近墨者黑！华人团队Cancer Cell封面论文，揭示免疫治疗后癌症复发的新机制

Core Viewpoint - The article discusses the complex interactions between cancer cells and the tumor microenvironment (TME), emphasizing the potential of targeted cancer immunotherapies to disrupt immunosuppressive interactions, although many therapies show limited durability due to a lack of understanding of these interactions [2][3]. Group 1: Research Findings - A study published by a team from the University of Chicago reveals that tumor-initiating stem cells (tSC) regulate the plasticity of neutrophils through metabolic reprogramming, creating a protective niche that allows them to survive cancer immunotherapy, leading to cancer recurrence [4]. - The research indicates that targeting the SOX2-FADS1-PGE2 signaling axis could serve as a novel combination therapy strategy to prevent immunotherapy resistance and tumor recurrence [4]. Group 2: Mechanisms of Immune Evasion - The study highlights the heterogeneity of tumor-associated neutrophils (TAN) and how different states of TAN arise and evolve, impacting the effectiveness of cancer immunotherapy [8]. - It was found that anti-PDL1 + CD40 agonist immunotherapy can induce TAN to regain anti-tumor activity in squamous cell carcinoma (SCC), while TAN at the tumor-stroma interface maintain their immunosuppressive state [8]. Group 3: Key Pathways and Implications - The SOX2 high-expressing tSCs enhance PGE2 signaling in TAN, which may disrupt interferon responses and inhibit the anti-tumor functions of TAN [9]. - Specific knockout of PGE2 receptors in neutrophils or using COX-2 inhibitors to block PGE2 synthesis can effectively restore the anti-tumor functions of neutrophils, enhancing the efficacy of immunotherapy and significantly reducing tumor recurrence rates [9]. Group 4: Overall Conclusions - The research explores how effective immunotherapies influence the plasticity of TAN, revealing how tSCs evade TAN-mediated anti-tumor immunity, allowing them to survive cancer immunotherapy and promote recurrence [12].