Polyethylene Glycol-Based Hydrogel as a 3D Extracellular Matrix Mimic for Cytotoxic T Lymphocytes.

M A Kristine Tolentino, Mir Hadi Seyedzadeh, Newton Gil Peres, Eric Yiwei Du, Lin Zhu, Katharina Gaus, Jesse Goyette, J Justin Gooding
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Abstract

Three-dimensional (3D) in vitro models enable us to understand cell behavior that is a better reflection of what occurs in vivo than 2D in vitro models. As a result, developing 3D models for extracellular matrix (ECM) has been growing exponentially. Most of the efforts for these 3D models are geared toward understanding cancer cells. An intricate network of cells that engages with cancer cells and can kill them are the immune cells, particularly cytotoxic T lymphocytes (CTLs). However, limited reports are available for 3D ECM mimics to understand CTL dynamics. Currently, we lack ECM mimetic hydrogels for immune cells, with sufficient control over variables, such as stiffness, to fully understand CTL dynamics in vitro. Here, we developed PEG-based hydrogels as ECM mimics for CTLs. The ECM mimics are targeted to mimic the stiffness of soft tissues where CTLs reside, migrate, and deliver their function. To understand cell-material interaction, we determined the porosity, biocompatibility, and stiffness of the ECM mimics. The ECM mimics have median pore sizes of 10.7 and 13.3 μm, close to the average nucleus size of CTLs (~8.6 μm), and good biocompatibility to facilitate cell migration. The stiffness of the ECM mimics corresponds to biologically relevant microenvironments such as lungs and kidneys. Using time-lapse fluorescence microscopy, 3D cell migration was imaged and measured. CTLs migrated faster in softer ECM mimic with larger pores, consistent with previous studies in collagen (the gold standard ECM mimic for CTLs). The work herein demonstrates that the PEG-based ECM mimic can serve as an in vitro tool to elucidate the cell dynamics of CTLs. Thus, this study opens possibilities to study the mechanics of CTLs in well-defined ECM mimic conditions in vitro.

聚乙二醇水凝胶作为细胞毒性 T 淋巴细胞的三维细胞外基质模拟物
与二维体外模型相比,三维体外模型能更好地反映细胞在体内的行为。因此,细胞外基质(ECM)三维模型的开发呈指数级增长。这些三维模型的大部分工作都是为了了解癌细胞。免疫细胞,尤其是细胞毒性 T 淋巴细胞(CTL)是与癌细胞接触并能杀死癌细胞的复杂细胞网络。然而,目前关于三维 ECM 模拟以了解 CTL 动态的报道非常有限。目前,我们还缺乏能充分控制硬度等变量的免疫细胞 ECM 模拟水凝胶,以充分了解 CTL 在体外的动态。在此,我们开发了基于 PEG 的水凝胶作为 CTL 的 ECM 模拟物。ECM 模拟物的目标是模拟 CTL 驻留、迁移和发挥其功能的软组织的硬度。为了了解细胞与材料之间的相互作用,我们测定了 ECM 模拟物的孔隙率、生物相容性和硬度。ECM 模拟物的孔隙大小中值分别为 10.7 和 13.3 μm,接近 CTL 细胞核的平均大小(约 8.6 μm),具有良好的生物相容性,可促进细胞迁移。ECM 模拟物的硬度与生物相关的微环境(如肺部和肾脏)相符。利用延时荧光显微镜对三维细胞迁移进行了成像和测量。CTL 在具有较大孔隙的较软 ECM 模拟物中迁移得更快,这与之前在胶原蛋白(CTL 的黄金标准 ECM 模拟物)中的研究结果一致。本文的研究表明,基于 PEG 的 ECM 模拟物可作为体外工具,用于阐明 CTL 的细胞动力学。因此,这项研究为研究 CTL 在定义明确的体外 ECM 模拟条件下的机理提供了可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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