Gerlach Brennan D, Marinello Michael, Heinz Justin, Rymut Nicholas, Sansbury Brian E, Riley Colin O, Sadhu Sudeshna, Hosseini Zeinab, Kojima Yoko, Tang Dale D, Leeper Nicholas J, Spite Matthew, Barroso Margarida, Rayner Katey J, Fredman Gabrielle
The Department of Molecular and Cellular Physiology, Albany Medical College, Albany, NY, 12208, USA.
Center for Experimental Therapeutics and Reperfusion Injury, Department of Anesthesiology, Perioperative and Pain Medicine, Brigham and Women's Hospital and Harvard Medical School, Boston, MA, 02115, USA.
Cell Death Differ. 2020 Feb;27(2):525-539. doi: 10.1038/s41418-019-0370-1. Epub 2019 Jun 20.
Inflammation-resolution is a protective response that is mediated by specialized pro-resolving mediators (SPMs). The clearance of dead cells or efferocytosis is a critical cellular program of inflammation-resolution. Impaired efferocytosis can lead to tissue damage in prevalent human diseases, like atherosclerosis. Therefore understanding mechanisms associated with swift clearance of dead cells is of utmost clinical importance. Recently, the accumulation of necroptotic cells (NCs) was observed in human plaques and we postulated that this is due to defective clearance programs. Here we present evidence that NCs are inefficiently taken up by macrophages because they have increased surface expression of a well-known "don't eat me" signal called CD47. High levels of CD47 on NCs stimulated RhoA-pMLC signaling in macrophages that promoted "nibbling", rather than whole-cell engulfment of NCs. Anti-CD47 blocking antibodies limited RhoA-p-MLC signaling and promoted whole-cell NC engulfment. Treatment with anti-CD47 blocking antibodies to Ldlr mice with established atherosclerosis decreased necrotic cores, limited the accumulation of plaque NCs and increased lesional SPMs, including Resolvin D1 (RvD1) compared with IgG controls. Mechanistically, RvD1 promoted whole-cell engulfment of NCs by decreasing RhoA signaling and activating CDC42. RvD1 specifically targeted NCs for engulfment by facilitating the release of the well-known "eat me signal" called calreticulin from macrophages in a CDC42 dependent manner. Lastly, RvD1 enhanced the clearance of NCs in advanced murine plaques. Together, these results suggest new molecules and signaling associated with the clearance of NCs, provide a new paradigm for the regulation of inflammation-resolution, and offer a potential treatment strategy for diseases where NCs underpin the pathology.
炎症消退是一种由特异性促消退介质(SPM)介导的保护性反应。死细胞的清除或胞葬作用是炎症消退的关键细胞程序。胞葬作用受损可导致常见人类疾病(如动脉粥样硬化)中的组织损伤。因此,了解与死细胞快速清除相关的机制具有至关重要的临床意义。最近,在人类斑块中观察到坏死性凋亡细胞(NC)的积累,我们推测这是由于清除程序存在缺陷。在此,我们提供证据表明,NC被巨噬细胞低效摄取,因为它们增加了一种名为CD47的著名“别吃我”信号的表面表达。NC上高水平的CD47刺激巨噬细胞中的RhoA-pMLC信号传导,促进对NC的“蚕食 ”,而不是全细胞吞噬。抗CD47阻断抗体限制了RhoA-p-MLC信号传导,并促进了全细胞对NC的吞噬。用抗CD47阻断抗体治疗已患动脉粥样硬化的Ldlr小鼠,与IgG对照组相比,可减少坏死核心,限制斑块NC的积累,并增加损伤部位的SPM,包括消退素D1(RvD1)。从机制上讲,RvD1通过降低RhoA信号传导和激活CDC42来促进巨噬细胞对NC的全细胞吞噬。RvD1通过以CDC42依赖的方式促进巨噬细胞释放名为钙网蛋白的著名“吃我信号”,特异性地靶向NC进行吞噬。最后,RvD1增强了晚期小鼠斑块中NC的清除。总之,这些结果揭示了与NC清除相关的新分子和信号传导,为炎症消退的调节提供了新的范例,并为NC构成病理基础的疾病提供了潜在的治疗策略。
