Project description:We report the development of a second-generation AKT degrader INY-05-040, which outperformed catalytic AKT inhibition both with respect to biochemical and cellular suppression of AKT/mTORC1-driven phenotypes in diverse breast cancer cell lines. Using multi-omic profiling and causal network integration, we demonstrate that the enhanced efficacy of INY-05-040 relies in part on potent downstream activation of stress mitogen activated protein kinase (MAPK) signaling. Systematic measurements of growth inhibition across 288 cancer cell lines confirmed the substantial improvement in potency for INY-05-040 compared to the first-generation AKT degrader (INY-03-041) and catalytic AKT inhibition with GDC-0068. Subsequent integration of breast cancer cell line-specific data with publicly available transcriptomic, proteomic and reverse phase protein array (RPPA) measurements revealed that decreased sensitivity to INY-05-040 correlates with a high baseline activation of inflammatory/stress signaling pathways. Collectively, our data uncover a unique mechanism of breast cancer cell line sensitivity to AKT degradation, further suggesting that the efficacy of catalytic AKT inhibition may be enhanced by activation of stress MAPKs in breast cancer cells with low baseline activity of these components.

Project description:Over 50% of human tumors display hyperactivation of the serine/threonine kinase AKT, but AKT inhibitors under clinical investigation lack therapeutic efficacy at tolerable doses and display significant on-target toxicities. Here we report the development of a second-generation AKT degrader, INY-05-040, which outperformed catalytic AKT inhibition both with respect to biochemical and cellular suppression of AKT-driven phenotypes in breast cancer cell lines. A systematic growth inhibition screen across 288 cancer cell lines confirmed a substantially higher potency for INY-05-040 (median GI50adj = 1.1 µM) compared to our first-generation AKT degrader (INY-03-041; median GI50adj = 3.1 µM), with both compounds outperforming catalytic AKT inhibition with GDC-0068 (median GI50adj > 10 µM). Using multi-omic profiling and causal network integration in breast cancer cells, we demonstrate that the enhanced efficacy of INY-05-040 is associated with sustained suppression of AKT signaling, followed by a potent induction of the stress mitogen activated protein kinase (MAPK) cJun N-terminal kinase (JNK). Further integration of growth inhibition assays with publicly available transcriptomic, proteomic, and reverse phase protein array (RPPA) measurements established low baseline JNK signaling as a biomarker for breast cancer sensitivity to AKT degradation. Collectively, our study presents a systematic framework for mapping the network-wide signaling effects of therapeutically relevant compounds, revealing that INY-05-040 is a potent pharmacological suppressor of AKT signaling.

Project description:Transcriptomic comparison of a second-generation AKT degrader to the catalytic AKT inhibitor GDC0068 in breast cancer cells

Project description:Transcriptomic comparison of a second-generation AKT degrader to the catalytic AKT inhibitor GDC0068 in breast cancer cells [PRO-seq]

Project description:Transcriptomic comparison of a second-generation AKT degrader to the catalytic AKT inhibitor GDC0068 in breast cancer cells [RNA-seq]

Project description:Triple-negative breast cancer (TNBC) is responsible for a disproportionate number of breast cancer deaths due to its molecular heterogeneity, high recurrence rate and lack of targeted therapies. Dysregulation of the phosphoinositide 3-kinase (PI3K)/AKT pathway occurs in approximately 50% of TNBC patients. We performed a genome-wide negative selection CRISPR/Cas9 screen with PI3K and AKT inhibitors to identify targetable synthetic lethalities in TNBC. We found that cholesterol homeostasis is a collateral vulnerability with AKT inhibition. Disruption of cholesterol homeostasis with pitavastatin synergized with AKT inhibition to induce TNBC cytotoxicity in vitro, in mouse TNBC xenografts and in patient-derived organoids of estrogen receptor (ER)-negative breast cancer. Neither ER-positive breast cancer cell lines nor ER-positive organoids were sensitive to combined AKT inhibitor and pitavastatin. Mechanistically, TNBCs show dysregulated SREBP-2 activation in response to single agent or combination AKT inhibitor and pitavastatin, and this was rescued by inhibition of the cholesterol trafficking protein Niemann-Pick C1 (NPC1). NPC1 loss promoted lysosomal cholesterol accumulation, decreased endoplasmic reticulum cholesterol levels and promoted SREBP-2 activation. Taken together, these data identify a TNBC-specific vulnerability to the combination of AKT inhibitors and pitavastatin mediated by dysregulated cholesterol trafficking. This work motivates combining AKT inhibitors with pitavastatin as a therapeutic modality in TNBC. 

