J. Crayton Pruitt Department of Biomedical Engineering, University of Florida, Biomedical Sciences Building JG-56, 1275 Center Drive, Gainesville, Florida 32611-6131, United States.
Department of Immunology, Moffitt Cancer Center MRC 4E, 12902 Magnolia Drive, Tampa, Florida 33612-9497, United States.
ACS Biomater Sci Eng. 2020 Jul 13;6(7):4179-4199. doi: 10.1021/acsbiomaterials.0c00259. Epub 2020 Jun 24.
A critical hurdle associated with natural killer (NK) cell immunotherapies is inadequate infiltration and function in the solid tumor microenvironment. Well-controlled 3D culture systems could advance our understanding of the role of various biophysical and biochemical cues that impact NK cell migration in solid tumors. The objectives of this study were to establish a biomaterial which (i) supports NK cell migration and (ii) recapitulates features of the in vivo solid tumor microenvironment, to study NK infiltration and function in a 3D system. Using peptide-functionalized poly(ethylene glycol)-based hydrogels, the extent of NK-92 cell migration was observed to be largely dependent on the density of integrin binding sites and the presence of matrix metalloproteinase degradable sites. When lung cancer cells were encapsulated into the hydrogels to create tumor microenvironments, the extent of NK-92 cell migration and functional activity was dependent on the cancer cell type and duration of 3D culture. NK-92 cells showed greater migration into the models consisting of nonmetastatic A549 cells relative to metastatic H1299 cells, and reduced migration in both models when cancer cells were cultured for 7 days versus 1 day. In addition, the production of NK cell-related pro-inflammatory cytokines and chemokines was reduced in H1299 models relative to A549 models. These differences in NK-92 cell migration and cytokine/chemokine production corresponded to differences in the production of various immunomodulatory molecules by the different cancer cells, namely, the H1299 models showed increased stress ligand shedding and immunosuppressive cytokine production, particularly TGF-β. Indeed, inhibition of TGF-β receptor I in NK-92 cells restored their infiltration in H1299 models to levels similar to that in A549 models and increased overall infiltration in both models. Relative to conventional 2D cocultures, NK-92 cell mediated cytotoxicity was reduced in the 3D tumor models, suggesting the hydrogel serves to mimic some features of the biophysical barriers in in vivo tumor microenvironments. This study demonstrates the feasibility of a synthetic hydrogel system for investigating the biophysical and biochemical cues impacting NK cell infiltration and NK cell-cancer cell interactions in the solid tumor microenvironment.
与自然杀伤 (NK) 细胞免疫疗法相关的一个关键障碍是 NK 细胞在实体瘤微环境中的浸润和功能不足。良好控制的 3D 培养系统可以增进我们对各种生物物理和生化线索的理解,这些线索影响 NK 细胞在实体瘤中的迁移。本研究的目的是建立一种生物材料,(i) 支持 NK 细胞的迁移,(ii) 再现体内实体瘤微环境的特征,以研究 NK 细胞在 3D 系统中的浸润和功能。使用肽功能化的基于聚乙二醇的水凝胶,观察到 NK-92 细胞的迁移程度在很大程度上取决于整合素结合位点的密度和基质金属蛋白酶可降解位点的存在。当将肺癌细胞包封到水凝胶中以创建肿瘤微环境时,NK-92 细胞的迁移和功能活性程度取决于癌细胞类型和 3D 培养的时间。与转移性 H1299 细胞相比,NK-92 细胞更倾向于迁移到由非转移性 A549 细胞组成的模型中,并且当癌细胞培养 7 天而不是 1 天时,两种模型中的迁移都减少。此外,与 A549 模型相比,H1299 模型中 NK 细胞相关促炎细胞因子和趋化因子的产生减少。NK-92 细胞迁移和细胞因子/趋化因子产生的这些差异对应于不同癌细胞产生的各种免疫调节分子的差异,即 H1299 模型显示应激配体脱落和免疫抑制细胞因子产生增加,特别是 TGF-β。事实上,在 NK-92 细胞中抑制 TGF-β受体 I 恢复了它们在 H1299 模型中的浸润水平,使其与 A549 模型相似,并增加了两种模型中的整体浸润。与传统的 2D 共培养相比,NK-92 细胞介导的细胞毒性在 3D 肿瘤模型中降低,这表明水凝胶可模拟体内肿瘤微环境中生物物理屏障的某些特征。本研究证明了合成水凝胶系统用于研究影响 NK 细胞浸润和 NK 细胞-癌细胞相互作用的生物物理和生化线索在实体瘤微环境中的可行性。
