KRAS G12C Mutation Research Articles

Molecular profiling reveals novel therapeutic targets and clonal evolution in ovarian clear cell carcinoma.

Ovarian clear cell carcinoma (OCCC) has a disproportionately high incidence among women in East Asia. Patients diagnosed with OCCC tend to experience worse clinical outcomes than those with high-grade serous carcinoma (HGSC) at advanced stages. The unfavorable prognosis of OCCC can be partly attributed to its frequent resistance to conventional chemotherapy. Within a precision medicine framework, we sought to provide a comprehensive molecular characterization of OCCC using whole-exome sequencing to uncover potential molecular targets that may inform novel therapeutic strategies. We performed whole-exome sequencing analysis on tumor-normal paired samples from 102 OCCC patients. This comprehensive genomic characterization of a substantial cohort of OCCC specimens was coupled with an analysis of clonal progression. On analyzing 102 OCCC samples, ARID1A (67%) and PIK3CA (49%) emerged as the most frequently mutated driver genes. We identified tier 1 or 2 clinically actionable molecular targets in 40% of cases. This included DNA mismatch repair deficiency (n = 1), as well as BRCA2 (n = 1), PIK3CA (n = 36), KRASG12C (n = 1), and ATM (n = 4) mutations. Furthermore, 45% of OCCC samples displayed ARID1A biallelic loss. Interestingly, we identified previously unreported mutations in the 5' untranslated region of the TERT gene that harbored an adverse prognostic significance. Clock-like mutational processes and activated APOBECs were major drivers of somatic point mutations. Mutations arising from DNA mismatch repair deficiency were uncommon. Reconstruction of clonal evolution revealed that early genetic events likely driving tumorigenesis included mutations in the ARID1A, PIK3CA, TERT, KRAS, and TP53 genes. Our study provides a comprehensive characterization of the genomic landscape and clonal evolution in OCCC within a substantial cohort. These findings unveil potentially actionable molecular alterations that could be leveraged to develop targeted therapies.

Redefining pancreatic cancer management with tumor-agnostic precision medicine.

Precision oncology and tumor-agnostic drug development provide hope for enhancing outcomes among patients with pancreatic cancer. Tumor-agnostic therapies have emerged across various tumor types, driven by insights into shared biomarkers. In the case of pancreatic cancer, the prevalence of the KRAS gene mutation is noteworthy. However, there exist other actionable alterations, such as BRCA1/2 mutations and fusion genes (BRAF, FGFR2, RET, NTRK, NRG1, and ALK), which present potential targets for therapy. Notably, tumor-agnostic drugs have demonstrated efficacy in specific subsets of pancreatic cancer patients who harbor these genetic alterations. Despite the rarity of NTRK fusions in pancreatic cancer, larotrectinib and entrectinib have exhibited effectiveness in NTRK fusion-positive pancreatic cancers. Additionally, repotrectinib, a next-generation NTRK inhibitor, has shown promising activity in NTRK positive pancreatic cancer patients who have developed acquired resistance to previous NTRK inhibitors. Immune checkpoint inhibitors, such as pembrolizumab and dostarlimab, have proven to be effective in dMMR/MSI-H pancreatic cancers. Moreover, targeted therapies for BRAF V600, RET fusions, and HER2/neu overexpression have displayed promising results in specific subsets of pancreatic cancer patients. Emerging targets like NRG fusions, FGFR2 fusions, TP53 mutations, and KRAS G12C mutations present potential avenues for targeted therapy. Tumor-agnostic therapies have the potential to revolutionize pancreatic cancer treatment by focusing on specific genetic alterations. It is crucial to continue implementing comprehensive screening strategies that encompass the ability to detect all these tumor-agnostic biomarkers. This will be essential in identifying pancreatic cancer patients who may benefit from these therapies.

Dependence of NPPS creates a targetable vulnerability in RAS-mutant cancers.

