TCR 与激动肽-MHC 之间动态结合键的积累触发 T 细胞信号转导。
Accumulation of dynamic catch bonds between TCR and agonist peptide-MHC triggers T cell signaling.
机构信息
Coulter Department of Biomedical Engineering, Georgia Institute of Technology, Atlanta, GA 30332, USA.
Department of Microbiology and Immunology, Emory University School of Medicine, Atlanta, GA 30322, USA.
出版信息
Cell. 2014 Apr 10;157(2):357-368. doi: 10.1016/j.cell.2014.02.053.
Abstract
TCR-pMHC interactions initiate adaptive immune responses, but the mechanism of how such interactions under force induce T cell signaling is unclear. We show that force prolongs lifetimes of single TCR-pMHC bonds for agonists (catch bonds) but shortens those for antagonists (slip bonds). Both magnitude and duration of force are important, as the highest Ca(2+) responses were induced by 10 pN via both pMHC catch bonds whose lifetime peaks at this force and anti-TCR slip bonds whose maximum lifetime occurs at 0 pN. High Ca(2+) levels require early and rapid accumulation of bond lifetimes, whereas short-lived bonds that slow early accumulation of lifetimes correspond to low Ca(2+) responses. Our data support a model in which force on the TCR induces signaling events depending on its magnitude, duration, frequency, and timing, such that agonists form catch bonds that trigger the T cell digitally, whereas antagonists form slip bonds that fail to activate.
摘要
TCR-pMHC 相互作用启动适应性免疫反应,但力如何诱导 T 细胞信号转导的机制尚不清楚。我们表明,力延长了激动剂(捕获键)的单个 TCR-pMHC 键的寿命,但缩短了拮抗剂(滑动键)的寿命。力的大小和持续时间都很重要,因为通过 pMHC 捕获键以 10 pN 的力可以产生最高的 Ca(2+)反应,该键的寿命峰值在此力下,而抗 TCR 滑动键的最大寿命发生在 0 pN。高 Ca(2+)水平需要早期和快速积累键的寿命,而寿命较短的键会减缓早期寿命的积累,对应于低 Ca(2+)反应。我们的数据支持这样一种模型,即 TCR 上的力根据其大小、持续时间、频率和时间诱导信号事件,使得激动剂形成触发 T 细胞的捕获键,而拮抗剂形成无法激活的滑动键。
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本文引用的文献
1
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Eur J Immunol. 2014 Jan;44(1):239-50. doi: 10.1002/eji.201343774. Epub 2013 Oct 20.
3
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4
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6
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