Epigenetic dysregulation of leukaemic HOX code in MLL-rearranged leukaemia mouse model.

HOX genes are frequently dysregulated in human leukaemia with the gene rearrangement between mixed lineage leukaemia (MLL) and partner genes. The resultant MLL fusion proteins are known to mediate leukaemia through disruption of the normal epigenetic regulation at the target gene loci. To elucidate the pathogenic role of MLL fusion proteins in HOX dysregulation in leukaemia, we generated a novel haematopoietic lineage-specific Mll-Een knock-in mouse model using a Cre-mediated inversion strategy. The Mll(Een) (/+) invertor mice developed acute myeloid leukaemia, with organomegaly of the spleen, liver and mesenteric lymph nodes caused by infiltration of blast cells. Using Mll-Een-expressing leukaemic cell lines derived from bone marrow of Mll(Een) (/+) mutant mice, we showed that induction of Hox genes in leukaemic cells was associated with hypomethylated promoter regions and an aberrant active chromatin state at the Hox loci. Knock-down of Prmt1 was insufficient to reverse the active chromatin status and the hypomethylated Hox loci, suggesting that Prmt1-mediated histone arginine methylation was only partially involved in the maintenance of Hox expression in leukaemic cells. Furthermore, in vivo analysis of bone marrow cells of Mll(Een) (/+) mice revealed a Hox expression profile similar to that of wild-type haematopoietic stem cells. The leukaemic Hox profile was highly correlated with aberrant hypomethylation of Hox promoters in the mutant mice, which highlights the importance of DNA methylation in leukaemogenic mechanisms induced by MLL fusion proteins. Our results point to the involvement of dynamic epigenetic regulations in the maintenance of the stem cell-like HOX code that initiates leukaemic stem cells in MLL-rearranged leukaemia. This provides insights for the development of alternative strategies for leukaemia treatment.

Activation of Ras-dependent Elk-1 activity by MLL-AF4 family fusion oncoproteins.

OBJECTIVE: Mixed lineage leukemia (MLL) gene rearrangement is commonly observed in human leukemias. Many of the resultant MLL fusion proteins are found correlated with Ras signaling. Nevertheless, Ras mutations have only been reported in a small subset of MLL-rearranged leukemia. With the potential of developing new therapeutic regimens targeting Ras signaling pathway, we studied the role of MLL-AF4 family fusions and MLL-septin family fusions in the activation of Ras signaling in leukemogenesis. MATERIALS AND METHODS: Elk-1-driven luciferase reporter system was used to study the role of MLL-AF4, MLL-AF5q31, MLL-LAF4, MLL-CDCrel, MLL-MSF, and MLL-Septin 6 in the activation of Ras signaling. Dominant negative Ras S17N mutant and mitogen-activated protein kinase/extracellular signal-regulated kinase kinase (MEK) inhibitor U0126 were employed to demonstrate the involvement of Ras and MEK in this transactivation event. The activation of endogenous Ras/MEK signaling pathway by MLL fusion proteins in leukemia cell lines was also addressed by immunoblot analysis and small interfering RNA knockdown approach. RESULTS: We demonstrated that MLL-AF4, MLL-AF5q31, and MLL-LAF4 activated Elk-1 transcription factor, one of the major downstream effectors of Ras. This activation was abolished in the presence of dominant negative Ras or MEK inhibitor U0126, indicating the requirements of Ras and MEK. We further showed that endogenous MEK is phosphorylated in a MLL-AF4-expressing leukemia cell line, whereas depletion of MLL-AF4 by small interfering RNA reduced the phospho-MEK level. CONCLUSION: Our findings suggest that MLL-AF4 family fusion oncoproteins can activate Elk-1 through Ras/MEK/extracellular signal-regulated kinase (ERK) pathway and strongly support the role of Ras signaling in the pathogenesis of MLL-rearranged leukemia.