Abstract 582: Oncogenic PIK3CA fortifies immune determinants in vascular cancers

Abstract

Abstract Angiosarcomas are a group of vascular cancers that form malignant blood vessels. These malignancies are seemingly inflamed primarily due to their pathognomonic nature, which consists of irregular endothelium and tortuous blood channels. The malignant vascular spaces host a variety of blood and immune components, where a controlled scavenging system is necessary for tumor maintenance. Oncogenes may convey molecular signals to foster the tumor immune niche, and PIK3CA mutations that induce continuous activation of the PI3K pathway occur in a subset of angiosarcomas. Despite the undoubtedly oncogenic properties of PIK3CA mutations, the mechanistic role of these mutations - particularly the potential for controlling the hemato-endothelial system in angiosarcomas - remains undetermined. In this study, we demonstrate the functional consequences of oncogenic PIK3CA and its molecular properties in angiosarcoma cells. We created isogenic cell clones from two angiosarcoma cell lines engineered to harbor hotspot mutations in PIK3CA using CRISPR/Cas9: two homozygous PIK3CA H1047R cell clones (C8 and C35) and one wild-type (WT) clone were generated from DHSA-1426 angiosarcoma cells; and one homozygous mutant clone was created from COSB cells. We found that PIK3CA mutant cells constitutively activated the PI3K/AKT/mTOR pathway at a greater level than that of WT cells. Bulk- and single cell(sc)-RNA-seq data revealed that mutant cells enriched gene sets associated with PI3K signaling and other oncogenic pathways including KRAS, MAPK, and TGF-beta. Also, mutant cells significantly increased cytokines regulating immune cell migration and chemotaxis such as IL-8 and MCP-1. In addition to the common features, we identified functional and molecular divergence between mutant clones. Noticeable changes in cellular morphology, growth kinetics, and tube-forming capacity were observed between two mutant clones. C35 mutant cells were more sensitive to both pan-PI3K and PI3K-alpha specific inhibitor, and DNA damage was greater than in the C8 clone. C35 cells enhanced activation of IL-6/STAT3 signaling compared to C8, despite the increment of the aforementioned immune cytokines in both mutants. Moreover, our comprehensive analysis of bulk- and sc-RNA-seq, ATAC-seq, and metabolomics data identified molecular signatures associated with metabolic vulnerabilities of C35 cells. In summary, we demonstrate that oncogenic PIK3CA perpetuates PI3K signaling activation and reinforces a supply for immune signaling. Furthermore, our data suggest that PIK3CA mutations contribute to establishing cellular heterogeneity that reveals a spectrum of vascular, immunogenic, and metabolic activities. Our ongoing work involves developing an experimental model of angiosarcoma using induced pluripotent stem cells to examine if oncogenic PIK3CA controls immune determinants during malignant endothelial transformation. Citation Format: Donghee Lee, Emma Kozurek, Md Abdullah, Rong Li, Erin B. Dickerson, Jong Hyuk Kim. Oncogenic PIK3CA fortifies immune determinants in vascular cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 582.