Frontiers of Chemical Science and Engineering >
Transformer2 proteins protect breast cancer cells from accumulating replication stress by ensuring productive splicing of checkpoint kinase 1
Received date: 25 Jun 2015
Accepted date: 27 Sep 2015
Published date: 19 May 2016
Copyright
Increased expression levels of the RNA splicing regulator Transformer2β (abbreviated Tra2β) have been reported in several types of cancer. Recent work has revealed an intimate cross-regulation between Tra2β and the highly similar Tra2α protein in human breast cancer cells, though these two proteins are encoded by separate genes created by a gene duplication that occurred over 500 million years ago. This cross-regulation involves splicing control of a special class of exons, called poison exons. Down-regulation of Tra2β reduces splicing inclusion of a poison exon in the mRNA encoding Tra2α, thereby up-regulating Tra2α protein expression. This buffers any splicing changes that might be caused by individual depletion of Tra2β alone. Discovery of this cross-regulation pathway, and its by-pass by joint depletion of both human Tra2 proteins, revealed Tra2 proteins are essential for breast cancer cell viability, and led to the identification of important targets for splicing control. These exons include a critical exon within the checkpoint kinase 1 (CHK1) gene that plays a crucial function in the protection of cancer cells from replication stress. Breast cancer cells depleted for Tra2 proteins have reduced CHK1 protein levels and accumulate DNA damage. These data suggest Tra2 proteins and/or their splicing targets as possible cancer drug targets.
Key words: RNA splicing; gene expression; breast cancer; DNA damage; CHK1
Andrew Best , Katherine James , Gerald Hysenaj , Alison Tyson-Capper , David J. Elliott . Transformer2 proteins protect breast cancer cells from accumulating replication stress by ensuring productive splicing of checkpoint kinase 1[J]. Frontiers of Chemical Science and Engineering, 2016 , 10(2) : 186 -195 . DOI: 10.1007/s11705-015-1540-4
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