RAS is the most frequently mutated oncoprotein for cancer driving. Understanding of RAS biology and discovery of druggable lynchpins in RAS pathway is a prerequisite for targeted therapy of RAS-mutant cancers. The recent identification of KRASG12C inhibitor breaks the "undruggable" curse on RAS and has changed the therapy paradigm of KRAS-mutant cancers. However, KRAS mutations, let alone KRASG12C mutation, account for only part of RAS-mutated cancers. Targeted therapies for cancers harboring other RAS mutations remain the urgent need. In this study we explored the pivotal regulatory molecules that allow for broad inhibition of RAS mutants. By comparing the expression levels of nucleotide pyrophosphatase (NPPS) in a panel of cell lines and the functional consequence of increased NPPS expression in RAS-mutant cells, we demonstrated that cancer cells with various kinds of RAS mutations depended on NPPS for growth and survival, and that this dependence conferred a vulnerability of RAS-mutant cancer to treatment of NPPS inhibition. RAS-mutant cells, compared with RAS-wildtype cells, bored and required an upregulation of NPPS. Transcriptomics and metabolomics analyses revealed a NPPS-dependent hyperglycolysis in RAS-mutant cells. We demonstrated that NPPS promoted glucose-derived glycolytic intermediates in RAS-mutant cells by enhancing its interaction with hexokinase 1 (HK1), the enzyme catalyzing the first committed step of glycolysis. Pharmacological inhibition of NPPS-HK1 axis using NPPS inhibitor Enpp-1-IN-1 or HK1 inhibitor 2-deoxyglucose (2-DG), or genetic interfere with NPPS suppressed RAS-mutant cancers in vitro and in vivo. In conclusion, this study reveals an unrecognized mechanism and druggable lynchpin for modulation of pan-mutant-RAS pathway, proposing a new potential therapeutic approach for treating RAS-mutant cancers.

KRAS G12C mutation in NSCLC in a small genetic center: insights into sotorasib therapy response potential

Lung cancer remains a significant health challenge, characterized by aberrant tissue growth within the pulmonary system. Early carcinogenic events often involve genomic instability and the emergence of a mutator phenotype. In this study, we aimed to explore the mutator phenotype in 89 patients diagnosed with non-small-cell lung cancer (NSCLC). RNA isolation from formalin-fixed paraffin-embedded (FFPE) tissue samples was performed using the Promega ReliaPrep RNA Miniprep System, facilitating gene amplification relevant to cancer through the Archer® FusionPlexComprehensiveThyroid and Lung (CTL) kit. Next-generation sequencing (NGS) on the Illumina NextSeq platform enabled comprehensive analysis of target areas. Utilizing Archer Analysis software, secondary analyses involving data cleansing, alignment, and variant/fusion identification were executed against the human reference genome hg19 (GRCh37). Expression patterns were visualized using HeatMap graphics. Our findings revealed a notable presence of KRAS gene mutations in approximately 20% of NSCLC patients. Among these mutations, the G12C variant was predominant at 50%, followed by G12V and G12D variants at 11.2% each. Notably, patients harboring the G12C variant responded favorably to sotorasib medication. These results underscore the importance of mutational profiling and targeted therapeutic approaches in managing NSCLC, particularly highlighting the promising efficacy of sotorasib in G12C-mutated cases.

A novel label-free impedance biosensor for KRAS G12C mutations detection based on PET-RAFT and ROP synergistic signal amplification

The KRAS G12C mutations, as crucial biomarkers, are closely associated with non-small cell lung cancer. Here, a novel label-free electrochemical biosensor with synergistic signal amplification of photocell energy transfer-reversible addition fragmentation chain transfer (PET-RAFT) and ring-opening polymerization (ROP) was developed for the first time for sensitive detection of KRAS G12C mutations. Specifically, hairpin DNA (hDNA), which act as biomolecular probe, was self-assembled on Au electrode surface by Au-S bond. 4-cyano-4-[(dodecylsulfanylthiocarbonyl) sulfanyl] pentanoic acid (CDTPA), the chain transfer agent of PET-RAFT reaction, was then attached to hDNA via amide bond. After that, the target DNA (tDNA) was captured on the electrode surface by complementary base pairing with hDNA. Subsequently, large numbers of electro-active monomers N-acryloxysuccinimide (NAS) were successfully grafted to the electrode surface via PET-RAFT reaction, which provided plenty of junction sites for doxorubicin-polycaprolactone (Dox-PCL) synthesized by ROP. Finally, the Dox-PCL was connected to the electrode surface by ester bond, significantly amplifying the electrochemical signal. Under optimized conditions, the biosensor has a wide linear detection range of 0.1 pM to 1 μM, with a detection limit of 86.9 fM. Attribute to its high sensitivity, specificity, reproducibility and stability, this biosensor possesses considerable potential in early diagnosis of disease and biomedical research.

