Notch1 mutation drives clonal expansion in normal esophageal epithelium but impairs tumor growth

NOTCH1 mutant clones occupy the majority of normal human esophagus by middle age, but are comparatively rare in esophageal cancers, suggesting NOTCH1 mutations may promote clonal expansion but impede carcinogenesis. Here we test this hypothesis. Visualizing and sequencing NOTCH1 mutant clones in aging normal human esophagus reveals frequent biallelic mutations that block NOTCH1 signaling. In mouse esophagus, heterozygous Notch1 mutation confers a competitive advantage over wild type cells, an effect enhanced by loss of the second allele. Notch1 loss alters transcription but has minimal effects on epithelial structure and cell dynamics. In a carcinogenesis model, Notch1 mutations were less prevalent in tumors than normal epithelium. Deletion of Notch1 reduced tumor growth, an effect recapitulated by anti-NOTCH1 antibody treatment. We conclude that Notch1 mutations in normal epithelium are beneficial as wild type Notch1 promotes tumor expansion. NOTCH1 blockade may have therapeutic potential in preventing esophageal squamous cancer.

Comprehensive genomic profiling and immune characterization of adenoid cystic carcinoma.

e18050 Background: Adenoid cystic carcinoma (ACC) is a rare malignancy of glandular tissue with a high rate of local recurrence and metastatic disease for which clinical behavior varies widely. Currently, no standard therapy exists, and available therapies have low response rates. Therefore, prognostic biomarkers to determine optimal treatment strategies are urgently needed. Here we investigate the molecular landscape and therapeutic targets of ACC. Methods: ACC samples were analyzed using next generation sequencing (NGS) (NextSeq, 592 gene panel) or whole exome sequencing (NovaSeq) (Caris Life Sciences, Phoenix, AZ). Pathogenic fusion events were detected using whole transcriptome sequencing (NovaSeq). Statistical significance was determined using the Chi-square test and adjusted for multiple comparisons. Tumor infiltrating Immune cell fractions were determined using the QuanTIseq deconvolution algorithm and WTS data. Results: 327 ACC patients were identified, median age of 58 years, 62% female and 62% metastatic disease. The most frequent mutations (excluding indeterminate results) involved genes in the NOTCH pathway ( NOTCH1 16% [41 of 298 cases]), chromatin remodeling ( ARID1A 24.3% [27 of 138 cases], KDM6A 12.5% [28 of 224 cases], KMT2C 10.7% [21 of 197 cases]) and TP53 10.2% (25 of 246 cases). Chromatin remodeling genes were co-mutated with NOTCH1. NOTCH1 mutations were found in 41 cases, 18 primary and 23 metastatic were associated with reduced median overall survival (mOS 1.8 years vs 3.8 years, p = 0.01). Mutations were most frequent in the PEST (n = 35), NRR (n = 18), PEST+NRR (n = 16) and EGF-like domains (n = 11). PEST domain mutations were found exclusively in ACC originating from the head and neck (H&N). GSEA showed that MYC, E2F and G2M target pathways were enriched in NOTCH1 mutated ACC regardless of the presence of MYB fusions. All three pathways were enriched in PEST domain mutations whereas only MYC targets were enriched in NRR and NRR+PEST domain mutations indicating that PEST domain mutations drive transcriptomic changes in NOTCH1 mutated ACC. MYC gene expression was significantly upregulated in NOTCH1 mutated ACC. Fusion events were detected in 45% (104/231). MYB:NFIB was the most common fusion (40%) and was more frequent in H&N origin than other sites. There was no difference in the mOS between MYB fusion positive and negative ACC (4.4 years vs 5.5 years, p = 0.14). M2-polarized macrophages, myeloid dendritic cells and neutrophils were significantly higher in metastatic compared to primary ACC while NK cells were more abundant in primary tumor. Conclusions: ACC is a genetically heterogenous disease with an immune-excluded microenvironment. NOTCH1 mutations were associated with worse, while MYB:NFIB fusion was not associated with prognosis. Our study shows that M2 macrophages and MYC are potential novel therapeutic targets in ACC.

Molecular profiling and survival outcomes of p16+ compared to p16- oropharynx squamous cell cancer patients.

e18026 Background: Previous studies have consistently shown that p16+ oropharynx squamous cell cancer (OPSCC) patients have better outcomes. The significance of molecular and transcriptional signatures and its correlation with p16 expression remains unclear. Methods: We queried the Caris Life Sciences database to assess the molecular and transcriptional signatures related to p16+ and p16- head and neck squamous cell cancer (HNSCC) patients. Comprehensive molecular profiling including whole exome sequencing (WES), targeted Next-Generation Sequencing (NGS), and immunohistochemistry (IHC) 22c3 for PD-L1 was performed (CPS ≥1 considered positive) (Caris Life Sciences, Phoenix, AZ). Tumor mutational burden (TMB) was calculated based on somatic nonsynonymous missense mutations. A standard cut-off of 2+, > 70% p16 staining was used. HPV16/18 was tested using WES. Patients were considered smokers if they had > 15 pack-years. Real world overall survival (rwOS) was obtained from insurance claims data and Kaplan-Meier estimates were calculated from the date of start of treatment to the date of last contact. Results: 948 cases of OPSCC were identified in the Caris database. 41% (82/199) were smokers. Where p16 and HPV data was available, 41% were p16+ (171/420) while HPV positivity rate was 52% (71/148). We noted a small number of patients with discordant p16 and HPV status (7 p16+/HPV-, 8 p16-/HPV+) in 327 patients who had HPV status available. Most common mutations were TP53 (33%), PIK3CA (17%) and KMT2D (10.6%). 87% were PD-L1 positive (342/394), with high expression in both p16+ and p16- subgroups, 90% and 85% respectively. 10% had TMB≥10/Mb (48/463). TP53 mutations were more common in p16- (49%) tumors in contrast to p16+ (10%) (p < 0.0005), while no statistical difference was detected in TMB≥10/Mb between the groups. CDKN2A, TERT and NOTCH1 mutations were more prevalent in tumors that were p16- or HPV- in contrast to tumors that were p16+ or HPV+ (p < 0.05). FGF3, CCND1, FGF4, FGF19 copy number alterations (CNA) were less common in p16+ OPSCC compared to p16- or HPV16- OPSCC (p < 0.0005). P16+ patients had longer rwOS when compared to p16-, 47 months versus 20 months (HR = 0.55, p = 0.014) respectively. Conclusions: Higher frequency of CDKN2A, TERT and NOTCH1 mutations among p16- (versus p16+) raise the possibility of potential targets for treatment in this group with poor prognosis. However, it remains unclear if these can serve as independent predictors of survival.[Table: see text]

