Abstract 3844: Anti-tumor efficacy of SMARCA degraders in pre-clinical models of cancer

SMARCA2/BRM and SMARCA4/BRG1 are the mutually exclusive DNA-dependent ATPases within the SWI/SNF complexes, which function in mobilizing nucleosomes to regulate transcription, DNA replication and repair, and higher-order chromosome dynamics. SMARCA4 is mutated in a number of cancers, which generally lack targetable oncogenes. Genetic silencing studies have established a requirement of SMARCA2 for survival of tumor cells lacking SMARCA4. SMARCA4-deficient patient population represents 10%-20% of NSCLC cases, ∼5% pancreatic cancer patients and ∼10% ovarian cancer patients where SMARCA2 is overexpressed. Interestingly, SMARCA4 is highly expressed without mutation in certain tumor types, where overexpression contributes to increased proliferation and survival. SMARCA4 knockdown in these tumors leads to inhibition of proliferation and also increase sensitivity to known chemotherapeutic agents, supporting the validity of targeting SMARCA4. Although genetic silencing of SMARCA2 leads to potent anti-proliferative activity in SMARCA4-deficient cancer cell lines, pharmacological studies with a probe capable of binding to SMARCA2 and SMARCA4 bromodomain have failed to show such an anti-proliferative phenotype. These findings triggered us to evaluate chemical degradation as an alternate approach to target SMARCA2/4 altered cancers. Optimization of bifunctional molecules with binding moieties for SMARCA2/4 and E3 ligase to induce proteasome-mediated degradation resulted in the identification of selective SMARCA2 and SMARCA4 degraders. These degraders showed selectivity against other bromodomain containing proteins such as BRD4, CBP and p300 in Western blot analysis. Functional analysis of a preferential SMARCA2 degrader in a panel of cell lines indicated a potent anti-proliferative activity in the context of SMARCA4 mutation. Additionally, these compounds displayed acceptable drug-like properties including solubility, metabolic stability and pharmacokinetics in mice. Dose-dependent tumor growth inhibition was observed in a SMARCA4-deficient lung cancer xenograft model and a syngeneic model of lymphoma at well-tolerated doses. Observed efficacy was correlated with the target degradation in the tumor supporting the potential to further develop them for cancer therapy. Based on the reported vulnerability of SMARCA4-deficient cell lines of diverse tumor origin to agents targeting PARP, PI3K/AKT and EZH2, combination effects with SMARC2 degrader are being interrogated.

Citation Format: Leena Khare Satyam, Sanjita Sasmal, Manoj K. Pothuganti, Sreevidya M.R., Ashokk Ettam, Sireesha Nunna, Marla Roshaiah, Shankaraiah Chithaluru, Rangarao Pallepati, Amitkumar A. Pawar, Leela P. Narukulla, Raghunadh A. Sripathi, Suraj Tgore, Rakesh P. Nankar, Charamanna KB, Nagesh Gowda S, Kiran Aithal, Samiulla DS, Subhendu Mukherjee, Shekar Chelur, Kavitha Nellore, Girish Daginakatte, Murali Ramachandra, Susanta Samajdar. Anti-tumor efficacy of SMARCA degraders in pre-clinical models of cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3844.

Abstract LB-258: Identification of SMARCA2/4 degraders for the treatment of SMARCA4-mutant and other cancers

The SWI/SNF complexes consist of one of two mutually exclusive DNA-dependent ATPases, BRG1/SMARCA4 or BRM/SMARCA2, together with core and accessory subunits that function in mobilizing nucleosomes to regulate transcription, DNA replication and repair, and higher-order chromosome dynamics. SMARCA2 (BRM) and SMARCA4 (BRG1), contain a bromodomain and an ATPase domain. The mammalian SWI/SNF complex functions as a tumor suppressor in many human malignancies. In addition to an essential role in pluripotency and development, genetic lesions of SWI/SNF complexes have been strongly linked to cancer development as components are mutated in many cancers. In some tumor types, mutations within the SWI/SNF complex lead to context specific vulnerabilities such as the requirement of SMARCA2 for survival of tumour cells lacking SMARCA4. This finding of SMARCA2/4 synthetic lethal relationship translates in vivo which emphasizes SMARCA2 as a promising therapeutic target for the treatment SMARCA4-mutant cancers. Moreover, the SMARCA4-deficient patient population generally lacks targetable oncogenes (such as mutant EGFR or ALK translocations), which further emphasizes the potential of developing SMARCA2 inhibitors. Previously, contrary to genetic silencing of SMARCA2 leading to potent anti-proliferative activity in SMARCA4-deficient cancer cell lines, pharmacological studies with a cell permeable probe capable of binding to SMARCA2 and SMARCA4 have failed to show such an anti-proliferative phenotype. These findings support that the ATPase domain, but not the bromodomain of SMARCA2, is the tractable therapeutic target for SMARCA4-deficient cancer. Significant hurdle in developing potent and selective ATPase inhibitors that must compete with intracellular concentrations of ATP (2-10 mM) triggered us to evaluate chemical degrader as an alternate approach. Herein we report the identification and characterization of potent SMARCA2/4 degraders. Design and SAR-based optimization of bifunctional molecules with binding moities for SMARCA2/4 and E3 ligase to induce proteosome-mediated degradation yielded compounds that potently degraded SMARCA2 alone or both SMARCA2 and SMARCA4. Selective binding to SMARCA2/4 was confirmed in biochemical assays followed by assessement of their cellular degradation potency in Western blot analysis. Selective degradation of SMARCA2/4 over other bromodomain containing protein such as BRD4 and CBP/p300 was also observed. Functional analysis of these compounds in a panel of cell lines indicated that the degradation of SMARCA2 or SMARCA2/4 resulted in potent anti-proliferative activity in selected cell lines that was not strictly dependent upon SMARCA4 status. Additionally, these compounds displayed reasonable drug-like properties including solubility, metabolic stability and pharmacokinetics in mice supporting their potential to fully evaluate the impact of SMARCA2/4 degradation and to develop them as a novel therapeutic approach.

Citation Format: Sanjita Sasmal, Leena K. Satyam, Manoj K. Pothuganti, Ashokk Ettam, Sireesha Nunna, Mohammed A. Shareef, Sreevalsam Gopinath, Subhendu Mukherjee, Murali Ramachandra, Susanta Samajdar. Identification of SMARCA2/4 degraders for the treatment of SMARCA4-mutant and other cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr LB-258.