Project description:KRASG12C inhibitors (KRASG12Ci) AMG510 and MRTX849 have shown promising efficacy in clinical trials and been approved for the treatment of KRASG12C-mutant cancers. However, the emergence of therapy-related drug resistance limits their long-term potential. We measured gene expression using RNA-sequencing for pancreatic cancer cell line MIA PaCa-2 parental and their AMG510-resistant equivalent without treatment or treated with with G12C KRAS inhibitor AMG510.

Project description:KRAS is the most frequently mutated oncogene in human cancers, but to date, only KRASG12C inhibitors have been FDA-approved. Small-molecule inhibitors that target other more prevalent KRAS mutations are in urgent clinical need. Here, we report a highly potent pan-KRAS inhibitor, MCB-294, that selectively targets KRAS, but not HRAS or NRAS. Molecular profiling studies show that MCB-294 binds to and inhibits several KRAS mutants, including G12D, G12C, G12V, thereby disabling KRAS oncogenic signaling. MCB-294 is well tolerated in mice and exhibits remarkable therapeutic efficacy against the growth of a comprehensive range of KRAS-driven cancer cell lines, patient-derived organoids, and tumor xenografts and prolongs mouse survival. By employing an MCB-294 derivative as the KRAS binder, we further identify a VHL-based pan-KRAS degrader, MCB-36, that efficiently degrades KRAS in vitro and in vivo through the ubiquitin-proteasome system. Importantly, MCB-294 and MCB-36 not only effectively kill KRASG12C inhibitor-resistant cells, but also reshape the tumor microenvironment by boosting T cell-mediated anti-tumor immunity. Taken together, our findings demonstrate a successful and feasible strategy for targeting pan-KRAS to impair multifaceted features of KRAS-driven cancers.

Project description:KRAS is the most frequently mutated oncogene in human cancers, but to date, only KRASG12C inhibitors have been FDA-approved. Small-molecule inhibitors that target other more prevalent KRAS mutations are in urgent clinical need. Here, we report a highly potent pan-KRAS inhibitor, MCB-294, that selectively targets KRAS, but not HRAS or NRAS. Molecular profiling studies show that MCB-294 binds to and inhibits several KRAS mutants, including G12D, G12C, G12V, thereby disabling KRAS oncogenic signaling. MCB-294 is well tolerated in mice and exhibits remarkable therapeutic efficacy against the growth of a comprehensive range of KRAS-driven cancer cell lines, patient-derived organoids, and tumor xenografts and prolongs mouse survival. By employing an MCB-294 derivative as the KRAS binder, we further identify a VHL-based pan-KRAS degrader, MCB-36, that efficiently degrades KRAS in vitro and in vivo through the ubiquitin-proteasome system. Importantly, MCB-294 and MCB-36 not only effectively kill KRASG12C inhibitor-resistant cells, but also reshape the tumor microenvironment by boosting T cell-mediated anti-tumor immunity. Taken together, our findings demonstrate a successful and feasible strategy for targeting pan-KRAS to impair multifaceted features of KRAS-driven cancers.

Project description:KRAS is the most frequently mutated oncogene in human cancers, but to date, only KRASG12C inhibitors have been FDA-approved. Small-molecule inhibitors that target other more prevalent KRAS mutations are in urgent clinical need. Here, we report a highly potent pan-KRAS inhibitor, MCB-294, that selectively targets KRAS, but not HRAS or NRAS. Molecular profiling studies show that MCB-294 binds to and inhibits several KRAS mutants, including G12D, G12C, G12V, thereby disabling KRAS oncogenic signaling. MCB-294 is well tolerated in mice and exhibits remarkable therapeutic efficacy against the growth of a comprehensive range of KRAS-driven cancer cell lines, patient-derived organoids, and tumor xenografts and prolongs mouse survival. By employing an MCB-294 derivative as the KRAS binder, we further identify a VHL-based pan-KRAS degrader, MCB-36, that efficiently degrades KRAS in vitro and in vivo through the ubiquitin-proteasome system. Importantly, MCB-294 and MCB-36 not only effectively kill KRASG12C inhibitor-resistant cells, but also reshape the tumor microenvironment by boosting T cell-mediated anti-tumor immunity. Taken together, our findings demonstrate a successful and feasible strategy for targeting pan-KRAS to impair multifaceted features of KRAS-driven cancers.

