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(PQ3) The role of damaged DNA in inter-individual variation of tumor immunity

(PQ3) 受损DNA在肿瘤免疫个体间变异中的作用

基本信息

批准号：
9338211
负责人：
Nir Hacohen
金额：
$ 51.82万
依托单位：
BROAD INSTITUTE, INC.
依托单位国家：
美国
项目类别：
财政年份：
2016
资助国家：
美国
起止时间：
2016-08-26 至 2021-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9338211
关键词：
Address Affect Animals Autoimmunity Automobile Driving Cancer Control Cancer Immunology Science Cancer cell line Cell Culture Techniques Cell Line Cell Nucleus Cells Clinical Colorectal Colorectal Cancer Cytosol DNA DNA Damage DNA Repair Genetic Goals Human Immune Immune response Immune system Immunity Immunologic Monitoring Immunotherapy Individual Individual Differences Innate Immune Response Malignant Neoplasms Malignant neoplasm of lung Metastatic Melanoma Mus Mutation Natural Immunity Natural Killer Cells Operative Surgical Procedures Outcome Pathway interactions Patients Process Property Reporting Role Sampling Series Smoker Source T-Lymphocyte Testing Tumor Burden Tumor Cell Line Tumor Immunity Variant adaptive immunity base chemokine colon cancer patients cytokine density immune checkpoint blockade inter-individual variation melanoma mouse model neoplastic cell new therapeutic target novel pathogen programs response sensor transcriptome sequencing tumor tumor growth

项目摘要

A central challenge in cancer immunology is to explain inter-individual differences in spontaneous and immunotherapy-induced immunity, and then build on the explanatory mechanisms to enhance existing and develop novel immunotherapies. Based on studies across diverse cancers, a substantial increase in overall survival is observed for patients with higher densities of T cells in their tumors. However, what remains obscure is why some patients develop powerful immune responses while others have undetectable immunity. A series of recent studies reported that patients with high loads of tumor mutations are more likely to have durable responses to checkpoint blockade therapy – for MSI+ CRC, lung cancer in smokers, and melanoma. The current hypothesis is that more mutations generate more neoantigens that provide unique targets for T cells to recognize tumors. Since mounting a strong immune response also requires stimulation of specialized pathogen sensors that drive innate immune response, we have hypothesized that potent tumor immunity may also depend on engagement of pathogen sensors. We recently discovered that damaged DNA is exported from nucleus to cytosol where it triggers the STING DNA-sensing pathway and thus induces cytokines, chemokines and subsequent immune responses, a finding observed recently by several groups independently. We propose that tumors with higher loads of damaged DNA could trigger intrinsic innate immune responses via STING and enhance protective anti-tumor immunity. Further supporting this hypothesis, we have identified 50 cancer cell lines that express a STING-dependent innate immune response constitutively. We thus hypothesize that tumors with higher loads of damaged DNA (or mutation rates) trigger DNA sensors within tumor cells, and induce innate immune responses that drive T or NK cell rejection of the tumor. This hypothesis synergizes well with the hypothesis that higher mutation rates produce more neoantigens, and explains the induction of both innate and adaptive immunity as a function of mutation rates and DNA damage. We propose to comprehensively test the role of damaged DNA in driving tumor immunity, using a combination of cell culture studies to study the role of damaged DNA in driving innate immune response (Aim 1); a mouse model to determine the impact of damaged DNA within a tumor on STING-dependent immune rejection of the tumor (Aim 2); and studies of human colorectal cancers and melanomas to test for associations between damaged DNA, local tumor immunity and clinical outcome (Aim 3). Since our long-term goal is to discover the mechanisms that explain variations in tumor immunity, we will employ an unbiased approach (Aim 3.2) to generate new hypotheses for how tumors drive or suppress immunity in human tumors with known outcome. Our studies are expected to help explain inter-individual variation in tumor immunity, address why immunotherapy succeeds or fails to control tumors, and inspire novel therapeutic targets.

癌症免疫学的一个核心挑战是解释自发性和非自发性免疫的个体间差异。免疫疗法诱导的免疫，然后建立在解释机制，以加强现有的，开发新的免疫疗法。根据对各种癌症的研究，在肿瘤中具有较高T细胞密度的患者中观察到存活。然而，仍然不清楚的是，这就是为什么有些病人会产生强大的免疫反应，而另一些病人却没有检测到免疫力。一系列最近的研究报告说，肿瘤突变负荷高的患者更有可能具有持久的对检查点阻断治疗的反应-MSI+ CRC、吸烟者肺癌和黑色素瘤。的目前的假设是，更多的突变产生更多的新抗原，为T细胞提供独特的靶点，识别肿瘤。由于建立一个强大的免疫反应也需要刺激专门的病原体传感器驱动先天免疫反应，我们假设，强大的肿瘤免疫也可能取决于病原体传感器的参与。我们最近发现，受损的DNA是从细胞核到胞质溶胶，在那里它触发STING DNA传感通路，从而诱导细胞因子、趋化因子以及随后的免疫反应，这一发现最近被几个独立的研究小组观察到。我们提出具有较高DNA损伤负荷的肿瘤可以通过STING触发内在先天免疫反应，增强保护性抗肿瘤免疫。进一步支持这一假设，我们已经确定了50个癌细胞组成性表达STING依赖性先天免疫应答的细胞系。因此，我们假设具有较高损伤DNA负荷（或突变率）的肿瘤触发肿瘤细胞内的DNA传感器，并且诱导先天免疫应答，其驱动肿瘤的T或NK细胞排斥。这一假设很好地协同作用假设较高的突变率产生更多的新抗原，并解释了两者的诱导先天性和适应性免疫是突变率和DNA损伤的函数。我们建议全面测试受损DNA在驱动肿瘤免疫中的作用，使用细胞培养和研究受损DNA在驱动先天免疫应答中的作用（Aim 1）; 确定肿瘤内受损DNA对肿瘤的STING依赖性免疫排斥的影响 (Aim 2）;以及对人类结肠直肠癌和黑色素瘤的研究，以测试受损的 DNA、局部肿瘤免疫和临床结局（目的3）。因为我们的长期目标是发现为了解释肿瘤免疫的变化机制，我们将采用无偏的方法（目标3.2），为肿瘤如何驱动或抑制具有已知结果的人类肿瘤中的免疫产生新的假设。我们的研究有望帮助解释肿瘤免疫的个体间差异，免疫疗法成功或失败控制肿瘤，并激发新的治疗靶点。