Divergent Functions of ERK Substrate Binding Domains in Pathogenesis of Myeloproliferative Neoplasms

PROJECT SUMMARY/ABSTRACT The Ras/MAPK pathway is activated in 85% of human cancer. Nevertheless, attempts to target Ras/MAPK signaling have produced only limited efficacy. We hypothesize that one reason for the failure to successfully target this pathway is that the targeting efforts have focused on the active sites of kinases in this cascade, which

has failed to provide long-lasting benefit. We hypothesize that the failure of this approach results from two causes: 1) Active site inhibitors, which resemble adenosine triphosphate (ATP), must overcome the exceedingly high cytosolic ATP levels in cancer cells; and 2) critical kinases in this cascade (e.g., ERK1/2) have distinct

substrate interactions domains that can perform antagonistic roles in regulating cancer progression. Consequently, active-site focused inhibition is akin to simultaneous depression of the accelerator and brake pedals of an automobile. We hypothesize that a more successful approach will be to develop inhibitors which

preserve kinase activity, but divert it exclusively to “brake pedal” substrates. In support, we have demonstrated that the two substrate binding domains of ERK2, termed the D and DPB domains, play opposing roles in the pathogenesis of JAK2-kinase driven myeloproliferative neoplasms (MPN). Indeed, the DBP and D domains act

like brake and accelerator pedals, opposing and promoting disease progression, respectively. Consequently, pharmacologic attenuation of the accelerator pedal (D-domain) or its substrates should impair tumor progression more potently than active site inhibition, because it selectively interferes with the disease promoting activity of

ERK2, while preserving the tumor suppressive function of the DBP-domain. While we have compelling evidence for the opposing roles of the ERK2-D and DBP domains, the molecular basis for their action remains unclear and this is an impediment to developing effective, pharmacologic interventions focused on the ERK2 D domain.

We now seek to address this gap in knowledge according to the following aims. We will: 1) Assess the generality of the opposing functions of the ERK2-D and DBP domains in the pathogenesis of distinct MPN subtypes; 2) Understand the mechanistic basis by which the ERK2-D and DBP domains exert their distinct functions; and 3)

Assess the efficacy of pharmacologic targeting of the ERK2-D domain and/or its targets in inhibiting cancer progression. Through these efforts we expect to bring new insights into the role of ERK2 substrate binding modules in regulating cancer progression and how to exploit this information therapeutically. While we begin with

MPN, these findings may have far reaching implications for other Ras/MAPK driven cancers.