Eisemann Tanja, Costa Barbara, Peterziel Heike, Angel Peter
Division of Signal Transduction and Growth Control, DKFZ/ZMBH Alliance, Heidelberg, Germany.
Faculty of Biosciences, University Heidelberg, Heidelberg, Germany.
Front Oncol. 2019 Mar 26;9:187. doi: 10.3389/fonc.2019.00187. eCollection 2019.
The dynamic and interactive tumor microenvironment is conceived as a considerable parameter in tumor development and therapy response. Implementing this knowledge in the development of future cancer treatments could provide novel options in the combat of highly aggressive and difficult-to-treat tumors such as gliomas. One compartment of the tumor microenvironment that has gained growing interest is the immune system. As endogenous defense machinery the immune system has the capacity to fight against cancer cells. This, however, is frequently circumvented by tumor cells engaging immune-regulatory mechanisms that disable tumor-directed immune responses. Thus, in order to unlock the immune system against cancer cells, it is crucial to characterize in great detail individual tumor-associated immune cell subpopulations and dissect whether and how they influence immune evasion. In this study we investigated the function of a tumor-associated myeloid cell subpopulation characterized by podoplanin expression on the development of high-grade glioma tumors. Here, we show that the deletion of podoplanin in myeloid cells results in increased (CD8) T-cell infiltrates and significantly prolonged survival in an orthotopic transplantation model. co-cultivation experiments indicate a podoplanin-dependent transcriptional regulation of arginase-1, a well-known player in myeloid cell-mediated immune suppression. These findings identify podoplanin positive myeloid cells as one novel mediator of the glioma-induced immune suppression. Thus, the targeted ablation of podoplanin positive myeloid cells could be included in combinatorial cancer therapies to enhance immune-mediated tumor elimination.
动态且相互作用的肿瘤微环境被认为是肿瘤发展和治疗反应中的一个重要参数。将这一认识应用于未来癌症治疗的开发中,可能为对抗高度侵袭性且难以治疗的肿瘤(如神经胶质瘤)提供新的选择。肿瘤微环境中一个越来越受关注的部分是免疫系统。作为内源性防御机制,免疫系统有能力对抗癌细胞。然而,肿瘤细胞经常通过参与免疫调节机制来规避这一点,这些机制会使针对肿瘤的免疫反应失效。因此,为了激活免疫系统对抗癌细胞,详细表征各个肿瘤相关免疫细胞亚群并剖析它们是否以及如何影响免疫逃逸至关重要。在这项研究中,我们调查了以血小板反应蛋白-1表达为特征的肿瘤相关髓样细胞亚群在高级别神经胶质瘤肿瘤发展中的作用。在此,我们表明,在髓样细胞中缺失血小板反应蛋白-1会导致(CD8)T细胞浸润增加,并在原位移植模型中显著延长生存期。共培养实验表明,精氨酸酶-1的转录调控依赖于血小板反应蛋白-1,精氨酸酶-1是髓样细胞介导的免疫抑制中一个众所周知的参与者。这些发现确定了血小板反应蛋白-1阳性髓样细胞是神经胶质瘤诱导的免疫抑制的一种新介质。因此,靶向清除血小板反应蛋白-1阳性髓样细胞可纳入联合癌症治疗中,以增强免疫介导的肿瘤清除。
