Fibroblast growth factor receptors (FGFR) 2 and 3 have been established as drivers of numerous types of cancer with multiple drugs approved or entering late stage clinical trials. A limitation of current inhibitors is vulnerability to gatekeeper resistance mutations. Using a combination of targeted high-throughput screening and structure-based drug design, we have developed a series of aminopyrazole based FGFR inhibitors that covalently target a cysteine residue on the P-loop of the kinase. The inhibitors show excellent activity against the wild-type and gatekeeper mutant versions of the enzymes. Further optimization using SAR analysis and structure-based drug design led to analogues with improved potency and drug metabolism and pharmacokinetics properties.
Mcl-1, an anti-apoptotic Bcl-2 family member, is a known resistance factor to many cancer therapies, and a historically difficult target to drug. Recently however, we have made significant progress optimizing the potency and characterizing the mechanism of action of a novel class of selective Mcl-1 inhibitors. Here, we characterize the activity of one of our lead compounds and confirm on-target mechanistic activity in vitro and in vivo. Using an Mcl-1 binding assay we demonstrate very potent activity (IC50 < 3nM), while maintaining selectivity over other anti-apoptotic Bcl-2 family proteins, Bcl-2 (IC50 > 33 µM) and Bcl-xL (IC50 > 33 µM). In an Mcl-1 dependent multiple myeloma cell line, MOLP-8, we demonstrate rapid Mcl-1/Bak complex disruption with 10 nM inhibitor by 15 min followed by caspase 9-dependent apoptosis by 1 hr (EC50= 50 nM), consistent with an Mcl-1 dependent mechanism of action. Importantly, by depleting Bak from cells using siRNA, we also confirm that the observed apoptosis is through a Bak-dependent mechanism. Moreover, our Mcl-1 inhibitor exhibits broad submicromolar activity across a panel of multiple myeloma cell lines. In the absence of a validated selective Mcl-1 reference compound to benchmark in vivo activity, we engineered MOLP-8 cells to express the pro-apoptotic protein, Noxa, using a Tet-on expression system and grew these as subcutaneous tumors on the flanks of SCID mice. Within 24 hours of switching the mice to a diet containing doxycycline, we observe significant upregulation of Noxa, leading to an increase in cleaved caspase 3 (CC3) and cleaved PARP in tumor lysates, resulting in rapid tumor regression. In the same MOLP-8 xenograft model, we demonstrate that our Mcl-1 inhibitor induces rapid dissociation of Bak from Mcl-1 in tumors leading to accumulation of CC3 and cleaved PARP by 1 hr. Complete tumor regression was observed after a single 60 mg/kg or 100 mg/kg dose, while partial regression was observed after a single 30 mg/kg dose, and tumor growth inhibition was observed after a single 10 mg/kg dose. All doses were well tolerated with no significant body weight loss. Together, these data reinforce the potential utility of selective Mcl-1 inhibitors in hematological malignancies. Disclosures Belmonte: Astrazeneca: Employment, Equity Ownership. Adam:Astrazenenca: Employment, Equity Ownership. Borrelli:AstraZeneca: Employment, Equity Ownership. Bhavsar:AstraZeneca: Employment, Equity Ownership. Bebernitz:AstraZeneca: Employment, Equity Ownership. Hird:AstraZeneca: Employment, Equity Ownership. Secrist:AstraZeneca: Employment, Equity Ownership.
e13529 Background: RAS mutant melanoma and colorectal cancer represent areas of significant unmet medical need. MLN2480 is an investigational class II RAF kinase inhibitor and TAK-733 is an investigational allosteric MEK kinase inhibitor; each of which is the subject of a single agent phase I clinical trial. The present studies have characterized the combination activity of these agents in BRAF mutant and RAS mutant preclinical models of melanoma and colorectal cancer. Methods: Combination effects of MLN2480 and TAK-733 on cell viability were studied using an ATP-based cell viability assay across a panel of BRAF and RAS mutant melanoma and CRC cell lines. Western blot analysis was used to compare effects on MAPK pathway signaling and response markers in cell lines showing a range of sensitivity to this combination. Pharmacodynamic responses and growth inhibitory effects of the combination were studied in xenografts of the same cell lines, as well as in primary human tumor xenografts, of RAS mutant melanoma and CRC. Results: MLN2480 inhibits MAPK pathway signaling in BRAF mutant and some RAS mutant preclinical cancer models at concentrations that are tolerated in vivo. MLN2480 is most potent in BRAF mutant melanoma models but also has single agent activity in some RAS mutant models. The combination of MLN2480 with TAK-733 inhibits the growth of a broader range of RAS mutant tumor models than single agent MLN2480, including primary human tumor xenograft models of melanoma and CRC. In vitroanalysis of this drug combination in cell proliferation assays demonstrates synergistic activity. Western blot analysis demonstrated the effect of MLN2480 in reversing feedback activation of MEK in response to TAK-733, leading to more concerted MAPK pathway inhibition. Conclusions: The activity of the RAF kinase inhibitor MLN2480 in preclinical models of BRAF and RAS mutant melanoma and CRC provides a rationale for clinical testing. The combination of MLN2480 with the MEK inhibitor TAK-733 represents an additional strategy for clinical research within these tumor types.
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