Gyau Benjamin B, Wang Junyan, Wu Weiguo, Scull Brooks, Major Angela M, Jin Weidong, Cates Justin M M, Hicks John, Man Tsz-Kwong
Section of Hematology and Oncology, Department of Pediatrics, Baylor College of Medicine, Houston, TX 77030, USA.
Texas Children's Cancer and Hematology Center, Houston, TX 77030, USA.
Cancers (Basel). 2025 Aug 26;17(17):2780. doi: 10.3390/cancers17172780.
Metastasis continues to be a leading cause of mortality in osteosarcoma (OS) among pediatric and young adult populations, with few effective therapeutic options available. Despite immunotherapy advancements, its efficacy in OS is hindered by an incomplete understanding of the immunosuppressive tumor microenvironment (TME). We utilized multiplex imaging mass cytometry and phenoplexing to characterize immune and stromal cell populations within the TME of a tissue microarray comprising 51 primary OS tumors. The prognostic significance of TME cell abundance and spatial cell-cell distance was evaluated using Kaplan-Meier and Cox regression analyses. To investigate macrophage functionality in vivo, we employed orthotopic xenograft mouse models by co-injecting THP-1-derived M0 or M2 macrophages with 143B OS cells to assess their impact on tumor growth and pulmonary metastasis. Mechanisms of macrophage-mediated metastasis were explored using Luminex, ELISA, and transwell migration assays. Our results showed that macrophages dominated the TME, with M0 and M2 subtypes significantly outnumbering M1 macrophages (M1) and other myeloid cells. T cells and myeloid-derived suppressor cells (MDSC) were the second and third most abundant immune populations, respectively. Among stromal cells, endothelial cells predominated over fibroblasts. While individual immunosuppressive cell populations (M2, MDSC, and Treg) showed no direct correlation with clinical outcomes, the collective abundance of M2 and MDSC was significantly associated with reduced metastasis-free survival (MFS, = 0.0244) and recurrence-free survival (RFS, = 0.0040). Notably, closer spatial proximity between M2 macrophages and immunosuppressive cells ( = 0.0248) or Ki-67 cells ( = 0.0321) correlated with decreased MFS, suggesting the formation of an M2-centric immunosuppressive and pro-tumor hub. In vivo, co-injection of M2 macrophages with 143B cells significantly enhanced pulmonary metastasis ( = 0.0140). Luminex analysis identified M2-derived MIP-1α (CCL3) as a candidate chemokine driving OS cell metastatic potential. This study provides a high-resolution map of the OS TME, highlighting the prognostic significance of M2 and immunosuppressive cell interactions in driving metastasis, potentially through MIP-1α signaling. These findings establish a foundation for developing targeted immunotherapies to improve outcomes in metastatic OS.
在儿童和年轻成人人群中,转移仍然是骨肉瘤(OS)死亡的主要原因,有效的治疗选择很少。尽管免疫疗法取得了进展,但其在骨肉瘤中的疗效因对免疫抑制性肿瘤微环境(TME)的不完全了解而受到阻碍。我们利用多重成像质谱流式细胞术和表型分析来表征包含51个原发性骨肉瘤肿瘤的组织微阵列的TME内的免疫和基质细胞群体。使用Kaplan-Meier和Cox回归分析评估TME细胞丰度和空间细胞间距离的预后意义。为了研究体内巨噬细胞的功能,我们通过将THP-1来源的M0或M2巨噬细胞与143B骨肉瘤细胞共同注射来建立原位异种移植小鼠模型,以评估它们对肿瘤生长和肺转移的影响。使用Luminex、ELISA和Transwell迁移试验探索巨噬细胞介导转移的机制。我们的结果表明,巨噬细胞在TME中占主导地位,M0和M2亚型明显多于M1巨噬细胞(M1)和其他髓系细胞。T细胞和髓系来源的抑制性细胞(MDSC)分别是第二和第三丰富的免疫群体。在基质细胞中,内皮细胞比成纤维细胞占优势。虽然单个免疫抑制细胞群体(M2、MDSC和调节性T细胞)与临床结果没有直接相关性,但M2和MDSC的总体丰度与无转移生存期(MFS,P = 0.0244)和无复发生存期(RFS,P = 0.0040)的降低显著相关。值得注意的是,M2巨噬细胞与免疫抑制细胞(P = 0.0248)或Ki-67细胞(P = 0.0321)之间更近的空间距离与MFS降低相关,表明形成了以M2为中心的免疫抑制和促肿瘤中心。在体内,将M2巨噬细胞与143B细胞共同注射显著增强了肺转移(P = 0.0140)。Luminex分析确定M2来源的MIP-1α(CCL3)是驱动骨肉瘤细胞转移潜能的候选趋化因子。这项研究提供了骨肉瘤TME的高分辨率图谱,突出了M2和免疫抑制细胞相互作用在驱动转移中的预后意义,可能是通过MIP-1α信号传导。这些发现为开发靶向免疫疗法以改善转移性骨肉瘤的治疗结果奠定了基础。
