Abstract
PURPOSE: Despite decreased esophageal carcinoma incidence, its prognosis remains challenging. We aimed to develop a multimodal prognostic model to optimize treatment strategies and elucidate biological mechanisms of key regulatory genes. METHODS: Pivotal prognostic genes were screened using integrated bioinformatics and immunohistochemistry. A multimodal model combining PET/CT radiomics (metabolic tumor volume, SUV), clinicopathological parameters (lymph node metastasis, differentiation grade, infiltration depth), and molecular biomarkers was established and validated. Functional experiments and co-immunoprecipitation/transcriptomic sequencing explored biological roles and molecular networks. RESULTS: CASQ2 emerged as a key prognostic gene. The validated model integrated CASQ2 expression, radiomic features (MTV/SUV), and clinical staging, demonstrating high predictive accuracy. Functional assays confirmed that CASQ2 overexpression enhanced esophageal cancer cell proliferation and invasion. Mechanistically, CASQ2 activated AKT/PI3K signaling and disrupted calcium homeostasis, with protein interaction and transcriptomic analyses delineating its regulatory network. CONCLUSION: We established a multimodal prognostic model incorporating molecular, radiomic, and clinical parameters, and identified CASQ2 as a critical regulator of esophageal carcinogenesis. CASQ2 likely drives tumor progression through AKT/PI3K signaling and calcium pathway dysregulation, offering dual therapeutic targets. This integrative approach advances personalized prognosis prediction and mechanistic understanding.