Intracellular immunity, cytosolic DNA sensing by cyclic GAMP synthase, and macrophages in ischemic injury and cardiac remodeling

细胞内免疫、环 GAMP 合酶检测胞质 DNA 以及缺血性损伤和心脏重塑中的巨噬细胞

• 批准号: 10226012
• 负责人: Dian Cao
• 金额: $ 40.5万
• 依托单位: UT SOUTHWESTERN MEDICAL CENTER
• 依托单位国家: 美国
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-07-01 至 2024-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10226012
• 关键词: Acute; Address; Affect; Antiviral Response; Award; Behavior; Binding Proteins; Biology; Cardiac; Cardiac Myocytes; Cardiovascular system; Caring; Caspase; Cells; Chronic Phase; Clinical; Clinical Trials; Cytosol; DNA; DNA receptor; Data; Disease; Drug usage; Endotoxic Shock; Engineering; Event; Fibroblasts; Goals; Heart failure; Immune; Immune response; Immunity; Immunologics; Immunology; Immunomodulators; Immunotherapy; Incidence; Inflammasome; Inflammation; Inflammatory; Inflammatory Response; Injury; Interferon Type I; Interferon-beta; Interferons; Interleukin-1 beta; Ischemia; Knock-out; Knowledge; Laboratories; Lead; Link; Longevity; Mediating; Membrane; Mitochondria; Mitochondrial DNA; Modeling; Molecular; Mus; Muscle Cells; Myocardial; Myocardial Infarction; Myocardial Ischemia; Myocardium; Nature; Nuclear; Outcome; Pathologic; Pathway interactions; Patients; Periodicity; Phagocytes; Phosphotransferases; Play; Process; Publishing; Quinacrine; Records; Reporter; Reporting; Research; Resources; Role; Safety; Signal Transduction; Source; Sterility; TBK1 gene; Testing; Time; Tissues; Translating; United States National Institutes of Health; Vesicle; Work; amlexanox; base; cardioprotection; cell type; clinically relevant; cytosolic receptor; design; ds-DNA; guanylate; heart function; improved; in vitro Model; insight; ischemic injury; macrophage; mortality; myocardial damage; new therapeutic target; novel; novel strategies; novel therapeutics; pathogen; receptor; recruit; repaired; response; sensor; side effect; therapeutic target; tissue injury; tissue repair; translational impact

PROJECT SUMMARY/ABSTRACT Inhibiting inflammation of the arterial wall by targeting interleukin-1β lowers the incidence of cardiovascular events. However, we have not discovered strategies limiting inflammation-related injury in acute ischemia. One major obstacle is the critical gap of knowledge in understanding danger recognition, the actual process that dictates the scope of inflammation. My long-term goal is to develop immune modulators that modify danger recognition to contain inflammation-mediated injury after MI. The overall objective of this proposal is to determine how DNA and its cytosolic receptor the cyclic GAMP synthase (cGAS) propagate injury triggered by ischemia. The damaged myocardium is enriched with mitochondrial (thousands of copies per cardiomyocyte) and nuclear DNA. The large amount of DNA poses a serious threat to myocardial repair when macrophages, the professional phagocytes, detect it and respond with robust inflammatory responses that are originally intended to get rid of pathogens (from the evolutionary standpoint). The central hypothesis is that recognition of DNA by cGAS sustains the inflammatory macrophages via activation of the type I interferon (IFN) pathway that promotes inflammasone activation; as a result, cGAS is crucial in ischemia-induced remodeling. This hypothesis has been formulated on the preliminary data and the recently published work from my laboratory. The rationale is that understanding the intracellular danger recognition in ischemic-triggered inflammation has the potential to discover effective ways of limiting inflammation-related injury. Guided by strong preliminary data, this hypothesis will be tested by pursuing the following specific aims: 1) Determine whether cGAS activation in macrophages drives ischemia- induced remodeling and define the source of the cytosolic DNA; 2) Determine whether cGAS sustains inflammation in macrophages by promoting AIM2 and NLRP3 inflammasome and caspase 11-mediated pyroptosis; 3) Identify effective and clinically relevant approaches for inhibition of cGAS. Aim 1 will be addressed using a cGASf/f mouse line to determine macrophage as the responsible cell type. Studies are also designed to trace the source of the cytosolic DNA. Under the second aim, I will determine if guanylate-binding proteins (GBP), induced by cGAS activation, increase danger signal visibility to sensors like AIM2 and NLRP3 and if cGAS-depndent priming is essential in cGAS-triggered inflammasome activation in ischemia. Pyroptosis- mediated by caspase 11 will also be evaluated. Aim 3 will identify clinically relevant strategies to inhibit cGAS by assessing two agents that treat inflammatory disorders. The study is conceptually novel by targeting DNA and its receptor cGAS, a bona fide anti-viral response, in the setting of myocardial ischemia. Knowledge acquired will vertically advance our understanding of the critical role of intracellular immunity in ischemic injury. As ischemic heart disease is an enormous burden and often a devastating condition, the proposed study moves the field forward by finding novel strategies alleviating the burden and improve care. Additionally, results will help to understand potential cardiac side effects from immunotherapy via boosting cGAS-STING pathway activity (in clinical trials).