Project description:Oncogenic KRAS mutations frequently detected in non-small cell lung cancer (NSCLC) have been considered undruggable until recent development of inhibitors, e.g., sortorasib, adagrasib or divarasib, specifically targeting KRASG12C. However, it still remains as a big challenge to target all the KRAS mutants besides KRASG12C. We here found that MEK inhibitor trametinib treatment results in the feedback activation of multiple receptor tyrosine kinases (RTKs) in NSCLC, and combined treatments with trametinib and anlotinib, a pan-RTK inhibitor, effectively inhibited KRAS-mutant lung cancer progression.

Project description:Oncogenic KRAS mutations frequently detected in non-small cell lung cancer (NSCLC)1,2, have been considered undruggable until recent development of inhibitors, e.g., sortorasib, adagrasib or divarasib, specifically targeting KRASG12C 3-6. However, it still remains as a big challenge to target all the KRAS mutants besides KRASG12C 2,7,8. We here found that MEK inhibitor trametinib treatment results in the feedback activation of multiple receptor tyrosine kinases (RTKs) in NSCLC, and combined treatments with trametinib and anlotinib, a pan-RTK inhibitor, effectively inhibited KRAS-mutant lung cancer progression.

Project description:Targeting ubiquitin-independent proteasome with small molecule increases susceptibility in pan-KRAS mutant cancers

Project description:KRAS is the most frequently mutated oncogene found in pancreatic, colorectal, and lung cancers. Although it has been challenging to identify targeted therapies for cancers harboring KRAS mutations, one particular form of mutant KRAS, namely KRASG12C, can be targeted by small molecule inhibitors that form covalent bonds with cysteine 12 (C12). Here, we designed a library of C12-directed covalent degrader molecules (PROTACs) and subjected them to a rigorous evaluation process to rapidly identify a lead compound. Although our lead degrader successfully engaged CRBN in cells, bound KRASG12C in vitro, induced CRBN/ KRASG12C dimerization, and degraded GFP-KRASG12C in GFP reporter cells in a CRBN-dependent manner, it failed to degrade endogenous KRASG12C in pancreatic and lung cancer cells. Our data suggest that inability of the lead degrader to effectively polyubiquitinate endogenous KRASG12C underlies the lack of activity. We discuss challenges for achieving targeted KRASG12C degradation and propose several possible solutions which may lead to efficient degradation of endogenous KRASG12C.

Project description:KRAS is the most frequently mutated oncogene found in pancreatic, colorectal, and lung cancers. Although it has been challenging to identify targeted therapies for cancers harboring KRAS mutations, one particular form of mutant KRAS, namely KRASG12C, can be targeted by small molecule inhibitors that form covalent bonds with cysteine 12 (C12). Here, we designed a library of C12-directed covalent degrader molecules (PROTACs) and subjected them to a rigorous evaluation process to rapidly identify a lead compound. Although our lead degrader successfully engaged CRBN in cells, bound KRASG12C in vitro, induced CRBN/ KRASG12C dimerization, and degraded GFP-KRASG12C in GFP reporter cells in a CRBN-dependent manner, it failed to degrade endogenous KRASG12C in pancreatic and lung cancer cells. Our data suggest that inability of the lead degrader to effectively polyubiquitinate endogenous KRASG12C underlies the lack of activity. We discuss challenges for achieving targeted KRASG12C degradation and propose several possible solutions which may lead to efficient degradation of endogenous KRASG12C.

Project description:KRAS is the most frequently mutated oncogene found in pancreatic, colorectal, and lung cancers. Although it has been challenging to identify targeted therapies for cancers harboring KRAS mutations, one particular form of mutant KRAS, namely KRASG12C, can be targeted by small molecule inhibitors that form covalent bonds with cysteine 12 (C12). Here, we designed a library of C12-directed covalent degrader molecules (PROTACs) and subjected them to a rigorous evaluation process to rapidly identify a lead compound. Although our lead degrader successfully engaged CRBN in cells, bound KRASG12C in vitro, induced CRBN/ KRASG12C dimerization, and degraded GFP-KRASG12C in GFP reporter cells in a CRBN-dependent manner, it failed to degrade endogenous KRASG12C in pancreatic and lung cancer cells. Our data suggest that inability of the lead degrader to effectively polyubiquitinate endogenous KRASG12C underlies the lack of activity. We discuss challenges for achieving targeted KRASG12C degradation and propose several possible solutions which may lead to efficient degradation of endogenous KRASG12C.