Staurosporine Induces Caspase-Dependent Proteolysis of MEF2D-Fusion Protein and Cell Death Selective to MEF2D-Fusion-Positive ALL Cells

MEF2D fusion (M-fusion) genes are newly discovered recurrent gene abnormalities that are detected in approximately 5% of acute lymphoblastic leukemia (ALL) cases. We previously found that the loss of the micro RNA target site in wild-type MEF2D gene by translocation led to strong expression of M-fusion protein in ALL cells by evasion from micro RNA and that M-fusion protein inhibited the transcriptional activity of PAX5, a B-cell differentiation regulator, in a dose-dependent manner. These findings prompted us to explore drugs that induced proteolysis of M-fusion protein as possible therapeutic agents for M-fusion-positive ALL. We developed a high-throughput screening system to find compounds that reduced protein expression level of MEF2D. The expression vector of the fusion protein of N-terminal half of MEF2D (MEF2D N) and luciferase (MEF2D N-Luc) was stably transfected to 293T cells (MEF2D N-Luc/293T). Stable transfectant of the expression vector of luciferase was also established (Luc/293T). We could easily measure protein expression level in these cells by luciferase assay. We screened 3766 compounds with known pharmaceutical activities with this system and selected staurosporine, a multi-kinase inhibitor, as a possible proteolysis-inducer of MEF2D. Staurosporine strongly reduced the luciferase value in MEF2D N-Luc/293T but not in Luc/293T (Figure 1A). Staurosporine induced proteolysis of MEF2D-HNRNPUL1 (M-H) and MEF2D-DAZAP1 (M-D) in M-fusion-positive ALL cell lines within 6 h. Proteolysis of M-fusion proteins were inhibited not by MG-132, a proteasome inhibitor, but by Z-VAD FMK, a caspase inhibitor, indicating that these proteolyses were caspase-dependent (Figure 1B). Consistent with this, Z-VAD-FMK blocked apoptosis by staurosporine in M-H positive ALL cell lines . We confirmed the cleavage of M-H by caspase 3 and caspase 7 in vitro and identified the cleavage site (Figure 1C). Furthermore, staurosporine demonstrated stronger cytotoxic effect on M-fusion-positive ALL cell lines than M-fusion-negative ones (Figure 1D). These results indicated that staurosporine induced apoptosis of M-fusion-positive ALL cells through caspase-dependent proteolysis of M-fusion protein at least in part. Luciferase-based proteolysis screening provided a novel strategy for the development of anti-cancer drugs. Figure legends Figure 1. A. Staurosporine strongly reduced the luciferase value in MEF2D N-Luc/293T but not in Luc/293T. MEF2D N-Luc/293T were treated with 3766 co