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引用次数: 2
摘要
新兴的免疫医学领域已准备好扩展到肿瘤学以外的领域(Aghajanian et al., 2022)。在过去的几十年里,许多基于细胞的治疗方法被提出、发展并应用于临床。最近爆发的靶向细胞疗法主要针对肿瘤恶性肿瘤。与此同时,心脏病学研究人员一直在研究导致心脏病的各种细胞类型,特别是那些导致组织纤维化和心肌功能障碍的细胞类型。我们的实验室在2019年提出将这两个学科结合起来:靶向细胞疗法是否可以用于改善心脏纤维化(Aghajanian et al., 2019)。虽然初步结果令人鼓舞,但用于制造免疫细胞的基因工程方法如果直接转化为人类,将导致持久的细胞溶解性T细胞。这将引起安全问题,因为活化的成纤维细胞是急性损伤的必要细胞。因此,我们开发了一种新的技术,将修饰的RNA传递到体内的T细胞,从而产生一种短暂的抗活化成纤维细胞治疗(Rurik et al., 2022)。虽然这些细胞只有几天的活性,但足以显著改善小鼠心脏纤维化模型的心功能。这些结果为纤维化疾病的低成本、可扩展、可剂量和免疫治疗铺平了道路。
Uniting Disciplines to Develop Therapeutics: Targeted mRNA Lipid Nanoparticles Reprogram the Immune System In Vivo to Treat Heart Disease.
The burgeoning field of immunomedicine is primed to expand beyond oncology (Aghajanian et al., 2022). Over the past several decades, many cell-based therapies have been proposed, developed, and deployed in the clinic. The recent explosion of targeted cell therapies has primarily been aimed at oncological malignancies. In parallel, cardiology researchers have been investigating the various cell types that contribute to heart diseases, especially those responsible for tissue fibrosis and myocardial dysfunction. Our laboratory proposed in 2019 to unite these two disciplines: could a targeted cell therapy be used to ameliorate cardiac fibrosis (Aghajanian et al., 2019). Although preliminary results were encouraging, the genetic engineering approach used to manufacture immune cells would result in persistent cytolytic T cell if directly translated to humans. This would pose a safety concern since activated fibroblasts are essential cells in the setting of acute injury. Therefore, we developed a novel technology to deliver modified RNA to T cells in vivo, resulting in a transient antiactivated fibroblast therapeutic (Rurik et al., 2022). Although active for only a few days, these cells were sufficient to significantly improve cardiac function in a murine model of cardiac fibrosis. These results pave the way for low-cost and scalable, and dose-able and immune therapy for fibrotic disorders.
期刊介绍:
DNA and Cell Biology delivers authoritative, peer-reviewed research on all aspects of molecular and cellular biology, with a unique focus on combining mechanistic and clinical studies to drive the field forward.
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Gene Structure, Function, and Regulation
Gene regulation
Molecular mechanisms of cell activation
Mechanisms of transcriptional, translational, or epigenetic control of gene expression
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Molecular pathogenesis
Genetic approaches to cancer and autoimmune diseases
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Cellular Organelles
Autophagy
Apoptosis
P bodies
Peroxisosomes
Protein Biosynthesis and Degradation
Regulation of protein synthesis
Post-translational modifications
Control of degradation
Cell-Autonomous Inflammation and Host Cell Response to Infection
Responses to cytokines and other physiological mediators
Evasive pathways of pathogens.