Hu Jean, Jacinto Randy, McCall Charles, Li Liwu
Section of Infectious Diseases, Department of Medicine, Wake Forest University School of Medicine, Winston-Salem, NC 27157, USA.
J Immunol. 2002 Apr 15;168(8):3910-4. doi: 10.4049/jimmunol.168.8.3910.
IL-1R-associated kinase (IRAK) plays a pivotal role in IL-1R/Toll-like receptor (TLR)-mediated signaling and NF-kappaB activation. IRAK from leukocytes undergoes rapid activation and inactivation/degradation following IL-1 or LPS stimulation. The rapid degradation of IRAK may serve as a negative feedback mechanism of down-regulating IL-1R/TLR-mediated signaling and cytokine gene transcription. Although IL-1/IL-1R-triggered IRAK degradation has been studied in detail, the mechanism of LPS-induced IRAK activation and degradation is not clearly defined. In this study, we demonstrate that the IRAK N-terminal 186-aa region is required for LPS-induced degradation. The N-terminally truncated IRAK protein expressed in human monocytic THP-1 cells remains stable upon LPS challenge. In comparison, IRAK as well as the IRAK mutant with C-terminal truncation undergo degradation with LPS stimulation. We demonstrate that pretreatment with protein kinase C inhibitor calphostin inhibits LPS-induced IRAK degradation. Furthermore, we observe coimmunoprecipitation of endogenous IRAK and protein kinase C-zeta protein. We show that functional TLR4 is required for LPS-mediated IRAK degradation. IRAK protein in the murine GG2EE cells harboring a mutated TLR4 gene does not undergo degradation upon LPS treatment. In sharp contrast, we observe that the IRAK homolog, IRAK2, does not undergo degradation upon prolonged LPS treatment, suggesting complex regulation of the innate immunity network upon microbial challenge.
白细胞介素-1受体相关激酶(IRAK)在白细胞介素-1受体/ Toll样受体(TLR)介导的信号传导和核因子-κB激活中起关键作用。来自白细胞的IRAK在白细胞介素-1或脂多糖刺激后会迅速激活并失活/降解。IRAK的快速降解可能作为下调白细胞介素-1受体/TLR介导的信号传导和细胞因子基因转录的负反馈机制。尽管已经详细研究了白细胞介素-1/白细胞介素-1受体触发的IRAK降解,但脂多糖诱导的IRAK激活和降解机制尚不清楚。在本研究中,我们证明IRAK的N端186个氨基酸区域是脂多糖诱导降解所必需的。在人单核细胞THP-1细胞中表达的N端截短的IRAK蛋白在脂多糖刺激下保持稳定。相比之下,IRAK以及C端截短的IRAK突变体在脂多糖刺激下会发生降解。我们证明用蛋白激酶C抑制剂钙泊三醇预处理可抑制脂多糖诱导的IRAK降解。此外,我们观察到内源性IRAK和蛋白激酶C-ζ蛋白的共免疫沉淀。我们表明功能性TLR4是脂多糖介导的IRAK降解所必需的。携带突变TLR4基因的小鼠GG2EE细胞中的IRAK蛋白在脂多糖处理后不会发生降解。与之形成鲜明对比的是,我们观察到IRAK同源物IRAK2在长时间脂多糖处理后不会发生降解,这表明在微生物攻击时固有免疫网络的调节很复杂。
