Project description:We discovered that KRAS-mutant lung adenocarcinomas (LADC) co-opt CREB in order to evade the innate immune system: KRAS-driven CREB activation in LADC suppresses the expression of CXCR1 ligands that would otherwise recruit neutrophils to the tumor site. CREB was overexpressed in murine KRAS-mutant LADC, pulmonary Creb1-deletion inhibited disease development, and Creb1-overexpression boosted the tumorigenicity of KRAS-mutant cells. Conditional Creb1 deletion in Kras-mutant LADC cells caused overexpression of CXCR1/2 ligands, and lung tumor-bearing Creb1-deleted mice displayed increased pulmonary neutrophils. Cxcr1-deficient mice were selectively permissive to KRAS-mutant tumor growth and showed defective neutrophil recruitment. The pro-tumor effects of CREB required intact host-Cxcr1 and those of host-Cxcr1 necessitated mutant KRAS in cancer cells. Pharmacologic CREB blockade prevented tumor growth and restored neutrophil recruitment only when initiated before immune evasion of KRAS-mutant LADC cells. CREB and CXCR1 expression were respectively restricted to tumor and stromal cells of human LADC, while CREB-controlled genes profoundly impacted survival. In summary, CREB-mediated immune evasion of KRAS-mutant LADC rests on signaling to myeloid CXCR1 and is actionable.

Project description:KRAS is the most frequently mutated oncogene in human cancer, and KRAS inhibition has been a longtime goal. Recently, inhibitors (G12C-Is) that bind KRAS-G12C-GDP and react with Cys-12 were developed. Using new affinity reagents to monitor KRAS-G12C activation and inhibitor engagement, we found that SHP2 inhibitors (SHP2-Is) increased KRAS-GDP occupancy, enhancing G12C-I efficacy. SHP2-Is abrogated feedback signaling by multiple RTKs and adaptive resistance to G12C-Is in vitro, in xenografts, and in syngeneic KRAS-G12C-mutant pancreatic ductal adenocarcinoma (PDAC) and non-small cell lung cancer (NSCLC) models. The combination of SHP2-I and G12C-I evoked favorable changes in the immune microenvironment, decreasing myeloid suppressor cells, increasing CD8+ T cells, and sensitizing tumors to PD-1 blockade. Experiments using an inhibitor-resistant SHP2 mutant showed that SHP2 inhibition in PDAC cells is required for tumor regression and remodeling of the immune microenvironment, but SHP2-Is also had direct effects on angiogenesis. Our results demonstrate that SHP2-I/G12C-I combinations confer a substantial survival benefit in PDAC and NSCLC and identify additional potential combination strategies. G12C-Is show significant, but limited, efficacy as single agents, in part because of “adaptive resistance”. We find that combining G12C-Is with SHP2-Is abrogates adaptive resistance and results in favorable changes in the immune microenvironment that potentiate PD-1 blockade in KRAS-mutant malignancies. SHP2-Is also can have direct, context-dependent, effects on tumor vasculature.

Project description:KRAS G12C inhibitors (G12Ci) alone and in various combinations are being tested in multiple tumors with over-activation of the RAS/ERK pathway. KRAS plays a critical role in normal cell signaling; hence, G12Cis could influence the signaling pathways. We found that several novel pathways including Hippo pathways are upregulated upon MRTX849 treatment. Our results argue for testing KRAS G12C and TEAD inhibitor combinations in NSCLC patients.

Project description:KRAS G12C inhibitors (G12Ci) alone and in various combinations are being tested in multiple tumors with over-activation of the RAS/ERK pathway. KRAS plays a critical role in normal cell signaling; hence, G12Cis could influence the signaling pathways. We found that several novel pathways including Hippo pathways are upregulated upon MRTX849 treatment. Our results argue for testing KRAS G12C and TEAD inhibitor combinations in NSCLC patients.

Project description:KRAS G12C inhibitors (G12Ci) alone and in various combinations are being tested in multiple tumors with over-activation of the RAS/ERK pathway. KRAS plays a critical role in normal cell signaling; hence, G12Cis has been reported to create resistance. We found several novel pathways, including Hippo pathways, are enriched from significant dropouts upon MRTX849 treatment. Our results argue for testing KRAS G12C and TEAD inhibitor combinations in NSCLC patients.

Project description:Oncogenic KRAS mutations are a key driver for initiation and progression in non-small-cell lung cancer (NSCLC). However, how post-translational modifications (PTMs) of KRAS, especially methylation, modify KRAS activity remain largely unclear. Here, we show that SET domain containing histone lysine methyltransferase 7 (SETD7) interacts with KRAS and methylates KRAS at lysines 182 and 184. SETD7-mediated methylation of KRAS leads to degradation of KRAS and attenuation of the RAS/MEK/ERK signaling cascade, endowing SETD7 with a potent tumor-suppressive role in NSCLC, both in vitro and in vivo. Mechanistically, RABGEF1, a ubiquitin E3 ligase of KRAS, was recruited and promoted KRAS degradation in a K182/K184 methylation-dependent manner. Notably, SETD7 is inversely correlated with KRAS at the protein level in clinical NSCLC tissues. Low SETD7 or RABGEF1 expression is associated with poor prognosis in lung adenocarcinoma patients. Altogether, our results elucidate a tumor-suppressive function of SETD7 that operates via modulating KRAS methylation and degradation.

Project description:The protein tyrosine phosphatase SHP2 is crucial for oncogenic transformation of acute myeloid leukemia (AML) cells expressing mutated receptor tyrosine kinases (RTKs), as it is required for full RAS-ERK activation to promote cell proliferation and survival programs. SHP2 allosteric inhibitors act by stabilizing SHP2 in its auto-inhibited conformation and they are currently being tested in clinical trials for tumors with over-activation of the RAS/ERK pathway, alone and in various drug combinations. Using in vitro models, we established acquired resistant cell lines to the allosteric SHP2 inhibitor SHP099 from two FLT3-ITD-positive AML cell lines. We performed both label-free and isobaric labeling quantitative mass spectrometry-based phosphoproteomics to reveal that AML cells can restore phosphorylated ERK (pERK) in presence of SHP099, thus developing adaptive resistance. Mechanistically, SHP2 inhibition induces the tyrosine phosphorylation and feedback-activation of the FLT3 receptor, which in turn phosphorylates SHP2 on Tyrosine 62. This phosphorylation stabilizes SHP2 in its open conformation, preventing SHP099 binding, thus resulting in resistance. Combinatorial inhibition of SHP2 and MEK or SHP2 and FLT3 prevents pERK rebound and resistant cell growth. We observed the same mechanism in a FLT3-mutated B-ALL cell line and in the inv(16)/KITD816Y AML mouse model. Finally, we show that allosteric SHP2 inhibition does not impair the clonogenic ability of normal bone marrow progenitors, supporting its future use for clinical applications.

Project description:KRAS mutant pancreatic tumors have poor prognosis and few therapeutic options. Here, Frank et al. show that the combination of RMC4550 (SHP2 inhibitor) and LY3214996 (ERK inhibitor)  effectively impairs tumor growth and induces tumor regression in multiplein vivo models of PDAC .

Project description:KRAS mutant pancreatic tumors have poor prognosis and few therapeutic options. Here, Frank et al. show that the combination of RMC4550 (SHP2 inhibitor) and LY3214996 (ERK inhibitor)  effectively impairs tumor growth and induces tumor regression in multiplein vivo models of PDAC .

Project description:Combined Inhibition of SHP2 and CXCR1/2 Promotes Anti-Tumor T Cell Response in NSCLC