GAS5, a non-protein-coding RNA, controls apoptosis and is downregulated in breast cancer.

Effective control of both cell survival and cell proliferation is critical to the prevention of oncogenesis and to successful cancer therapy. Using functional expression cloning, we have identified GAS5 (growth arrest-specific transcript 5) as critical to the control of mammalian apoptosis and cell population growth. GAS5 transcripts are subject to complex post-transcriptional processing and some, but not all, GAS5 transcripts sensitize mammalian cells to apoptosis inducers. We have found that, in some cell lines, GAS5 expression induces growth arrest and apoptosis independently of other stimuli. GAS5 transcript levels were significantly reduced in breast cancer samples relative to adjacent unaffected normal breast epithelial tissues. The GAS5 gene has no significant protein-coding potential but expression encodes small nucleolar RNAs (snoRNAs) in its introns. Taken together with the recent demonstration of tumor suppressor characteristics in the related snoRNA U50, our observations suggest that such snoRNAs form a novel family of genes controlling oncogenesis and sensitivity to therapy in cancer.

Commitment to apoptosis induced by tumour necrosis factor-alpha is dependent on caspase activity.

Tumour Necrosis Factor alpha binding at the cell surface induces a complex series of signaling events culminating in the caspase cascade, which is central to apoptosis. However, recent work from several laboratories has questioned caspase involvement in commitment to cell death. We have therefore investigated the involvement of caspases in the crucial commitment stage of tumour necrosis factor-induced apoptosis in human T-leukaemic CEM-C7 cells and breast carcinoma MCF-7 cells, using both peptide-based and viral caspase inhibitors. Our observations converge on the conclusion that commitment to death in these systems is dependent on caspase activity, e.g. baculovirus p35 produces over 50-fold protection of colony-forming ability, the most stringent criterion of cell survival. These observations strongly support the view that the caspase family is of great biological and medical significance, since caspase dysfunction resulting in failure to commit to cell death after treatment with tumour necrosis factor or other stimuli may contribute to cancer development.

Molecular failure of apoptosis: inappropriate cell survival and mutagenesis?

Since cell death by apoptosis is achieved through complex interactions between numerous molecular components, cells may fail to die when stimulated because of molecular abnormalities in the apoptosis pathway or in its control mechanisms. Such inappropriate cell survival is well established when apoptosis is suppressed by elevated expression of bcl-2, at least for some cell types. Many cells undergo apoptosis at moderate levels of DNA damage and suppression of such apoptosis might be expected to increase the rate of mutation because of the persistence of cells with damaged DNA. We and others have now confirmed this prediction in bcl-2 transfected cells. Suppression of the apoptosis pathway can only lead to inappropriate cell survival if it relates to events before the cell becomes committed to die. We have analyzed this question for agents that inhibit the caspases, the site-specific proteases which form the biochemical core of the process of apoptosis. We have shown that inhibition of certain caspases does lead to the survival of Jurkat human T-cells induced to undergo Fas-mediated apoptosis.