Reactivation of MAPK-SOX2 pathway confers ferroptosis sensitivity in KRASG12C inhibitor resistant tumors

The clinical success of KRASG12C inhibitors (G12Ci) including AMG510 and MRTX849 is limited by the eventual development of acquired resistance. A novel and effective treatment to revert or target this resistance is urgent. To this end, we established G12Ci (AMG510 and MRTX849) resistant KRASG12C mutant cancer cell lines and screened with an FDA-approved drug library. We found the ferroptosis inducers including sorafenib and lapatinib stood out with an obvious growth inhibition in the G12Ci resistant cells. Mechanistically, the G12Ci resistant cells exhibited reactivation of MAPK signaling, which repressed SOX2-mediated expression of cystine transporter SLC7A11 and iron exporter SLC40A1. Consequently, the low intracellular GSH level but high iron content engendered hypersensitivity of these resistant tumors to ferroptosis inducers. Ectopic overexpression of SOX2 or SLC7A11 and SLC40A1 conferred resistance to ferroptosis in the G12Ci resistant cells. Ferroptosis induced by sulfasalazine (SAS) achieved obvious inhibition on the tumor growth of xenografts derived from AMG510-resistant KRASG12C-mutant cells. Collectively, our results suggest a novel therapeutic strategy to treat patients bearing G12Ci resistant cancers with ferroptosis inducers.

Comparative Efficacy of Adagrasib and Sotorasib in KRAS G12C-Mutant NSCLC: Insights from Pivotal Trials.

Background: The KRAS G12C mutation, prevalent in various malignancies, including non-small cell lung cancer (NSCLC), represents a unique therapeutic target. Adagrasib and sotorasib, two FDA-approved agents specifically targeting this mutation, have shown promise in clinical trials. This study aims to compare their efficacy in treating KRAS G12C-mutated NSCLC, drawing insights from pivotal clinical trials. Methods: We analyzed data from three key clinical trials: KRYSTAL-1, CodeBreak100, and CodeBreak200. Our methodology involved reconstructing individual patient data from published Kaplan-Meier curves using the IPDfromKM tool (Version 0.1.10). The primary endpoints were progression-free survival (PFS) and overall survival (OS), evaluated through hazard ratios (HRs) and the restricted mean survival time (RMST) method. Results: The HR for PFS favored adagrasib (HR: 0.90 [95% CI: 0.69, 1.19], p = 0.473), suggesting a non-significant trend toward better disease control compared to sotorasib. For OS, the HR was 0.99 [95% CI: 0.75, 1.33] (p = 0.969), indicating no significant difference between the two drugs. RMST analysis supported these findings, with adagrasib showing a consistently higher RMST in PFS at 6, 12, and 18 months. However, OS benefits converged over time, with adagrasib marginally surpassing sotorasib by the 18-month mark. Conclusions: This comprehensive analysis reveals that while adagrasib may offer a slight advantage in PFS, both drugs demonstrate comparable efficacy in OS for KRAS G12C-mutated NSCLC. The subtle differences observed, particularly in PFS, could inform clinical decision-making, emphasizing the need for personalized treatment strategies. Future research should focus on long-term effects and identifying patient subgroups that may benefit more from one drug over the other.

Comprehensive liquid biopsy analysis for monitoring NSCLC patients under second-line osimertinib treatment.

The heterogeneous and complex genetic landscape of NSCLC impacts the clinical outcomes of patients who will eventually develop resistance to osimertinib. Liquid biopsy (LB) analysis as a minimally invasive approach is a key step to efficiently identify resistance mechanisms and adjust to proper subsequent treatments. In the present study, we combined plasma-cfDNA and CTC analysis from 30 NSCLC patients in samples collected before treatment and at the progression of disease (PD). We detected molecular alterations at the DNA mutation (EGFR, PIK3CA, KRAS G12C, BRAF V600E), DNA methylation (RASSF1A, BRMS1, FOXA1, SLFN1, SHISA3, RARβ,, WIF-1, RASSF10 and APC), gene expression (CK-19, CK-18, CK-8, AXL, TWIST-1, PD-L1, PIM-1, Vimentin, ALDH-1, and B2M) and chromosomal level (HER2 and MET amplification) as possible resistance mechanisms and druggable targets. We also studied the expression of PD-L1 in single CTCs using immunofluorescence. In some cases, T790M resistance EGFR mutation was detected at baseline in CTCs but not in the corresponding plasma cfDNA. PIK3CA mutations were detected only in plasma-cfDNA but not in corresponding CTCs. KRAS G12C and BRAF V600E mutations were not detected in the samples analyzed. MET amplification was detected in the CTCs of two patients before treatment whereas HER2 amplification was detected in the CTCs of three patients at baseline and in one patient at PD. DNA methylation analysis revealed low concordance between CTCs and cfDNA, indicating the complementary information obtained through parallel LB analysis. Results from gene expression analysis indicated high rates of vimentin-positive CTCs detected at all time points during osimertinib. Moreover, there was an increased number of NSCLC patients at PD harboring CTCs positive in PD-L1. AXL and PIM-1 expression detected in CTCs during treatment suggesting new possible therapeutic strategies. Our results reveal that comprehensive liquid biopsy analysis can efficiently represent the heterogeneous molecular landscape and provide prominent information on subsequent treatments for NSCLC patients at PD since druggable molecular alterations were detected in CTCs.

