Alternative splicing enhances proteome diversity and modulates cancer-associated proteins. To identify tissueand tumor-specific alternative splicing, we used the GeneChip Human Exon 1.0 ST Array to measure wholegenome exon expression in 102 normal and cancer tissue samples of different stages from colon, urinary bladder, and prostate. We identified 2069 candidate alternative splicing events between normal tissue samples from colon, bladder, and prostate and selected 15 splicing events for RT-PCR validation, 10 of which were successfully validated by RT-PCR and sequencing. Furthermore 23, 19, and 18 candidate tumor-specific splicing alterations in colon, bladder, and prostate, respectively, were selected for RT-PCR validation on an independent set of 81 normal and tumor tissue samples. In total, seven genes with tumor-specific splice variants were identified (ACTN1, CALD1, COL6A3, LRRFIP2, PIK4CB, TPM1, and VCL). The validated tumor-specific splicing alterations were highly consistent, enabling clear separation of normal and cancer samples and in some cases even of different tumor stages. A subset of the tumor-specific splicing alterations (ACTN1, CALD1, and VCL) was found in all three organs and may represent general cancer-related splicing events. In silico protein predictions suggest that the identified cancerspecific splice variants encode proteins with potentially altered functions, indicating that they may be involved in pathogenesis and hence represent novel therapeutic targets. In conclusion, we identified and validated alternative splicing between normal tissue samples from colon, bladder, and prostate in addition to cancerspecific splicing events in colon, bladder, and prostate Alternative splicing is a key component in expanding a relatively limited number of genes into very complex proteomes. It has been estimated that about three-quarters of all human genes undergo alternative splicing (1-3), which may affect function, localization, binding properties, and stability of the encoded proteins (4). The recent results from the ENCODE (Encyclopedia of DNA Elements) consortium (5) extend and confirm the ubiquity of alternative splicing (6). Several splice variants with antagonistic functions have been described, e.g. BCL-X has an antiapoptotic long isoform and a proapoptotic short isoform (7,8). Alternative splicing can also lead to degradation of the transcript, thereby abrogating protein expression; examples include certain Serine/Arginine-rich (SR) protein splicing factors for which the inclusion of a particular exon causes mRNA degradation by nonsense-mediated decay (9, 10).Single nucleotide polymorphisms and somatic splice site mutations leading to aberrant splicing patterns have been described for a number of tumor suppressor genes, including APC, TP53, and BRCA1 (11). Deregulation of trans-acting proteins, such as splicing factors and heterogeneous nuclear ribonucleoproteins, may cause a more general change in RNA splicing in cancer cells. The SFRS1 gene, encoding the splicing factor 2/alternate spli...