项目总结/摘要 通过靶向白细胞介素-1 β抑制动脉壁炎症降低心血管疾病的发生率 事件然而，我们还没有发现限制急性缺血中炎症相关损伤的策略。一 主要障碍是在理解危险识别方面的关键知识差距， 决定了炎症的范围我的长期目标是开发免疫调节剂， 识别包含MI后炎症介导的损伤。本建议的总体目标是 确定DNA及其胞质受体环GAMP合酶（cGAS）如何传播由 缺血受损的心肌富含线粒体（每个心肌细胞有数千个拷贝） 和核DNA当巨噬细胞， 专职吞噬细胞，检测它并以强烈的炎症反应作出反应， 意图摆脱病原体（从进化的角度来看）。核心假设是， cGAS的DNA通过激活I型干扰素（IFN）途径维持炎性巨噬细胞， 促进炎性激素激活;因此，cGAS在缺血诱导的重塑中至关重要。这一假设 我是根据我的实验室的初步数据和最近发表的工作制定的。基本原理是 了解缺血触发炎症中的细胞内危险识别有可能发现 限制炎症相关损伤的有效方法。在强有力的初步数据的指导下， 1）确定巨噬细胞中的cGAS活化是否驱动缺血- 诱导重塑并确定胞质DNA的来源; 2）确定cGAS是否维持 通过促进AIM2和NLRP3炎性体和caspase 11介导的巨噬细胞炎症 3）鉴定用于抑制cGAS的有效且临床相关的方法。目标1将是 使用cGASf/f小鼠系来确定巨噬细胞作为负责细胞类型。研究也 用来追踪胞质DNA的来源在第二个目标下，我将确定鸟苷酸结合是否 由cGAS激活诱导的GBP蛋白增加了AIM2和NLRP 3等传感器的危险信号可见性 以及cGAS依赖性启动是否在缺血中cGAS触发的炎性小体激活中是必需的。焦亡- 还将评估由胱天蛋白酶11介导的细胞凋亡。目标3将确定抑制cGAS的临床相关策略 通过评估两种治疗炎症性疾病的药物。这项研究在概念上是新颖的， 及其受体cGAS，一种真正的抗病毒反应，在心肌缺血的情况下。知识 这将垂直推进我们对细胞内免疫在缺血性损伤中的关键作用的理解。作为 缺血性心脏病是一个巨大的负担，往往是一个毁灭性的条件，拟议的研究移动领域 通过寻找新的战略来减轻负担和改善护理。此外，结果将有助于理解 通过增强cGAS-STING途径活性的免疫疗法的潜在心脏副作用（在临床试验中）。