Disrupting PDGFRA-Driven Immune Evasion in Glioma: Vaccine-Based Strategies on the Horizon

Xialin Zhang¹Xinwei Li¹Ran Cui²Xinlin Yu³Zihan Zhang¹Zhongxiang Luo¹Gang Chen¹Sheng Lin^1*

• ¹The Affiliated Hospital of Southwest Medical University, Luzhou, China
• ²The First People's Hospital of Neijiang, Neijiang, China
• ³Affiliated Hospital of Chengdu University, Chengdu, China

Gliomas, the most aggressive primary brain tumors, present a formidable challenge in neuro-oncology, characterized by infiltrative growth, high recurrence rates, and a profoundly immunosuppressive microenvironment that severely limits the efficacy of current treatments. Platelet-derived growth factor receptor alpha (PDGFRA) has emerged as a pivotal oncogenic driver in gliomas, not only promoting cellular proliferation and angiogenesis but critically orchestrating complex immune evasion mechanisms. Understanding how PDGFRA shapes this immunosuppressive landscape is paramount for developing effective immunotherapies, especially given the minimal response rates of gliomas to conventional checkpoint inhibitors. PDGFRA signaling actively remodels the glioma microenvironment, contributing to vascular abnormalities (e.g., via the PDGFRA-Endocan-MYC axis), metabolic reprogramming that impairs T cell function, and immune cell polarization, all of which restrict anti-tumor immunity. Crucially, vaccine-based therapeutic modalities targeting PDGFRA offer a compelling dual strategy: they hold the potential to suppress tumor proliferation while simultaneously reversing immune evasion mechanisms. This positions PDGFRA-targeted vaccines as a significant innovation on the horizon for glioma immunotherapy. Addressing substantial translational hurdles, including blood-brain barrier impermeability, inherent tumor heterogeneity, and the pervasive immunosuppressive milieu, is essential for clinical success. Future clinical translation will require the integration of multi-omics to identify immunogenic neoantigens, the implementation of advanced nanodelivery systems for optimized vaccine distribution and efficacy, and synergistic combinations with immune checkpoint inhibitors to overcome resistance. By dissecting the intricate PDGFRA-mediated signaling network, we highlight critical targets and outline strategies for developing precision-oriented, individualized immunotherapeutic interventions, aiming to significantly improve outcomes for patients with gliomas.