培养破骨细胞中表面诱导的足体组织和动力学调控
Surface-induced regulation of podosome organization and dynamics in cultured osteoclasts.
作者信息
Geblinger Dafna, Geiger Benjamin, Addadi Lia
机构信息
Department of Structural Biology, Weizmann Institute of Science, 76100 Rehovot, Israel.
出版信息
Chembiochem. 2009 Jan 5;10(1):158-65. doi: 10.1002/cbic.200800549.
Abstract
Bone is continuously repaired and remodeled through the well-coordinated activity of osteoblasts, which form new bone, and osteoclasts, which resorb it. How osteoclasts sense the properties of the bone surface remains unclear. By combining light and electron microscopy, we compared osteoclast behavior on three distinct surfaces: glass, calcite single crystals, and bone. Podosomes, the basic units of the adhesion structure, and their organization into superstructures were found to be common to cells that were attached to all three substrates, whereas the structure of the resorption organelle, the so-called "ruffled border," markedly differed. Moreover, the integrity, stability, and dynamic behavior of the adhesion superstructures also fundamentally differed, depending on the substrate. We conclude that osteoclasts sense the local properties of the underlying substrate and respond to these signals, both locally and globally.
摘要
骨骼通过成骨细胞(形成新骨)和破骨细胞(吸收骨组织)的协同活动不断地进行修复和重塑。破骨细胞如何感知骨表面的特性仍不清楚。通过结合光学显微镜和电子显微镜,我们比较了破骨细胞在三种不同表面上的行为:玻璃、方解石单晶和骨骼。粘附结构的基本单位——足体及其组织形成的超结构,在附着于所有三种基质的细胞中都很常见,而吸收细胞器(即所谓的“皱褶缘”)的结构则明显不同。此外,粘附超结构的完整性、稳定性和动态行为也因基质的不同而有根本差异。我们得出结论,破骨细胞能够感知下层基质的局部特性,并对这些信号做出局部和整体的反应。
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