RUNX1 transformation of primary embryonic fibroblasts is revealed in the absence of p53.

The mammalian Runx gene family (Runx1-3) are transcription factors that play essential, lineage-specific roles in development. A growing body of evidence implicates these genes as mutational targets in cancer where, in different contexts, individual family members have been reported to act as tumour suppressors, dominant oncogenes or mediators of metastasis. We are exploring these paradoxical observations by ectopic expression of RUNX genes in primary murine embryonic fibroblasts where, in common with a number of other dominant oncogenes, RUNX1 induces senescence-like growth arrest in the presence of an intact p19(ARF)-p53 pathway. We now report that, in MEFs lacking functional p53, RUNX1 has apparently pro-oncogenic effects on cell growth that include cytoskeletal reorganization, reduced contact inhibition at confluence and accelerated tumour expansion in vivo. On the other hand, RUNX1 conferred no obvious growth advantage at low cell density and actually delayed entry of primary MEFs into S phase. We also found that ectopic RUNX1 interferes with the morphological and growth responses of p53-null MEFs to TGFbeta indicating that these effects are mediated by overlapping pathways. These observations help to elucidate the context-dependent consequences of loss and gain of Runx activity.

AML1/RUNX1 increases during G1 to S cell cycle progression independent of cytokine-dependent phosphorylation and induces cyclin D3 gene expression.

AML1/RUNX1, a member of the core binding factor (CBF) family stimulates myelopoiesis and lymphopoiesis by activating lineage-specific genes. In addition, AML1 induces S phase entry in 32Dcl3 myeloid or Ba/F3 lymphoid cells via transactivation. We now found that AML1 levels are regulated during the cell cycle. 32Dcl3 and Ba/F3 cell cycle fractions were prepared using elutriation. Western blotting and a gel shift/supershift assay demonstrated that endogenous CBF DNA binding and AML1 levels were increased 2-4-fold in S and G(2)/M phase cells compared with G(1) cells. In addition, G(1) arrest induced by mimosine reduced AML1 protein levels. In contrast, AML1 RNA did not vary during cell cycle progression relative to actin RNA. Analysis of exogenous Myc-AML1 or AML1-ER demonstrated a significant reduction in G(1) phase cells, whereas levels of exogenous DNA binding domain alone were constant, lending support to the conclusion that regulation of AML1 protein stability contributes to cell cycle variation in endogenous AML1. However, cytokine-dependent AML1 phosphorylation was independent of cell cycle phase, and an AML1 mutant lacking two ERK phosphorylation sites was still cell cycle-regulated. Inhibition of AML1 activity with the CBFbeta-SMMHC or AML1-ETO oncoproteins reduced cyclin D3 RNA expression, and AML1 bound and activated the cyclin D3 promoter. Signals stimulating G(1) to S cell cycle progression or entry into the cell cycle in immature hematopoietic cells might do so in part by inducing AML1 expression, and mutations altering pathways regulating variation in AML1 stability potentially contribute to leukemic transformation.