Project description:The PI3K/AKT signaling cascade is one of the most commonly dysregulated pathways in cancer, with over 50% of tumors showing aberrant AKT hyperactivation. Although potent small molecule AKT inhibitors have entered clinical trials, robust and durable therapeutic responses have not been observed. As an alternative strategy to target AKT, we report the development of INY-03-041, a pan-AKT degrader consisting of GDC-0068, an AKT inhibitor, conjugated to lenalidomide, a recruiter of the E3 ubiquitin ligase, Cereblon (CRBN). INY-03-041 induced potent degradation of all three AKT isoforms and displayed enhanced anti-proliferative effects relative to GDC-0068. Notably, INY-03-041 promoted sustained AKT degradation and inhibition of downstream signaling effects for up to 96 hours, even after compound washout. Overall, our findings suggest that AKT degradation may provide prolonged pharmacological effects compared to inhibition, and highlight the potential advantages of AKT-targeted degradation.

Project description:Human tumors often contain slowly proliferating cancer cells that resist treatment but we do not know precisely how these cells arise. We show that rapidly proliferating cancer cells can divide asymmetrically to produce slowly proliferating “G0-like” progeny that are enriched following chemotherapy in breast cancer patients. Asymmetric cancer cell division results from asymmetric suppression of AKT/PKB kinase signaling in one daughter cell during telophase of mitosis. Moreover, inhibition of AKT signaling with small molecule drugs can induce asymmetric cancer cell division and the production of slow proliferators. Cancer cells therefore appear to continuously flux between symmetric and asymmetric division depending on the precise state of their AKT signaling network. This model may have significant implications for understanding how tumors grow, evade treatment, and recur. 3 replicates each of MCF7 Reactive Oxygen Species (ROS) high, HCT116 ROS high, MCF7 ROS low, and HCT116 ROS low.

Project description:Cyclin-dependent kinases 12 and 13 (CDK12 and CDK13) play pivotal roles in orchestrating transcription elongation, DNA damage response, and maintenance of genomic stability. Aberrant CDK12 expression, homozygous loss, and mutations have been documented in various malignancies. Previous studies have demonstrated CDK12 and 13 are promising therapeutic targets in cancer. In this study, we developed a selective CDK12/13 PROTAC degrader YJ9069, which in a panel of cancer cell lines, affirm its effectiveness in inhibiting cell proliferation in subsets of cancer. CDK12/13 degradation rapidly triggers gene-length dependent transcriptional elongation defects, leading to DNA damage and cell cycle arrest. In vivo, YJ9069 significantly suppresses tumor growth in prostate cancer cell line-derived xenograft (CDX) and patient-derived xenograft (PDX) models. Modifications of YJ9069 yielded a first-in-class orally bioavailable CDK12/13 degrader, YJ1206, which exhibits a comparable efficacy with significantly less toxicity. To identify pathways that may be synthetically lethal upon CDK12/13 degradation, we screened phosphorylation pathway arrays employing cell lines treated with YJ1206. Interestingly, degradation or genetic knock-down of CDK12/13, led to activation of the Akt pathway. Degradation of CDK12/13 with YJ1206, combined with AKT pathway inhibition with uprosertib, led to a striking synthetic lethal effect in pre-clinical models of prostate cancer. Taken together, these studies demonstrate that combination CDK12/13 and AKT pathway antagonism induces drug-drug synthetic lethality.

Project description:Cyclin-dependent kinases 12 and 13 (CDK12 and CDK13) play pivotal roles in orchestrating transcription elongation, DNA damage response, and maintenance of genomic stability. Aberrant CDK12 expression, homozygous loss, and mutations have been documented in various malignancies. Previous studies have demonstrated CDK12 and 13 are promising therapeutic targets in cancer. In this study, we developed a selective CDK12/13 PROTAC degrader YJ9069, which in a panel of cancer cell lines, affirm its effectiveness in inhibiting cell proliferation in subsets of cancer. CDK12/13 degradation rapidly triggers gene-length dependent transcriptional elongation defects, leading to DNA damage and cell cycle arrest. In vivo, YJ9069 significantly suppresses tumor growth in prostate cancer cell line-derived xenograft (CDX) and patient-derived xenograft (PDX) models. Modifications of YJ9069 yielded a first-in-class orally bioavailable CDK12/13 degrader, YJ1206, which exhibits a comparable efficacy with significantly less toxicity. To identify pathways that may be synthetically lethal upon CDK12/13 degradation, we screened phosphorylation pathway arrays employing cell lines treated with YJ1206. Interestingly, degradation or genetic knock-down of CDK12/13, led to activation of the Akt pathway. Degradation of CDK12/13 with YJ1206, combined with AKT pathway inhibition with uprosertib, led to a striking synthetic lethal effect in pre-clinical models of prostate cancer. Taken together, these studies demonstrate that combination CDK12/13 and AKT pathway antagonism induces drug-drug synthetic lethality.