de la Rosa Gonzalo, Yáñez-Mó María, Samaneigo Raphael, Serrano-Gómez Diego, Martínez-Muñoz Laura, Fernández-Ruiz Elena, Longo Natividad, Sánchez-Madrid Francisco, Corbí Angel L, Sánchez-Mateos Paloma
Servicio de Inmunología, Hospital General Universitario Gregorio Marañón, Madrid, Spain.
J Leukoc Biol. 2005 May;77(5):699-709. doi: 10.1189/jlb.0904529. Epub 2005 Feb 22.
Zymosan is a beta-glucan, mannan-rich yeast particle widely used to activate the inflammatory response of immune cells. We studied the zymosan-binding potential of human dendritic cells (hDCs) by using specific carbohydrate inhibitors and blocking monoclonal antibodies. We show that DC-specific intercellular adhesion molecule-grabbing nonintegrin (DC-SIGN) is a major nonopsonic recognition receptor for zymosan on hDCs. Indeed, blocking of DC-SIGN inhibited the inflammatory response of DCs to zymosan. We compared the zymosan-binding capacity of hDC-SIGN to that of Dectin-1 and complement receptor 3 (CR3), which are receptors involved in the nonopsonic recognition of these yeast-derived particles. Dectin-1- and DC-SIGN-K562 cells bound to zymosan particles, whereas CR3-K562 cells did not. DC-SIGN and Dectin-1 were also expressed in COS cells to compare their ability to trigger particle internalization in a nonphagocytic cell line. DC-SIGN transfectants were unable to internalize bound particles, indicating that DC-SIGN is primarily involved in recognition but not in particle internalization. Zymosan induced a rapid DC aggregation that was accompanied by a dramatic change of DC-SIGN distribution in the plasma membrane. Under resting conditions, DC-SIGN was diffusely distributed through the cell surface, displaying clusters at the free leading edge. Upon zymosan treatment, DC-SIGN was markedly redistributed to cell-cell contacts, supporting an adhesion role in DC-DC interactions. The mechanism(s) supporting DC-SIGN-mediated intercellular adhesion were further investigated by using DC-SIGN-K562 aggregation. DC-SIGN was highly concentrated at points of cell-cell contact, suggesting a role for enhanced avidity during DC-SIGN-mediated intercellular adhesion.
酵母聚糖是一种富含β-葡聚糖和甘露聚糖的酵母颗粒,广泛用于激活免疫细胞的炎症反应。我们通过使用特异性碳水化合物抑制剂和阻断性单克隆抗体研究了人树突状细胞(hDCs)与酵母聚糖的结合潜力。我们发现,树突状细胞特异性细胞间粘附分子捕获非整合素(DC-SIGN)是hDCs上酵母聚糖的主要非调理素识别受体。事实上,阻断DC-SIGN可抑制DCs对酵母聚糖的炎症反应。我们比较了hDC-SIGN与Dectin-1和补体受体3(CR3)对酵母聚糖的结合能力,这两种受体参与了对这些酵母衍生颗粒的非调理素识别。Dectin-1和DC-SIGN转染的K562细胞与酵母聚糖颗粒结合,而CR3转染的K562细胞则不结合。DC-SIGN和Dectin-1也在COS细胞中表达,以比较它们在非吞噬细胞系中触发颗粒内化的能力。DC-SIGN转染子无法内化结合的颗粒,这表明DC-SIGN主要参与识别而非颗粒内化。酵母聚糖诱导了快速的DC聚集,同时伴随着DC-SIGN在质膜上分布的显著变化。在静息条件下,DC-SIGN在细胞表面呈弥散分布,在游离前沿显示出簇状。经酵母聚糖处理后,DC-SIGN明显重新分布到细胞-细胞接触部位,这支持了其在DC-DC相互作用中的粘附作用。通过使用DC-SIGN-K562聚集进一步研究了支持DC-SIGN介导的细胞间粘附的机制。DC-SIGN高度集中在细胞-细胞接触点,这表明在DC-SIGN介导的细胞间粘附中亲和力增强发挥了作用。
