Solanki Nehal R, Stadanlick Jason E, Zhang Yong, Duc Ann-Cecile, Lee Sang-Yun, Lauritsen Jens Peter Holst, Zhang Zhiqiang, Wiest David L
Blood Cell Development and Function Program, Fox Chase Cancer Center, Philadelphia, PA 19111; and Department of Microbiology and Immunology, Drexel University College of Medicine, Philadelphia, PA 19111.
Blood Cell Development and Function Program, Fox Chase Cancer Center, Philadelphia, PA 19111; and.
J Immunol. 2016 Sep 15;197(6):2280-9. doi: 10.4049/jimmunol.1600815. Epub 2016 Aug 3.
Although ribosomal proteins (RP) are thought to primarily facilitate biogenesis of the ribosome and its ability to synthesize protein, emerging evidence suggests that individual RP can perform critical regulatory functions that control developmental processes. We showed previously that despite the ubiquitous expression of the RP ribosomal protein L22 (Rpl22), germline ablation of Rpl22 in mice causes a selective, p53-dependent block in the development of αβ, but not γδ, T cell progenitors. Nevertheless, the basis by which Rpl22 loss selectively induces p53 in αβ T cell progenitors remained unclear. We show in this study that Rpl22 regulates the development of αβ T cells by restraining endoplasmic reticulum (ER) stress responses. In the absence of Rpl22, ER stress is exacerbated in αβ, but not γδ, T cell progenitors. The exacerbated ER stress in Rpl22-deficient αβ T lineage progenitors is responsible for selective induction of p53 and their arrest, as pharmacological induction of stress is sufficient to induce p53 and replicate the selective block of αβ T cells, and attenuation of ER stress signaling by knockdown of protein kinase R-like ER kinase, an ER stress sensor, blunts p53 induction and rescues development of Rpl22-deficient αβ T cell progenitors. Rpl22 deficiency appears to exacerbate ER stress by interfering with the ability of ER stress signals to block new protein synthesis. Our finding that Rpl22 deficiency exacerbates ER stress responses and induces p53 in αβ T cell progenitors provides insight into how a ubiquitously expressed RP can perform regulatory functions that are selectively required by some cell lineages but not others.
尽管核糖体蛋白(RP)主要被认为有助于核糖体的生物合成及其合成蛋白质的能力,但新出现的证据表明,单个RP可以执行控制发育过程的关键调节功能。我们之前表明,尽管RP核糖体蛋白L22(Rpl22)普遍表达,但小鼠中Rpl22的种系缺失会导致αβ而非γδ T细胞祖细胞发育中出现选择性的、p53依赖性阻滞。然而,Rpl22缺失在αβ T细胞祖细胞中选择性诱导p53的基础仍不清楚。我们在本研究中表明,Rpl22通过抑制内质网(ER)应激反应来调节αβ T细胞的发育。在缺乏Rpl22的情况下,αβ而非γδ T细胞祖细胞中的ER应激会加剧。Rpl22缺陷型αβ T谱系祖细胞中加剧的ER应激是p53选择性诱导及其阻滞的原因,因为药理学诱导应激足以诱导p53并复制αβ T细胞的选择性阻滞,而通过敲低作为ER应激传感器的蛋白激酶R样ER激酶来减弱ER应激信号传导,会减弱p53的诱导并挽救Rpl22缺陷型αβ T细胞祖细胞的发育。Rpl22缺陷似乎通过干扰ER应激信号阻断新蛋白质合成的能力来加剧ER应激。我们发现Rpl22缺陷会加剧ER应激反应并在αβ T细胞祖细胞中诱导p53,这为一种普遍表达的RP如何执行某些细胞谱系选择性需要而其他细胞谱系不需要的调节功能提供了见解。
