reported cluster of NotI sites on 16p13.3. Methylation status of the cloned NotI sites on genomic DNA was established by hybridization of the cosmids to Southern blots containing EcoRI and EcoRI/NotI digest of genomic DNA. These results indicated that four of six clones included in our study can be used as linking clones for physical mapping. Two clones have NotI sites which are not cleavable in the cell lines tested. In one clone, the NotI site exists as an isolated rare-cutting restriction enzyme site, whereas in the other clone the NotI site appears to be island-related.