Exploration of Cryptic Pockets Using Enhanced Sampling Along Normal Modes: A Case Study of KRAS G12D.

Identification of cryptic pockets has the potential to open new therapeutic opportunities by discovering ligand binding sites that remain hidden in static apo structures of a target protein. Moreover, allosteric cryptic pockets can become valuable for designing target-selective ligands when the natural ligand binding sites are conserved in variants of a protein. For example, before an allosteric cryptic pocket was discovered, KRAS was considered undruggable due to its smooth surface and conservation of the GDP/GTP binding pocket across the wild type and oncogenic isoforms. Recent identification of the Switch-II cryptic pocket in the KRASG12C mutant and FDA approval of anticancer drugs targeting this site underscores the importance of cryptic pockets in solving pharmaceutical challenges. Here, we present a newly developed approach for the exploration of cryptic pockets using weighted ensemble molecular dynamics simulations with inherent normal modes as progress coordinates applied to the wild type KRAS and the G12D mutant. We performed extensive all-atomic simulations (>400 μs) with and without several cosolvents (xenon, ethanol, benzene), and analyzed trajectories using three distinct methods to search for potential binding pockets. These methods have been applied as a proof-of-concept to KRAS and have shown they can predict known cryptic binding sites. Furthermore, we performed ligand-binding simulations of a known inhibitor (MRTX1133) to shed light on the nature of cryptic pockets in KRASG12D and the role of conformational selection vs induced-fit mechanism in the formation of these cryptic pockets.

OA14.04 Efficacy and Safety of Olomorasib with Pembrolizumab + Chemotherapy as First-Line Treatment in Patients with KRAS G12C-Mutant Advanced NSCLC

OA14.04 Efficacy and Safety of Olomorasib with Pembrolizumab + Chemotherapy as First-Line Treatment in Patients with KRAS G12C-Mutant Advanced NSCLC

Multigene Panel Next-Generation Sequencing Techniques in the Management of Patients with Metastatic Colorectal Carcinoma: The Way Forward for Personalized Treatment? A Single-Center Experience

The efficacy and cost-effectiveness of Multigene Panel Next-Generation Sequencing (NGS) in directing patients towards genomically matched therapies remain uncertain. This study investigated metastatic colorectal cancer (mCRC) patients who underwent NGS analysis on formalin-fixed paraffin-embedded tumor samples. Data from 179 patients were analyzed, revealing no mutations in 39 patients (21.8%), one mutation in 83 patients (46.4%), and two or more mutations in 57 patients (31.8%). KRAS mutations were found in 87 patients (48.6%), including KRAS G12C mutations in 5 patients (2.8%), PIK3CA mutations in 40 patients (22.4%), and BRAF mutations in 26 patients (14.5%). Less common mutations were identified: ERBB2 in five patients (2.8%) and SMO in four patients (2.2%). Additionally, MAP2K1, CTNNB1, and MYC were mutated in three patients (2.4%). Two mutations (1.1%) were observed in ERBB3, RAF1, MTOR, JAK1, and FGFR2. No significant survival differences were observed based on number of mutations. In total, 40% of patients had druggable molecular alterations, but only 1.1% received genomically guided treatment, suggesting limited application in standard practice. Despite this, expanded gene panel testing can identify actionable mutations, aiding personalized treatment strategies in metastatic CRC, although current eligibility for biomarker-guided trials remains limited.

Clinical utility of upfront liquid biopsy in non-small cell lung cancer in the community setting.

