Wichroski Michael, Liu Si-Qi, Zasadil Lauren M, Benci Joseph L, Gedeon Patrick C, Condon Kendall J, Joshi Suhasini, Posy Shana, Carlson Patrick, Maier Alison, Shen Jiao, Kureshi Rakeeb, Amako Yuka, Wang Tai, Powles Ryan L, Li Yanyun, Lai Tho, Katsyv Igor, Qiu Hongchen, Qi Huilin, Wong Jessica, Zhao Dandan, Banas Dana, Onorato Joelle, Locke Gregory, Chen Xueer, Chou Wen-Chi, Cook Erica, Witt Abigail E, Barbieri Christopher M, Zhang Hong, Olsen Jonathan B, Font Tello Alba, Drokhlyansky Eugene, Grünenfelder Denise C, Chupak Louis, Longmire Tyler A, Jones Jon C, Hollmann Travis J, Kugler David G, Feder John N, Bueno Raphael, Wain John, Sivakumar Pallavur, Liu Yu, Dougan Stephanie K, Paweletz Cloud P, Barbie David A, Lees Emma
Research and Development, Bristol Myers Squibb Company, Cambridge, Massachusetts.
Department of Medical Oncology, Dana-Farber Cancer Institute, Boston, Massachusetts.
Cancer Immunol Res. 2025 Sep 2;13(9):1342-1362. doi: 10.1158/2326-6066.CIR-25-0156.
Diacylglycerol kinase α (DGKα) and DGKζ are lipid kinases that negatively regulate T-cell signaling through diacylglycerol metabolism, making them attractive targets for next-generation immunotherapy. In this study, we report the discovery and preclinical characterization of the clinical-stage DGKα and DGKζ lipid kinase inhibitor, BMS-986408. BMS-986408 binds to the accessory subdomain of the catalytic domain and inhibits DGKα/ζ through a mechanism of action that includes competitive inhibition for the diacylglycerol substrate, subcellular translocation to the plasma membrane, and proteosome-dependent degradation. DGKα/ζ inhibition markedly improved the therapeutic benefit of PD-1 therapy by unleashing T-cell responses in the tumor while also amplifying the priming and expansion of tumor-reactive T cells in tumor-draining lymph nodes. Simultaneous inhibition of both DGKα and DGKζ was required to maximize combination benefit with PD-1 therapy. Furthermore, we observed in non-small cell lung cancer (NSCLC) patient samples that DGKα and DGKζ were broadly expressed in tumor-infiltrated T cells and that combination therapy invigorated a robust cytokine response in organotypic tumors derived from patients with NSCLC, supporting the clinical evaluation of this combination in patients with NSCLC. BMS-986408 also markedly improved CD19-targeted CAR T-cell therapy efficacy by overcoming hypofunctionality, insufficient expansion, and lack of costimulatory ligands. BMS-986408 represents a critical step toward evaluating the broad immunotherapy potential of DGKα/ζ inhibitors in patients with cancer.
二酰甘油激酶α(DGKα)和DGKζ是脂质激酶,可通过二酰甘油代谢对T细胞信号传导进行负调控,使其成为下一代免疫疗法的有吸引力的靶点。在本研究中,我们报告了临床阶段的DGKα和DGKζ脂质激酶抑制剂BMS-986408的发现和临床前特征。BMS-986408与催化结构域的辅助亚结构域结合,并通过包括对二酰甘油底物的竞争性抑制、亚细胞转位至质膜以及蛋白酶体依赖性降解的作用机制抑制DGKα/ζ。DGKα/ζ抑制通过释放肿瘤中的T细胞反应,同时放大肿瘤引流淋巴结中肿瘤反应性T细胞的启动和扩增,显著提高了PD-1治疗的疗效。同时抑制DGKα和DGKζ是实现与PD-1治疗联合获益最大化所必需的。此外,我们在非小细胞肺癌(NSCLC)患者样本中观察到,DGKα和DGKζ在肿瘤浸润性T细胞中广泛表达,并且联合治疗在源自NSCLC患者的器官样肿瘤中激发了强大的细胞因子反应,支持在NSCLC患者中对这种联合疗法进行临床评估。BMS-986408还通过克服功能减退、扩增不足和缺乏共刺激配体,显著提高了靶向CD19的嵌合抗原受体T细胞(CAR T)疗法的疗效。BMS-986408代表了评估DGKα/ζ抑制剂在癌症患者中广泛免疫治疗潜力的关键一步。
