A missense mutation in the APC tumor suppressor gene disrupts an ASF/SF2 splicing enhancer motif and causes pathogenic skipping of exon 14.

A missense mutation at codon 640 in the APC gene was identified in a familial adenomatous polyposis (FAP) patient, however, its pathological consequence remained unclear. Here we found that this missense mutation interferes at the nucleotide level with an exonic splicing regulatory element and leads to aberrant splicing of the mutant APC transcript rather than exerting its effect through the observed amino acid change. Analysis of the patient RNA revealed complete skipping of exon 14 in transcripts from the mutant APC allele, leading to a frameshift and a premature stop codon. When cloned into a splicing reporter minigene and transfected into colorectal cell lines, the exon 14 point mutation c.1918C>G (pR640G) was found sufficient to cause the observed exon skipping. Bioinformatic analysis predicted the mutation to change SRp55, hnRNP A1 or ASF/SF2 splicing factor binding sites. Using RNA interference methodology these predictions were experimentally validated and revealed that only ASF/SF2 was required for exon 14 inclusion. These research data identify APC mutation c.1918C>G (pR640G) as pathogenic and indicate a mechanism involving disruption of an ASF/SF2 exonic splicing enhancer element. The results allow genetic diagnosis of a hereditary tumour predisposition but also illustrate the need to complement in silico prediction by splicing reporter assays.

Combined molecular diagnosis of B-cell lymphomas with t(11;14)(q13;q32) or t(14;18)(q32;q21) using multiplex- and long distance inverse-polymerase chain reaction.

Translocations t(14;18)(q32;q21) and t(11;14)(q13;q32) are recurrent findings in follicular lymphoma (FL) and mantle cell lymphoma (MCL), respectively. However, the molecular counterparts of these translocations can only be detected in up to 75% of FL and 50% of MCL cases using routine techniques. To improve the efficiency of detection, we first devised a single-tube multiplex-polymerase chain reaction (PCR) assay with primers located within a conserved immunoglobulin heavy chain (IGH) sequence and 5' to the main breakpoint cluster regions of BCL2 and CCND1. Using this assay in 17 FL and 11 MCL diagnostic DNA samples, we readily identified a BCL2-IGH fusion in 65% of FL patients and a CCND1-IGH fusion in 55% of MCL patients. In the remaining cases, we used long distance inverse-PCR to detect BCL2-IGH and CCND1-IGH fusion genes with different BCL2 and CCND1 breakpoint locations. We found additional translocations in 3 patients (17%) with FL and in 4 patients (36%) with MCL. Taken together, we show that multiplex-PCR combined with long distance inverse-PCR detected a t(14;18) in 82% of FL patients and a t(11;14) in 91% of MCL patients, demonstrating that this 2-step protocol is an effective approach for molecular detection of t(11;14) and t(14;18) in B-cell lymphomas.