316 Background: Molecular diagnosis of advanced non-small cell lung cancer (NSCLC) is critical to guide therapeutic decisions. Blood next generation sequencing (NGS) allows for non-invasive screening for targetable genetic abnormalities. Many studies have validated using the liquid biopsies to screen for resistant mutations at the emergence of treatment failure. However, the clinical utility of liquid biopsy for newly diagnosed NSCLC, as part of a comprehensive molecular profiling, is an area of active research. Methods: Retrospective analysis of the molecular landscape and clinical outcomes in NSCLC patients who had liquid biopsy done between December of 2017 to February of 2022. Patients had EGFR, ALK, ROS-1, and BRAF tested in the tissue, and underwent liquid biopsy for broad molecular profiling. The plasma genotyping was conducted using a 73-gene panel by Guardant 360 test. Actionable mutations were stratified accordingly to the OncoKB database based on the level of preclinical and clinical evidence of drug targetability. Survival analysis was conducted by August of 2023. Results: We enrolled 122 NSCLC patients who 84% were treatment-naïve and 78% had the liquid biopsy performed at the initial diagnosis. We found that 86 patients had oncogenic mutations and 43 (35%) had actionable mutations, with 37 (29%) falling under level 1 of evidence mutations. EGFR and KRAS G12C mutations were the two most common level 1 genetic abnormalities (23% and 11% of all actionable mutations, respectively). We identified two germline BRCA carriers who were referred for genetic counselling. 25 patients (20%) received treatment based on the liquid biopsy results, with 15 (12%) achieving partial response. Six patients had liquid biopsy done at progression of EGFR or MET therapies, which identified a resistance mechanism in three of them. Conclusions: Upfront liquid biopsy identified a significant proportion of patients with targetable mutations. Here, we reported actionable mutations in 35% of our patients who 84% had no prior systemic treatment. Our results complement prior literature and shows that blood next generation sequencing can be a useful tool to guide upfront therapeutical options at the community healthcare setting.

Molecular Profiling of Low-Grade Appendiceal Mucinous Neoplasms (LAMN).

Low-grade appendiceal mucinous neoplasia (LAMN) represents a relatively rare tumor of the appendix typically diagnosed incidentally through appendectomy for acute appendicitis. In cases where perforation occurs, mucinous content may disseminate into the abdominal cavity, leading to the development of pseudomyxoma peritonei (PMP). The primary objective of this study was to elucidate the molecular characteristics associated with various stages of LAMN and PMP. DNA was extracted from LAMN, primary PMPs, recurrent PMPs, and adenocarcinomas originating from LAMN. The subsequent analysis involved the examination of mutational hotspot regions within 50 cancer-related genes, covering over 2800 COSMIC mutations, utilizing amplicon-based next-generation sequencing (NGS). Our findings revealed activating somatic mutations within the MAPK-signaling pathway across all tumors examined. Specifically, 98.1% of cases showed mutations in KRAS, while one tumor harbored a BRAF mutation. Additionally, GNAS mutations were identified in 55.8% of tumors, with no significant difference observed between LAMN and PMP. While LAMN rarely displayed additional mutations, 42% of primary PMPs and 60% of recurrent PMPs showed additional mutations. Notably, both adenocarcinomas originating from LAMN showed mutations within TP53. Furthermore, 7.7% (4/52) of cases exhibited a potentially targetable KRAS G12C mutation. In four patients, NGS analysis was performed on both primary PMP and recurrent PMP/adenocarcinoma samples. While mutations in KRAS and GNAS were detected in almost all samples, 50% of recurrent cases displayed an additional SMAD4 mutation, suggesting a notable alteration during disease progression. Our findings indicate two key points: First, mutations within the MAPK pathway, particularly in KRAS, are evident across all tumors, along with a high frequency of GNAS mutations. Second, progression toward PMP or adenocarcinoma is associated with an accumulation of additional mutations within common oncogenic pathways.

384 (PB372): TUSC2 gene therapy in KRASG12C mutant NSCLC overcomes acquired resistance to sotorasib

384 (PB372): TUSC2 gene therapy in KRASG12C mutant NSCLC overcomes acquired resistance to sotorasib

Potent covalent irreversible inhibitor of KRAS G12C IBI351 in patients with advanced solid tumors: First-in-human phase I study

BackgroundIBI351 is an irreversible and covalent inhibitor of KRAS G12C. Despite FDA approval of two KRAS G12C inhibitors, there are still significant unmet clinical needs in Chinese patients and ongoing concerns about the optimal dosage. Herein, we presented the phase Ia/Ib study of IBI351 monotherapy in Chinese patients with advanced solid tumors harboring KRAS G12C mutation. MethodsIn phase Ia dose escalation, IBI351 at 250/450/700/900 mg once daily and 450/600/750 mg twice daily (BID) were evaluated. Potentially efficacious doses and optimal recommended phase 2 dose (RP2D) were further evaluated in patients with advanced non-small cell lung cancer (NSCLC) in phase Ia dose expansion and phase Ib. Safety, pharmacokinetics, and investigator-assessed tumor response were evaluated. ResultsAs of June 13, 2023, 176 patients were enrolled. IBI351 was well tolerated with no dose-limiting toxicity reported across all evaluated doses. The RP2D was determined as 600 mg BID by considering safety, efficacy and pharmacokinetics. A total of 168 patients (95.5 %) had at least one treatment-related adverse event (TRAE), and 64 patients (36.4 %) had grade 3 or higher TRAEs, most commonly gamma-glutamyl transferase increased (10.2 %) and anemia (6.8 %). For patients with NSCLC, the confirmed objective response rate (ORR) was 45.5 % across all doses. At 600 mg BID, the confirmed ORR was 46.8 % and median progression-free survival was 9.6 months with a median follow-up of 6.9 months. ConclusionsIBI351 was well tolerated in patients with advanced solid tumors and showed promising antitumor activity in advanced NSCLC patients with KRAS G12C mutation.

