唾液酸结合免疫球蛋白样凝集素CD22的纳米级组织与动力学在抑制BCR信号传导过程中与细胞骨架协同作用。
Nanoscale organization and dynamics of the siglec CD22 cooperate with the cytoskeleton in restraining BCR signalling.
作者信息
Gasparrini Francesca, Feest Christoph, Bruckbauer Andreas, Mattila Pieta K, Müller Jennifer, Nitschke Lars, Bray Dennis, Batista Facundo D
机构信息
Lincoln's Inn Fields Laboratory, The Francis Crick Institute, London, UK.
Chair of Genetics, Department of Biology, University of Erlangen, Erlangen, Germany.
出版信息
EMBO J. 2016 Feb 1;35(3):258-80. doi: 10.15252/embj.201593027. Epub 2015 Dec 15.
Abstract
Receptor organization and dynamics at the cell membrane are important factors of signal transduction regulation. Using super-resolution microscopy and single-particle tracking, we show how the negative coreceptor CD22 works with the cortical cytoskeleton in restraining BCR signalling. In naïve B cells, we found endogenous CD22 to be highly mobile and organized into nanodomains. The landscape of CD22 and its lateral diffusion were perturbed either in the absence of CD45 or when the CD22 lectin domain was mutated. To understand how a relatively low number of CD22 molecules can keep BCR signalling in check, we generated Brownian dynamic simulations and supported them with ex vivo experiments. This combined approach suggests that the inhibitory function of CD22 is influenced by its nanoscale organization and is ensured by its fast diffusion enabling a "global BCR surveillance" at the plasma membrane.
摘要
细胞膜上的受体组织和动力学是信号转导调控的重要因素。利用超分辨率显微镜和单粒子追踪技术,我们展示了负性共受体CD22如何与皮质细胞骨架协同作用来抑制BCR信号传导。在未成熟B细胞中,我们发现内源性CD22具有高度的流动性,并组织成纳米结构域。在缺乏CD45的情况下或当CD22凝集素结构域发生突变时,CD22的分布格局及其侧向扩散都会受到干扰。为了理解相对少量的CD22分子如何控制BCR信号传导,我们进行了布朗动力学模拟,并通过体外实验对其进行了支持。这种综合方法表明,CD22的抑制功能受其纳米级组织的影响,并通过其快速扩散得以确保,从而在质膜上实现“全局BCR监测”。
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