KRASG12V mutant cancers represent a significant unmet medical need with nearly 44,000 new diagnoses annually in the US. The KRASG12V mutation occurs frequently in multiple tumor histotypes; the incidence in NSCLC, CRC and pancreatic cancers is 6%, 10% and 26%, respectively. RAS proteins are small GTPases that drive cell proliferation and survival when bound to GTP. Mutant RAS proteins exist predominantly in the GTP-bound (RAS(ON)) state, leading to excessive downstream signaling via interaction with effectors such as RAF. The intrinsic GTP hydrolysis rate of KRASG12V is significantly lower than that of either KRASG12C or KRASG12D. Therefore, targeting the KRASG12V(ON) state will be critical for maximal suppression of this oncogenic driver. No targeted, direct inhibitors of KRASG12V(ON) have been described to date. We have built a pipeline of small molecule inhibitors targeting multiple oncogenic RAS(ON) mutants. Here we describe the preclinical profile of KRASG12V(ON) inhibitors that promote a tri-complex between the inhibitor, the immunophilin cyclophilin A (CypA), and the active GTP-bound state of KRASG12V. In cancer cell lines bearing KRASG12V mutations, KRASG12V(ON) inhibitors trigger an immediate disruption of RAS-effector interactions, leading to attenuation of RAS pathway signaling, potent (sub-nM EC50) growth suppression, and apoptosis. KRASG12V(ON) inhibitors produce deep, durable, and dose-dependent suppression of tumor RAS pathway activation in vivo following oral administration. An extended duration of tumor pharmacodynamic activity, relative to plasma exposure, is observed that likely reflects retention of the inhibitors in tumor tissue due to high affinity binding to CypA. In human tumor xenograft models of KRASG12V mutant NSCLC, CRC and pancreatic cancers, oral administration of KRASG12V(ON) inhibitors is well-tolerated and drives profound and durable tumor regressions, with complete responses in some animals. KRASG12V(ON) inhibitors also downregulate immune checkpoint proteins PD-L1 and CD73 on KRASG12V mutant cancer cells, changes which can support enhanced anti-tumor immunity. The ability to target the GTP-bound form of mutant KRASG12V permits a broad array of combination opportunities in cancer types where single agent KRASG12V(ON) inhibition may be insufficient, for example with agents targeting pathway nodes both upstream (e.g. SHP2, SOS1) and downstream (e.g. MEK, ERK) of RAS, as well as parallel pathways (e.g. mTORC1). Tri-complex inhibitors that target KRASG12V(ON) are predicted to combat escape mechanisms in RAS-addicted cancer cells characterized by an increased pool of activated KRASG12V(ON). These inhibitors may lead to an attractive, targeted therapeutic option for the treatment of RAS-addicted cancers with a very high unmet medical need. Citation Format: Elena Koltun, Jim Cregg, Meghan A. Rice, Dan M. Whalen, Rebecca Freilich, Jingjing Jiang, Richard Hansen, Alun Bermingham, John E. Knox, Jay Dinglasan, Kyle Seamon, Cristina Blaj, Stephanie S. Chang, Yang Liu, Jun Huang, Kang-Jye Chou, Laura McDowell, Bianca J. Lee, David Wildes, Zhengping Wang, Mallika Singh, Adrian L. Gill, Jacqueline A. Smith. First-in-class, orally bioavailable KRASG12V(ON) tri-complex inhibitors, as single agents and in combinations, drive profound anti-tumor activity in preclinical models of KRASG12V mutant cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1260.
