Alterations of the phosphoinositide-3 kinase (PI3K)/Akt signaling pathway occur broadly in cancer via multiple mechanisms including mutational activation of the PIK3CA gene. The dysregulation of this pathway has been implicated in tumor cell growth and survival, thus PI3K is a promising therapeutic target with multiple inhibitors in clinical trials. Taselisib (GDC-0032), a novel, oral, selective inhibitor of p110alpha, sparing inhibition of p110beta, is more potent against cancer cells bearing mutations in the PIK3CA gene than those with wildtype PIK3CA. The mechanism leading to this enhanced mutant selectivity is revealed in these preclinical studies. Uniquely among PI3K inhibitors, taselisib has a gain of potency in PIK3CA mutant SW48 isogenic cells compared to wildtype SW48 parental cells. Pathway inhibition and increased apoptosis are associated with the enhanced activity observed in PIK3CA mutant cells. In PIK3CA mutant cell culture-derived and patient-derived xenograft (PDX) models taselisib induces tumor regressions. In comparison to other clinical-stage PI3K inhibitors, taselisib confers superior anti-tumor activity in PIK3CA mutant xenografts when treated at a Maximum Tolerated Dose (MTD) in vivo. We have discovered that taselisib has a dual mechanism of action, both blocking kinase signaling and inducing down-regulation of the mutant p110alpha protein level in a dose-dependent and time-dependent manner. Taselisib treatment leads to the specific degradation of mutant p110alpha without significant change in wildtype p110alpha protein in cultured cells and in mutant xenograft models including PDX. Other clinical PI3K inhibitors, including PI3Kalpha selective and pan-PI3K inhibitors are unable to induce degradation of mutant p110 alpha. The taselisib-induced degradation of mutant p110a protein is ubiquitin-mediated and proteasome-dependent. These unique mechanistic effects of taselisib are most pronounced when comparing signaling suppression and p110a protein levels at 24 hours vs. 1 hour of drug exposure in PIK3CA mutant cell lines. This discovery indicates that PI3K inhibitors which trigger degradation of mutant p110a protein can more effectively suppress the signaling pathway in response to feedback, and may result in greater activity and improved therapeutic index. Citation Format: Friedman LS, Edgar KA, Song K, Schmidt S, Kirkpatrick DS, Phu L, Nannini MA, Hong R, Cheng E, Crocker L, Young A, Sampath D. The PI3K inhibitor, taselisib, has enhanced potency in PIK3CA mutant models through a unique mechanism of action [abstract]. In: Proceedings of the 2016 San Antonio Breast Cancer Symposium; 2016 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2017;77(4 Suppl):Abstract nr S6-04.
Mutations in the phosphoinositide-3 kinase alpha isoform (PIK3CA) are frequent in breast cancer and activate the PI3K signaling pathway. We discovered GDC-0032, a selective, potent, orally bioavailable inhibitor of PI3Ka with a Ki = 0.2nM, and with reduced inhibitory activity against PI3Kβ. This selectivity profile, and excellent pharmacokinetic and pharmaceutical properties, allowed for greater efficacy in vivo at the maximum tolerated dose relative to a pan Class I PI3K inhibitor in PIK3CA mutant xenografts. Notably, GDC-0032 preferentially inhibited PIK3CA mutant cells relative to cells with wild-type PI3K. GDC-0032 potently inhibits signal transduction downstream of PI3K and induces apoptosis at low concentrations in breast cancer cell lines and xenograft models that harbor PIK3CA mutations. The mutant-bias of GDC-0032 is linked to unique properties of GDC-0032, including cellular potency against the mutant isoform and reduction of receptor tyrosine kinase (RTK) signaling. Endocrine therapies such as letrozole are commonly used treatment options for metastatic Hormone Receptor positive (HR+) breast cancer but many patients ultimately relapse. Due to the importance of PI3K in breast cancer, PI3K inhibitors such as GDC-0032 are attractive for combination with endocrine therapies. GDC-0032 was evaluated in breast cancer lines and models in combination with letrozole, and assayed for cellular viability, modulation of PI3K pathway, modulation of ER pathway markers, and apoptosis induction. The combination of GDC-0032 and letrozole decreased cellular viability and increased apoptosis relative to either single agent. We observed cross-talk between the PI3K and ER pathways that suggest a mechanism of action for the combination. In a secreted factor screen we found that multiple soluble factors render breast cancer cells non-responsive to letrozole. It was discovered that many of these factors signal through the PI3K pathway and GDC-0032 in combination with letrozole was able to overcome the growth inhibition caused by the soluble factor. We also established letrozole resistant cell lines that grow independently of any estrogen source. These letrozole resistant lines have elevated PI3K pathway signaling and are still sensitive to GDC-0032. Taken together, these data provide rationale for evaluating GDC-0032 in combination with endocrine therapies for ER+ breast cancer treatment in the clinic. Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr P2-17-01.
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