Abstract C168: Developing lung adenocarcinoma cell lines to mitigate lung cancer health disparities

Abstract Lung cancer continues to be the number one cause of cancer-related deaths worldwide and remains a prominent source of cancer health disparities. Black/African American (B/AA) males exhibit a 12% higher lung cancer incidence rate and a 15% higher lung cancer death rate when compared to white males. Lung adenocarcinoma (LUAD) is the most common histological subtype of lung cancer in all ethnic/racial groups, including B/AAs. To further examine this phenomenon, we want to create a collection of lung cancer cell lines that would be useful for molecular studies of lung cancer development, progression, development of new targeted therapies, and pre-clinical drug testing. After reviewing the literature (Leon et al. 2023, Frontiers in Oncology, Vol. 13, p. 1187585, 2023), we identified only 30 unique B/AA cell lines out of ∼800, the majority of which are derived from White and Asian patients. Moreover, only 6 of the 30 cell lines are derived from patients with LUAD. We are in the process of deriving more LUAD cell lines from B/AA patients as well as alveolar epithelial cell lines in order to study the development of LUAD. In addition, we are creating a collection of multiple independent isogenic cell line variants from an existing lung cancer cell line NCI-H23. NCI-H23 was derived from a B/AA male LUAD patient and harbors a KRASG12C heterozygous mutation. G12C is the most common KRAS mutation in LUAD (∼40% of KRAS mutations) followed by G12V (∼20%), G12D (∼15%), G12A (∼10%), and G13C (∼6%). We used CRISPR/Cas-9 genome- based editing to replace the KRASG12C mutation with KRASG12V, KRASG12D, KRASG12A, and KRASG13C. We have derived multiple independent cell lines for most mutations. We are in the process of performing whole genome sequencing of these cell lines to exclude any off-target effects that may have arisen from the CRISPR/Cas-9 engineering. In addition, we will carry out whole genome RNA sequencing to assess the effect of the engineering and/or KRAS mutation switching. As a control, we are also sequencing the genomes and transcriptomes of three monoclonal cell lines we derived from NCI-H23 cells, to determine what variability ensues with the derivation of monoclonal lines, since that is required to obtain the CRISPR/Cas9-edited cells. We will use this collection of cell lines to study the efficacy of polyisoprenylated cysteinyl amide inhibitors (PCAIs) and other drugs on cell lines bearing these KRAS mutations. PCAIs were developed to target cells carrying mutant KRAS. Our efforts will provide new cell lines to study lung adenocarcinoma in B/AA subjects, addressing a key shortcoming and disparity in the lung cancer research toolkit. Citation Format: Sofia A. Lugo, Christopher Leon, Matthew A. Gladstone, Chunli Yan, Daniel J. Mullen, Pablo E. Puente, Kweku Ofosu-Asante, Justin K. Mensah-Mamfo, Kyle R. Phillips, Yong Huang, Nazarius S. Lamango, Ite A. Offringa. Developing lung adenocarcinoma cell lines to mitigate lung cancer health disparities [abstract]. In: Proceedings of the 17th AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2024 Sep 21-24; Los Angeles, CA. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2024;33(9 Suppl):Abstract nr C168.