The KRASG12C mutation is found in 11% of non-small cell lung cancers, 4% of colorectal cancers, and 2% of pancreatic cancers in the U.S., and drives these cancers by shifting the cellular equilibrium of KRAS towards the GTP-bound, active state, KRASG12C(ON). The resulting increased levels of KRASG12C(ON) in turn increase signaling output to initiate and support the oncogenic state. In recent years, a class of KRASG12C(OFF) inhibitors has transformed the treatment landscape for patients with cancers bearing KRASG12C. These inhibitors work via sequestration of the GDP-bound, inactive state, KRASG12C(OFF), starving cancer cells of their oncogenic driver, KRASG12C(ON). Recent reports on the nature of resistance to KRASG12C(OFF) inhibitors suggest this class of drugs can be overcome through reactivation of KRASG12C to the ON form. Direct inhibition of KRASG12C(ON) with a first in class, potent, orally bioavailable, selective, tri-complex inhibitor RMC-6291, represents a more robust approach and presents the possibility that RMC-6291 will be a ‘best-in-class’ inhibitor of tumors harboring KRASG12C. RMC-6291 is a potent covalent inhibitor of KRASG12C(ON) that forms a tri-complex within tumor cells between KRASG12C(ON) and cyclophilin A (CypA), a highly abundant immunophilin. The assembled tri-complex prevents KRASG12C(ON) from signaling via steric blockade of RAS effector binding. In cells, kinetic analyses demonstrate near-immediate disruption of RAS effector binding and extinction of KRASG12C(ON) signaling. Oral administration of RMC-6291 produces deep and durable suppression of RAS pathway activity in KRASG12C tumor models and drives profound tumor regressions in vivo at well-tolerated doses. In a mouse clinical trial consisting of multiple patient- and cell line-derived xenograft models of KRASG12C NSCLC, RMC-6291 outperformed adagrasib, a KRASG12C(OFF) inhibitor, by increasing the number of responses, the depth of tumor regressions, and the durability of responses. Combination treatment with RMC-6291 and SHP2 or SOS1 inhibitors was well tolerated in preclinical models and further increased anti-tumor activity, likely by preventing reactivation of wild-type RAS proteins that cooperate with KRASG12C to fuel cancer growth. RMC-6291 also combined well with immune checkpoint inhibitors, sensitizing KRASG12C-bearing cancer models to anti-tumor immunity. RMC-6291 is a next-generation, mutant-selective inhibitor of KRASG12C(ON) that overcomes limitations of first-generation KRASG12C(OFF) inhibitors in preclinical models by directly targeting the active form of this important oncogenic driver. Citation Format: Robert J. Nichols, Y.C. Yang, Jim Cregg, Chris J. Schulze, Zhican Wang, Richa Dua, Jingjing Jiang, Lindsay S. Garrenton, Nicole Nasholm, Alun Bermingham, John E. Knox, Kyle Seamon, Michael Longhi, Kang-Jye Chou, Shaoling Li, David P. Wildes, Mallika Singh, Elena S. Koltun, Adrian L. Gill, Jacqueline A.M. Smith. RMC-6291, a next-generation tri-complex KRASG12C(ON) inhibitor, outperforms KRASG12C(OFF) inhibitors in preclinical models of KRASG12C cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3595.
Mutant RAS is common in pancreatic carcinoma (PDAC), non-small cell lung cancer (NSCLC) and colorectal cancer (CRC) and exists predominantly in the GTP-bound (RAS(ON)) state, leading to excessive downstream oncogenic signaling. KRASG12C(OFF) inhibitors have provided clinical proof of concept for targeting mutant KRAS. Preclinical data suggests inhibition of RAS(ON) may be a superior therapeutic strategy. In addition, KRASG12 mutations such as KRASG12D and KRASG12V remain unserved.RMC-6236 is a first-in-class, potent, oral tri-complex RASMULTI(ON) small molecule inhibitor designed to treat cancers driven by a variety of RAS mutations. RMC-6236 non-covalently binds to an abundant intracellular chaperone protein, cyclophilin A (CypA), resulting in a binary complex that engages RAS(ON) to form a high-affinity, RAS-selective tri-complex that sterically inhibits RAS binding to effectors. Exposure to RMC-6236 suppressed ERK phosphorylation and cell growth, and induced apoptosis in multiple human RAS-addicted cancer cell lines in vitro.RMC-6236 induced dose-dependent, deep, and durable suppression of RAS pathway activation up to 48 hours in preclinical xenograft models in vivo. Prolonged exposure in tumors was observed relative to blood and various healthy tissues, likely mediated by high affinity binding of RMC-6236 to tumor CypA.RMC-6236 at tolerable doses induced profound and durable tumor regressions in multiple cell line-derived (CDX) and patient-derived (PDX) RASMUT xenograft models, including NSCLC, CRC and PDAC. Anti-tumor activity was particularly notable in KRAS position 12 (G12X) mutant tumors, particularly KRASG12D, KRASG12V, and KRASG12R, with significant tumor regressions observed. Tumor growth inhibition was durable even in tumors that did not regress. Intermittent scheduling of RMC-6236 was active and permitted a higher dose intensity than daily dosing.RMC-6236 promoted anti-tumor immunity in vivo and was additive with anti-PD1 antibodies, driving durable complete responses and immunologic memory in a KRAS mutant CRC model. Furthermore, RMC-6236 treatment reversed oncogenic RAS-driven immune evasion mechanisms in a checkpoint blockade refractory KRAS mutant model, significantly transforming the tumor microenvironment in favor of anti-tumor immunity.These preclinical results support the inclusion of NSCLC, PDAC, and CRC patients in our planned clinical trial of RMC-6236 in patients with KRASG12X advanced solid tumors. Citation Format: Elena S. Koltun, Meghan A. Rice, W. Clay Gustafson, David Wilds, Jingjing Jiang, Bianca J. Lee, Zhengping Wang, Stephanie Chang, Mike Flagella, Yunming Mu, Nuntana Dinglasan, Nicole Nasholm, James W. Evans, Yingyun Wang, Kyle Seamon, Yang Liu, Cristina Blaj, John Knox, Rebecca Freilich, Elsa Quintana, Jim Cregg, Alun Bermingham, Adrian L. Gill, Jacqueline Am Smith, Mallika Singh. Direct targeting of KRASG12X mutant cancers with RMC-6236, a first-in-class, RAS-selective, orally bioavailable, tri-complex RASMULTI(ON) inhibitor [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3597.
