Rayahin Jamie E, Buhrman Jason S, Zhang Yu, Koh Timothy J, Gemeinhart Richard A
Department of Biopharmaceutical Sciences, University of Illinois, Chicago, IL 60612-7231, USA.
Department of Kinesiology and Nutrition, Center for Wound Healing and Tissue Regeneration, University of Illinois, Chicago, IL 60612-7246, USA.
ACS Biomater Sci Eng. 2015 Jul 13;1(7):481-493. doi: 10.1021/acsbiomaterials.5b00181.
Macrophages exhibit phenotypic diversity permitting wide-ranging roles in maintaining physiologic homeostasis. Hyaluronic acid, a major glycosaminoglycan of the extracellular matrix, has been shown to have differential signaling based on its molecular weight. With this in mind, the main objective of this study was to elucidate the role of hyaluronic acid molecular weight on macrophage activation and reprogramming. Changes in macrophage activation were assessed by activation state selective marker measurement, specifically quantitative real time polymerase chain reaction, and cytokine enzyme-linked immunoassays, after macrophage treatment with differing molecular weights of hyaluronic acid under four conditions: the resting state, concurrent with classical activation, and following inflammation involving either classically or alternatively activated macrophages. Regardless of initial polarization state, low molecular weight hyaluronic acid induced a classically activated-like state, confirmed by up-regulation of pro-inflammatory genes, including , , , and , and enhanced secretion of nitric oxide and TNF-α. High molecular weight hyaluronic acid promoted an alternatively activated-like state, confirmed by up regulation of pro-resolving gene transcription, including , , and , and enhanced arginase activity. Overall, our observations suggest that macrophages undergo phenotypic changes dependent on molecular weight of hyaluronan that correspond to either (1) pro-inflammatory response for low molecular weight HA or (2) pro-resolving response for high molecular weight HA. These observations bring significant further understanding of the influence of extracellular matrix polymers, hyaluronic acid in particular, on regulating the inflammatory response of macrophages. This knowledge can be used to guide the design of HA-containing biomaterials to better utilize the natural response to HAs.
巨噬细胞表现出表型多样性,在维持生理稳态中发挥着广泛作用。透明质酸是细胞外基质的主要糖胺聚糖,已被证明根据其分子量具有不同的信号传导。基于此,本研究的主要目的是阐明透明质酸分子量对巨噬细胞激活和重编程的作用。在用不同分子量的透明质酸处理巨噬细胞后,通过激活状态选择性标志物测量,特别是定量实时聚合酶链反应和细胞因子酶联免疫测定,评估巨噬细胞激活的变化,处理条件有四种:静息状态、与经典激活同时、以及涉及经典或替代激活巨噬细胞的炎症后状态。无论初始极化状态如何,低分子量透明质酸诱导出类似经典激活的状态,这通过促炎基因(包括 、 、 和 )的上调以及一氧化氮和肿瘤坏死因子-α分泌的增加得到证实。高分子量透明质酸促进类似替代激活的状态,这通过促分解基因转录(包括 、 和 )的上调以及精氨酸酶活性的增强得到证实。总体而言,我们的观察结果表明,巨噬细胞会根据透明质酸的分子量发生表型变化,这对应于(1)低分子量透明质酸的促炎反应或(2)高分子量透明质酸的促分解反应。这些观察结果进一步显著加深了我们对细胞外基质聚合物,特别是透明质酸对巨噬细胞炎症反应调节影响的理解。这些知识可用于指导含透明质酸生物材料的设计,以更好地利用对透明质酸的天然反应。