Intergenic Splicing between Four Adjacent Genes () Gives Rise to Variant UGT Proteins That Inhibit Glucuronidation via Protein-Protein Interactions.

Recent studies have investigated alternative splicing profiles of UDP-glucuronosyltransferase genes and identified over 130 different alternatively spliced UGT transcripts. Although genes are highly clustered, the formation of chimeric transcripts by intergenic splicing between two or more genes has not yet been reported. This study identified 12 chimeric transcripts (chimeras A-L) containing exons from two or three genes of the four neighboring genes (, , , and ) in human liver and prostate cancer cells. These chimeras typically contain the first five exons of or (exons 1-5) spliced to a terminal exon (exon 6) from a downstream gene. Hence they encode truncated UGTs with novel C-terminal peptides. Functional assays of representative chimeric UGT proteins (termed chimeric UGT2B15 and chimeric UGT2B17) showed that they are inactive and can repress the activity of wild-type UGTs. Coimmunoprecipitation assays demonstrated heterotypic interactions between chimeric UGT2B15 (or chimeric UGT2B17) and the UGT2B7 protein. Thus oligomerization of the chimeric UGTs with wild-type UGTs may explain their inhibitory activity. Studies in breast and prostate cancer cells showed that both wild-type and chimeric UGT2B15 and UGT2B17 transcripts are regulated in a similar way at the transcriptional level by sex hormones through their canonical promoters but are differentially regulated at the post-transcriptional level by micro-RNA 376c via their unique 3'-untranslated regions. In conclusion, the formation of chimeric transcripts by intergenic splicing among genes represents a novel mechanism contributing to the diversity of the human UGT transcriptome and proteome. The differential post-transcriptional regulation of wild-type and variant transcripts by micro-RNAs may contribute to their deregulated expression in cancer.