The KRASG12C mutation is found in 11% of non-small cell lung cancers and 4% of colorectal cancers. Recently, a class of KRASG12C(OFF) inhibitors has shown promising activity in patients whose cancers bear KRASG12C. These data validate KRASG12C as an oncogenic driver, as well the mechanism of action of the KRASG12C(OFF) inhibitor class – sequestration of inactive, GDP-bound KRASG12C(OFF) proteins. Previous work has demonstrated this mechanism of action is vulnerable to adaptive tumor cell responses that activate KRASG12C by increasing upstream signaling and driving the cellular pool of KRASG12C towards the RAS(ON) state. These escape mechanisms, in which KRASG12C can be reactivated in the presence of a KRASG12C(OFF) inhibitor, highlight the potential for an inhibitor that directly targets and disables the KRASG12C(ON) form. Using structure-based drug design, we have discovered RM-032, a potent covalent inhibitor of KRASG12C(ON) that forms a tri-complex between KRASG12C(ON) and cyclophilin A (CypA), a highly abundant immunophilin. The assembled tri-complex prevents KRASG12C(ON) from signaling via steric blockade of RAS effector binding. In cells, kinetic analyses demonstrate near-immediate disruption of RAS effector binding and extinction of KRASG12C(ON) signaling. RM-032 is dual selective for KRASG12C(ON) and NRASG12C(ON). In vitro, RM-032 drives increased durability of inhibition of both RAS pathway signaling and cell proliferation in KRASG12C tumor cells compared with KRASG12C(OFF) inhibition. RM-032 displays attractive drug-like properties including cross-species oral bioavailability, and is predicted to achieve adequate exposures following oral dosing in humans. Oral administration of RM-032 produces deep and durable suppression of RAS pathway activity in KRASG12C tumor models and drives profound tumor regressions in vivo at well-tolerated doses. Across multiple tumor xenograft models, advanced KRASG12C(ON) inhibitors, including RM-032, appear to outperform KRASG12C(OFF) inhibitors. RM-032 permits a broad array of combination opportunities for treating KRASG12C mutant cancer types where single agent KRASG12C(ON) inhibition may be insufficient, for example with agents targeting nodes both upstream (e.g., SHP2 and SOS1) and downstream (e.g., MEK and ERK) of RAS, as well as parallel pathways (e.g., mTORC1). RM-032 is a next generation mutant-selective inhibitor of KRASG12C(ON) that may overcome liabilities of first-generation KRASG12C(OFF) inhibitors and provide additional benefit to patients by directly targeting the active form of this important oncogenic driver mutation. Citation Format: Robert J. Nichols, Jim Cregg, Christopher J. Schulze, Zhican Wang, Kevin Yang, Jingjing Jiang, Daniel M. Whalen, Rich Hansen, Lindsay S. Garrenton, Alun Bermingham, John E. Knox, Tiffany Choy, Denise Reyes, Mayra Rios, Kyle Seamon, Michael Longhi, Kang-Jye Chou, Shaoling Li, David P. Wildes, Mallika Singh, Elena S. Koltun, Adrian L. Gill, Jacqueline A. M. Smith. A next generation tri-complex KRASG12C(ON) inhibitor directly targets the active, GTP-bound state of mutant RAS and may overcome resistance to KRASG12C(OFF) inhibition [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1261.
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