Abstract C025: A novel pan-RAS/β-catenin inhibitor, ADT-030, produces tumor regression in PDX models of pancreatic cancer

Abstract BACKGROUND: The absence of symptoms often leads to late diagnosis of pancreatic ductal adenocarcinoma (PDAC) limiting treatment options. Tumor cell proliferation and invasion/metastasis are usually driven by KRAS mutations and activation of Wnt/β-catenin pathway components. The recent approval of KRASG12C-specific inhibitors for lung cancer has validated RAS as a druggable target but has had limited application for PDAC given the rarity of this codon in PDAC. In addition, no Wnt/β-catenin inhibitors have been FDA approved. Thus, drugs which inhibit these important targets are urgently needed for PDAC and other cancers. Here, we describe treatment results with ADT-030, a novel dual pan-RAS/β-catenin inhibitor in murine models of PDAC and lung cancer. METHODS: In vitro assays of growth inhibition, colony formation, apoptosis, and cell cycle, along with western blotting for RAS signaling were performed to assess potency and selectivity of ADT-030. Murine 2838c3-Luc KRASG12D PDAC cells were implanted orthotopically into the pancreas of C57BL/6J mice and cells from two PDAC patient-derived xenograft (PDX) models harboring KRASG12D or KRASG12C mutations were implanted subcutaneously (SC) in NSG mice to evaluate the antitumor activity of ADT-030. ADT-030 was administered once daily by gavage 5x/week for 4 weeks. RESULTS: ADT-030 potently inhibited the growth of PDAC cells in vitro harboring the most prevalent KRASG12D mutation as well as those with KRASG12C. Annexin V assay revealed the capacity of ADT-030 to trigger apoptosis in KRAS mutant cells with minimal impact on BxPC3 RASWT cells. Cell cycle analysis using propidium iodide staining revealed that ADT-030 arrested cells in the G2/M phase. Other experiments showed that ADT-030 simultaneously suppressed both MAPK/AKT signaling and β-catenin transcriptional by inhibiting PDE10 and activating cGMP/PKG signaling. ADT-030 caused tumor regression in SC PDAC PDX mouse tumor models harboring either KRASG12D or KRASG12C mutations without discernable toxicity. Inhibition of orthotopic PDAC tumor growth by ADT-030 was dose-dependent, causing up to 80% reduction in tumor volume following a 4-week treatment period. In addition, ADT-030 significantly extended survival and yielded a high percentage of cures after stopping treatment in a murine model of KRAS- mutant lung cancer. CONCLUSION: ADT-030, novel dual pan-RAS/β-catenin inhibitor, showed strong and durable antitumor activity in clinically relevant and aggressive murine models of PDAC and lung cancer. ADT-030 is a promising development candidate for treatment of PDAC and other RAS-driven cancers, particularly given the complex KRAS mutation landscape of many cancers. Citation Format: Dhana Sekhar Reddy Bandi, Ganji P Nagaraju, Jeremy B Foote, Adam B Keeton, Xi Chen, Kristy L Berry, Yulia Y Maxuitenko, Upender Manne, Donald J Buchsbaum, Gary A Piazza, Bassel F El-Rayes. A novel pan-RAS/β-catenin inhibitor, ADT-030, produces tumor regression in PDX models of pancreatic cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr C025.

Abstract IA-05: Targeting KRAS for pancreatic cancer treatment

Abstract The approval of clinically effective inhibitors for KRAS G12C mutant non-small cell lung cancers in 2021 and 2022 marks a significant milestone in anti-KRAS oncogene drug discovery. This success has fueled intense efforts to develop inhibitors targeting additional KRAS mutations. However, primary and treatment-associated acquired resistance limit the depth and duration of efficacy of KRAS G12C selective and likely other KRAS inhibitors. Thus, a major challenge moving forward will be the elucidation of mechanisms of resistance to then guide development of effective combination anti-KRAS therapies. Recent studies have begun to identify mechanisms of acquired resistance, where most involve alterations in components in the RAS signaling network that then cause reactivation of KRAS effector signaling that bypass drug activity. Our studies have established the critical role of reactivation of the RAF-MEK-ERK mitogen activated protein kinase cascade, and the ERK target MYC, in driving resistance in KRAS-mutant pancreatic cancer. To fully understand how aberrant ERK and MYC activation overcomes KRAS inhibitor response, we have established a comprehensive molecular portrait of ERK- and MYC-dependent activities. We have also identified YAP/TAZ-TEAD activation as a mechanism of acquired resistance and have characterized KEAP1 loss as a mechanism of primary resistance. Together, these studies have identified drug combination strategies that enhance KRAS inhibitor activity. Progress in these and other studies will be presented. Citation Format: Channing J. Der. Targeting KRAS for pancreatic cancer treatment [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr IA-05.