NOTCH1 Signaling in Head and Neck Squamous Cell Carcinoma

Biomarker-driven targeted therapies are lacking for head and neck squamous cell carcinoma (HNSCC), which is common and lethal. Efforts to develop such therapies are hindered by a genomic landscape dominated by the loss of tumor suppressor function, including NOTCH1 that is frequently mutated in HNSCC. Clearer understanding of NOTCH1 signaling in HNSCCs is crucial to clinically targeting this pathway. Structural characterization of NOTCH1 mutations in HNSCC demonstrates that most are predicted to cause loss of function, in agreement with NOTCH1’s role as a tumor suppressor in this cancer. Experimental manipulation of NOTCH1 signaling in HNSCC cell lines harboring either mutant or wild-type NOTCH1 further supports a tumor suppressor function. Additionally, the loss of NOTCH1 signaling can drive HNSCC tumorigenesis and clinical aggressiveness. Our recent data suggest that NOTCH1 controls genes involved in early differentiation that could have different phenotypic consequences depending on the cancer’s genetic background, including acquisition of pseudo-stem cell-like properties. The presence of NOTCH1 mutations may predict response to treatment with an immune checkpoint or phosphatidylinositol 3-kinase inhibitors. The latter is being tested in a clinical trial, and if validated, it may lead to the development of the first biomarker-driven targeted therapy for HNSCC.

Activating NOTCH1 Mutations Alter T-ALL Chemosensitivity By PREX2-AKT Pathway

Mutations on NOTCH1 gene are the most commonly found mutations in T-cell acute lymphoblastic leukemia (T-ALL) and they are reported to be favorable indicators for T-ALL patients' prognosis. However, the effects of activating NOTCH1 mutations on T-ALL's chemosensitivity have not been studied. We reported that NOTCH1 inhibition by γ-secretase inhibitors or shRNA knockdown in MOLT-3 cells could reduce the T-ALL cells' sensitivity to chemotherapeutic drugs. However, this effect was absent in Jurkat and CUTLL cells. We further demonstrated that NOTCH1 inhibition could activate the PI3K-AKT pathway in a cell specific pattern similar as their effects on chemosensitivity. RNA-seq revealed that Phosphatidylinositol-3,4,5-Trisphosphate Dependent Rac Exchange Factor 2 (PREX2) is a target gene of NOTCH1 and may mediate the effects of activating NOTCH1 mutations on chemosensitivity. Consistently, we proved that overexpression of PREX2 could mimic the effects of NOTCH1 inhibition on chemosensitivity. Our study has highlighted the effects of activating NOTCH1 mutations on T-ALL's chemosensitivity by altering PREX2-AKT pathway, which may explain the favorable effects of NOTCH1 mutations on T-ALL patients' prognosis, as well as provided potential targets to alter T-ALL cells' chemosensitivity. Disclosures No relevant conflicts of interest to declare.

A Molecular Test for Quantifying Functional Notch Signaling Pathway Activity in Human Cancer

Background: The Notch signal transduction pathway is pivotal for various physiological processes, including immune responses, and has been implicated in the pathogenesis of many diseases. The effectiveness of various targeted Notch pathway inhibitors may vary due to variabilities in Notch pathway activity among individual patients. The quantitative measurement of Notch pathway activity is therefore essential to identify patients who could benefit from targeted treatment. Methods: We here describe a new assay that infers a quantitative Notch pathway activity score from the mRNA levels of generally conserved direct NOTCH target genes. Following the calibration and biological validation of our Notch pathway activity model over a wide spectrum of human cancer types, we assessed Notch pathway activity in a cohort of T-ALL patient samples and related it to biological and clinical parameters, including outcome. Results: We developed an assay using 18 select direct target genes and high-grade serous ovarian cancer for calibration. For validation, seven independent human datasets (mostly cancer series) were used to quantify Notch activity in agreement with expectations. For T-ALL, the median Notch pathway activity was highest for samples with strong NOTCH1-activating mutations, and T-ALL patients of the TLX subtype generally had the highest levels of Notch pathway activity. We observed a significant relationship between ICN1 levels and the absence/presence of NOTCH1-activating mutations with Notch pathway activity scores. Patients with the lowest Notch activity scores had the shortest event-free survival compared to other patients. Conclusions: High Notch pathway activity was not limited to T-ALL samples harboring strong NOTCH1 mutations, including juxtamembrane domain mutations or hetero-dimerization combined with PEST-domain or FBXW7 mutations, indicating that additional mechanisms may activate Notch signaling. The measured Notch pathway activity was related to intracellular NOTCH levels, indicating that the pathway activity score more accurately reflects Notch pathway activity than when it is predicted on the basis of NOTCH1 mutations. Importantly, patients with low Notch pathway activity had a significantly shorter event-free survival compared to patients showing higher activity.