New therapeutic approaches in clonal hematopoiesis and atherosclerosis

克隆造血和动脉粥样硬化的新治疗方法

基本信息

批准号：
10719058
负责人：
ALAN richard TALL
金额：
$ 69.47万
依托单位：
COLUMBIA UNIVERSITY HEALTH SCIENCES
依托单位国家：
美国
项目类别：
财政年份：
2023
资助国家：
美国
起止时间：
2023-08-01 至 2027-05-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10719058
关键词：
Acceleration Age Aging Alleles Anti-Inflammatory Agents Antibodies Arterial Fatty Streak Atherosclerosis Blood Cells Blood Vessels Bone Marrow Cardiovascular Diseases Carotid Artery Plaques Cause of Death Cells Cellular Indexing of Transcriptomes and Epitopes by Sequencing Clinical Clinical Trials Collaborations Cytokine Signaling Epigenetic Process Fibroblasts Frequencies General Population Genes Hematopoiesis Hematopoietic Hematopoietic stem cells Human Immune Immunosuppression Impairment Infection Inflammasome Inflammation Inflammatory Interleukin-1 Interleukin-1 beta JAK2 gene Lesion Link Low-Density Lipoproteins Macrophage Maps Mediating Mesenchymal Stem Cells Modeling Modification Mus Mutation Myeloid Cells Myocardial Infarction Necrosis Observational Study Outcome Pathway interactions Patients Population Precision therapeutics Resolution Risk Risk Factors Role Signal Transduction Somatic Mutation Stromal Cells TREM2 gene Techniques Testing Therapeutic Intervention Thick Transplantation Variant Visualization antagonist atherosclerosis risk biobank cardiovascular disorder risk cardiovascular risk factor fitness hematopoietic gene improved insight mouse model mutant novel novel therapeutic intervention premature stem success targeted treatment transcriptome sequencing translational study

项目摘要

PROJECT SUMMARY Despite the success of LDL lowering treatments, atherosclerotic cardiovascular disease remains the major cause of death in the US. Recent clinical trials employing anti-inflammatory therapies have shown a reduction in CVD but led to increased infections. This indicates an urgent need for more precise targeting of anti-inflammatory treatments to patients with higher inflammatory risk. Clonal hematopoiesis (CH) arises from somatic mutations such as in JAK2 or TET2 that provide a fitness advantage to hematopoietic stem cells and outgrowth of clones of blood cells. CH, which increases in frequency with aging, has emerged as a major independent risk factor for CVD. Studies in Tet2-/- and Jak2VF mouse models indicate a central role of macrophage inflammasome activation. We have shown increased atherosclerosis, defective efferocytosis, increased necrosis and inflammatory myeloid cell populations in mice expressing Jak2VF in hematopoietic cells and in CH models. Inhibition of the inflammasome product lL-1β improved features of plaques stabilization including increased fibrous caps and decreased necrotic cores. We propose to investigate the mechanisms linking CH, inflammasomes and pathways acting downstream of lL-1β to atherosclerotic plaque stability. Low frequency Jak2VF alleles are found in 3-4% of general populations and increase CVD risk. Our recent findings indicate that transplantation of only 1.5% Jak2VF cells leads to increased lesions with impaired efferocytosis and increased necrosis. This suggests a new hypothesis that inflammatory crosstalk from Jak2VF Μφs to bystander WT Μφs or stromal cells, promotes plaque destabilization. In Aim 1 we will assess the impact of CH on bystander cells in lesions focusing on Jak2VF -WT Μφ crosstalk. We will evaluate the hypothesis that inflammatory signals from Jak2VF to WT macrophages, such as inflammasome-derived IL-1, increase inflammatory macrophages and decrease Trem2Hi non-inflammatory macrophages, leading to impaired efferocytosis and increased inflammation in mice with low allele burden Jak2VF CH. In Aim2 we will assess the impact of CH on stromal cells in Jak2VF or Tet2-/- CH mice, building on preliminary studies showing that IL-1b antagonism increases fibroblasts in the cap of atherosclerotic lesions. We will also employ a novel Dre-Cre mouse model that allows Jak2VF to be inactivated during lesion regression to test the hypothesis that this increases fibrogenic Trem2Hi macrophages and fibroblasts in lesion caps. In Aim 3 we will collaborate with the Munich Vascular Biobank to assess the impact of CH on human carotid plaque inflammation. Proposed studies may reveal novel genes and pathways acting downstream of inflammasome activation in clonal hematopoiesis to destabilize plaques, and point to new and more precisely targeted therapeutic approaches that are less immunosuppressive than global inhibition of IL-1β or inflammasomes.

项目概要尽管降低低密度脂蛋白的治疗取得了成功，但动脉粥样硬化性心血管疾病仍然是主要原因美国最近采用抗炎疗法的临床试验表明，CVD 的死亡人数有所减少。但导致感染增加，这表明迫切需要更精确的抗炎靶向治疗。对具有较高炎症风险的患者进行治疗由体细胞突变引起的克隆性造血（CH）。例如 JAK2 或 TET2 为造血干细胞和克隆的生长提供适应性优势血细胞的CH随着年龄的增长而增加，已成为一个主要的独立危险因素。 CVD。Tet2-/- 和 Jak2VF 小鼠模型的研究表明巨噬细胞炎性体的核心作用我们已经发现动脉粥样硬化增加、胞吞作用缺陷、坏死增加和在造血细胞和 CH 模型中表达 Jak2VF 的小鼠中的炎症性骨髓细胞群。抑制炎症体产物 lL-1β 可改善斑块稳定的特征，包括增加我们建议研究纤维帽和坏死核心的减少之间的联系。炎症小体和作用于 lL-1β 下游的通路对动脉粥样硬化斑块稳定性的影响低频。 Jak2VF 等位基因存在于 3-4% 的普通人群中，并且会增加 CVD 风险。仅移植 1.5% Jak2VF 细胞会导致病变增加，胞吞作用受损，并增加这提出了一个新的假设，即从 Jak2VF Mφs 到旁观者 WT Mφs 的炎症串扰或基质细胞促进斑块不稳定在目标 1 中，我们将评估 CH 对旁观者细胞的影响。我们将评估炎症信号来自 Jak2VF -WT Mφ 串扰的假设。 Jak2VF 与 WT 巨噬细胞（例如炎症小体衍生的 IL-1）相比，会增加炎症巨噬细胞的数量，减少 Trem2Hi 非炎症巨噬细胞，导致胞吞作用受损和炎症增加在具有低等位基因负荷 Jak2VF CH 的小鼠中，我们将评估 CH 对 Jak2VF 或 Jak2VF 中基质细胞的影响。 Tet2-/- CH 小鼠，基于初步研究表明 IL-1b 拮抗作用会增加帽中的成纤维细胞我们还将采用一种新型 Dre-Cre 小鼠模型，使 Jak2VF 失活。在病变消退过程中测试这一假设，即这会增加纤维化的 Trem2Hi 巨噬细胞和在目标 3 中，我们将与慕尼黑血管生物库合作评估其影响。 CH 对人类颈动脉斑块炎症的影响。拟议的研究可能揭示作用的新基因和途径。克隆造血过程中炎症小体激活的下游，破坏斑块的稳定，并指出新的和更精确的靶向治疗方法，其免疫抑制程度低于 IL-1β 的整体抑制或炎症小体。