The 12p13 ETV6 (TEL) gene is frequently targeted by chromosomal translocations in human malignancies, resulting in the formation of oncogenic ETV6 gene fusions. Many of the known partner genes encode protein tyrosine kinases (PTKs), generating fusion proteins that function as chimeric PTKs. ETV6-NTRK3 (EN), comprised of the ETV6 SAM domain fused to the NTRK3 PTK, is unique among ETV6 chimeric oncoproteins, as it is expressed in cancers of multiple lineages. We initially hypothesized that, similar to other ETV6-PTK chimeras, SAM-mediated dimerization of EN leads to constitutive activation of the PTK and downstream signaling cascades. However, when the EN SAM domain was replaced with an inducible FK506 binding protein (FKBP) dimerization system, resulting FKBP-NTRK3 chimeras failed to transform NIH 3T3 cells even though PTK activation was preserved. It was recently shown that the ETV6 SAM domain has two potential interacting surfaces, raising the possibility that this domain can mediate protein polymerization. We therefore mutated each EN SAM binding interface in a manner shown previously to abolish self-association of wild-type ETV6. Each mutation completely blocked the ability of EN to polymerize, to activate its PTK, and to transform NIH 3T3 cells. Furthermore, EN itself formed large polymeric structures within cells while mutant EN proteins were present only as monomers. Finally, we observed a dominant negative effect on the transformation of isolated SAM domains coexpressed in EN-transformed cells. Taken together, our results suggest that higher-order polymerization may be a critical requirement for the transformation activity of EN and possibly other ETV6-PTK fusion proteins.Many chromosomal translocations described in human malignancies lead to the expression of chimeric oncogenes resulting from the in-frame fusion of coding sequences from two different partner genes (30). Dimerization or oligomerization through the interaction of domains contributed by one of the partner genes has been shown to be an important activating mechanism for many chimeric oncoproteins. For BCR-ABL and other chimeric protein tyrosine kinases (PTKs), oligomerization leads to ligand-independent auto-or cross-phosphorylation of the kinase domain and constitutive PTK activation (2). Moreover, oligomerization appears to have additional roles in facilitating oncogenesis, such as by stabilizing the binding of other proteins to the oncoprotein complex. For example, evidence suggests that binding of the SMRT corepressor to the STAT5-RAR␣ fusion protein is facilitated by its oligomerization (23). In general, however, structural aspects and stoichiometric relationships within oligomeric complexes of these chimeric oncoproteins remain very poorly understood.The ETS family transcription factor ETV6 (or TEL), required for developmental processes such as hematopoiesis and yolk sac angiogenesis (50), consists of an N-terminal (SAM) domain and a C-terminal DNA-binding ETS domain (36). The ETV6 gene, found on chromosome 12p13, is disrupted by trans...
