Banas Richard, Miller Carrie, Guzik Lynda, Zeevi Adriana
Stemnion, Inc., Pittsburgh, PA, USA.
Cell Transplant. 2014;23(9):1111-25. doi: 10.3727/096368913X670165.
Cells derived from the placenta have become the focus of extensive research concerning their ability to be used for regenerative medicine or cellular therapies. In a previous study, we characterized amnion-derived multipotent progenitor cells, or AMP cells, by in vitro methods and showed they were able to inhibit antigen-specific T-cell proliferation in a cell-to-cell contact-dependent fashion. Here we examine specific mechanisms involved in immunomodulation by AMP cells. We found that AMP cells significantly inhibited monocyte-derived myeloid dendritic cell (DC) maturation when placed in coculture. Cocultured monocytes retained the nondifferentiated macrophage marker CD14 while exhibiting significant reduction in DC maturation markers CD83 and CD1a, indicating an immature DC maturation state that is pivotal in determining its immune stimulatory or regulatory status. This effect was again dependent on cell-to-cell contact interaction. We also found a significant shift in cytokines present in the microenvironment of cocultures, which indicated a regulatory DC function rather than a stimulatory cell type. Here supernatants taken from AMP cell/monocyte cocultures yielded significant levels of regulatory cytokines, such as PGE2, IL-6, IL-10, and MIC-1. The soluble form of HLA-G was also found at higher levels in cocultures. In contrast, supernatants contained significantly less amounts of the T-cell-stimulating factor IL-12, which is normally produced by activated DCs. Interestingly, cocultured monocytes acquired significant expression of HLA-G on their cell surface over time. HLA-G has multifaceted immunological implications and may be a key molecule in influencing these cells to behave as regulatory DCs. Together, the influence of AMP cells on maturing DCs may favor a regulatory pathway that can be useful for therapeutic applications for immune-mediated disorders or transplantation therapies.
源自胎盘的细胞因其可用于再生医学或细胞疗法的能力而成为广泛研究的焦点。在先前的一项研究中,我们通过体外方法对羊膜来源的多能祖细胞(即AMP细胞)进行了表征,并表明它们能够以细胞间接触依赖的方式抑制抗原特异性T细胞增殖。在此,我们研究了AMP细胞参与免疫调节的具体机制。我们发现,将AMP细胞置于共培养体系中时,它们能显著抑制单核细胞来源的髓样树突状细胞(DC)的成熟。共培养的单核细胞保留了未分化巨噬细胞标志物CD14,同时DC成熟标志物CD83和CD1a显著减少,这表明DC处于未成熟状态,这对于确定其免疫刺激或调节状态至关重要。这种效应同样依赖于细胞间的接触相互作用。我们还发现共培养微环境中存在的细胞因子发生了显著变化,这表明DC发挥的是调节功能而非刺激功能。从AMP细胞/单核细胞共培养体系中获取的上清液产生了大量的调节性细胞因子,如前列腺素E2、白细胞介素-6、白细胞介素-10和巨噬细胞抑制因子-1(MIC-1)。在共培养体系中还发现可溶性HLA-G水平较高。相比之下,上清液中T细胞刺激因子白细胞介素-12的含量显著减少,白细胞介素-12通常由活化的DC产生。有趣的是,随着时间的推移,共培养的单核细胞在其细胞表面获得了HLA-G的显著表达。HLA-G具有多方面的免疫学意义,可能是影响这些细胞表现为调节性DC的关键分子。总之,AMP细胞对成熟DC的影响可能有利于一种调节途径,这对于免疫介导性疾病的治疗应用或移植疗法可能是有用的。