Abstract IA-04: Targeting the oncogenic state of RAS with tri-complex inhibitors

Abstract KRAS oncogenic driver mutations occur in approximately 30% of all human cancers, and in particular, in over 90% of patients with pancreatic ductal adenocarcinoma (PDAC). Small molecule inhibitors that selectively target the inactive, GDP-bound state of KRAS G12C mutant proteins have demonstrated clinical efficacy in non-small cell lung cancer (NSCLC) as monotherapies, and in the small subset of PDAC patients that harbor this mutation. However, there are no currently approved RAS-targeted therapy options for the majority of patients with non-G12C RAS mutant PDAC. We have designed a series of tri-complex inhibitors that specifically target the GTP-bound, active state of RAS (RAS(ON)). These small molecule inhibitors bind non-covalently to an abundant intracellular protein, cyclophilin A (CypA). The resulting binary complex selectively engages RAS(ON), forming a tri-complex that sterically inhibits RAS interaction with downstream effectors. We have generated mutant-selective inhibitors that covalently engage RAS(ON) G12C (RMC-6291) or RAS(ON) G12D (RMC-9805). In addition, RMC-6236 is a RAS(ON) multi-selective inhibitor that non-covalently inhibits the active, GTP-bound state of mutant and wild-type variants of the canonical RAS isoforms (KRAS, NRAS, and HRAS). Here we will describe the mechanism of action of these investigational agents and the preclinical profiles that support their clinical evaluation in patients with PDAC as monotherapies and in combination therapy regimens with standard-of-care agents or as novel RAS(ON) inhibitor doublets. Citation Format: Mallika Singh. Targeting the oncogenic state of RAS with tri-complex inhibitors [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr IA-04.

Abstract IA-08: Syndecan 1 is a therapeutic target for KRAS-driven pancreatic cancer

Abstract KRAS inhibitors targeting G12C mutation have been approved by FDA for the treatment of non-small cell lung cancers and have shown promising clinical responses in pancreatic ductal adenocarcinoma (PDAC). RAS inhibitors targeting additional KRAS mutations or multiple RAS isoforms are under clinical development. Although targeting KRAS exhibits anti-tumor effect in PDAC, majority of tumors inevitably develop resistant disease, as is the case for most targeted therapies. In this new era of targeting KRAS driven cancer, understanding mechanisms driving this resistance to RAS targeted therapies and further devising combination strategies to overcome it have become a necessary, though challenging, task to achieve long term disease control. To tackle this problem, we employed various in vitro and in vivo preclinical model systems to explore the development of resistance to both genetic and pharmacological KRAS blockade. Our previous work identified the membrane proteoglycan Syndecan 1 (SDC1) as a KRAS downstream surrogate whose cell surface localization is tightly controlled by oncogenic KRAS signaling and is critical for KRAS-driven tumor development. Here, our analysis of KRAS driven genetically engineered PDAC mouse model and human pancreatic or colorectal cancer (CRC) cells with KRASG12C mutation discovered that, while cell surface SDC1 is reduced upon acute genetic or pharmacological inhibition of oncogenic KRAS, plasma membrane SDC1 is recovered in tumor cells that become resistant to KRAS inhibition (KRAS-bypass cells). Surface localization of SDC1 leads to the activation of multiple receptor tyrosine kinases (RTKs) and macropinocytosis, resulting in the resistance to KRAS blockade. We further identified that the recovery of plasma membrane SDC1 in KRAS-bypass cells is driven by YAP1 oncogene, which induces the downregulation of ARF6 GAPs, leading to the activation of ARF6, a small GTPase required for SDC1 membrane recycling. To therapeutically targeting SDC1, we have successfully developed a monoclonal antibody (22B mAb), which exhibits remarkable sensitivity and specificity for human SDC1. Our results indicate that 22B mAb exerts substantial inhibition of PDAC cell growth in vitro and desirable tumor inhibitory effects in vivo in murine PDAC tumors and human PDAC cell-derived xenograft tumors. Importantly, our 22B mAb synergizes with KRAS inhibitors, chemotherapy, or immunotherapy, resulting in significantly enhanced therapeutic effects. Taken together, our study identified SDC1 as a functional driver for the bypass of KRAS-dependence and therapeutically targeting SDC1 with a novel mAb will overcome the acquired resistance to KRAS targeted therapy. As such, our research yields important new insights in the fields of cancer biology regarding mechanisms of resistance employed by human cancers, and identifies new actionable therapeutic targets and approaches to overcome resistance to KRAS inhibition. Citation Format: Mitsunobu Takeda, Zecheng Yang, Madeline S Theardy, Alexey Sorokin, Oluwadara Coker, Shuaitong Chen, Long T Vien, Laura Bover, Haoqiang Ying, Scott Kopetz, Wantong Yao. Syndecan 1 is a therapeutic target for KRAS-driven pancreatic cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr IA-08.