Jiranuwat Sapudom , Aseel Alatoom , Paul Sean Tipay , Jeremy CM. Teo
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引用次数: 0
Abstract
T-cells are essential components of the immune system, adapting their behavior in response to the mechanical environments they encounter within the body. In pathological conditions like cancer, the extracellular matrix (ECM) often becomes stiffer due to increased density and alignment of collagen fibrils, which can have a significant impact on T-cell function. In this study, we explored how these ECM properties—density and fibrillar alignment—affect T-cell behavior using three-dimensional (3D) collagen matrices that mimic these conditions. Our results show that increased matrix stiffness, whether due to higher density or alignment, significantly suppresses T-cell activation, reduces cytokine production, and limits proliferation, largely through enhanced YAP signaling. Individually, matrix alignment appears to lower actin levels in activated T-cells and changes migration behavior in both resting and activated T-cells, an effect not observed in matrices with randomly oriented fibrils. Notably, inhibiting YAP signaling was able to restore T-cell activation and improve immune responses, suggesting a potential strategy to boost the effectiveness of immunotherapy in stiff ECM environments. Overall, this study provides new insights into how ECM characteristics influence T-cell function, offering potential avenues for overcoming ECM-induced immunosuppression in diseases such as cancer.
T 细胞是免疫系统的重要组成部分,它们会根据在体内遇到的机械环境调整自己的行为。在癌症等病理情况下,细胞外基质(ECM)往往会因为胶原纤维密度和排列的增加而变得更加坚硬,这可能会对 T 细胞的功能产生重大影响。在这项研究中,我们利用三维(3D)胶原蛋白基质模拟这些情况,探索了这些 ECM 特性(密度和纤维排列)如何影响 T 细胞的行为。我们的研究结果表明,基质刚度的增加(无论是由于密度增加还是排列整齐)会显著抑制 T 细胞的活化、减少细胞因子的产生并限制其增殖,这主要是通过 YAP 信号的增强来实现的。单独来看,基质排列似乎会降低活化T细胞的肌动蛋白水平,并改变静止和活化T细胞的迁移行为,而这种效应在随机定向纤维的基质中观察不到。值得注意的是,抑制 YAP 信号传导能恢复 T 细胞活化并改善免疫反应,这表明在僵硬的 ECM 环境中提高免疫疗法效果的潜在策略是可行的。总之,这项研究提供了关于 ECM 特性如何影响 T 细胞功能的新见解,为克服癌症等疾病中 ECM 诱导的免疫抑制提供了潜在的途径。
期刊介绍:
Biomaterials is an international journal covering the science and clinical application of biomaterials. A biomaterial is now defined as a substance that has been engineered to take a form which, alone or as part of a complex system, is used to direct, by control of interactions with components of living systems, the course of any therapeutic or diagnostic procedure. It is the aim of the journal to provide a peer-reviewed forum for the publication of original papers and authoritative review and opinion papers dealing with the most important issues facing the use of biomaterials in clinical practice. The scope of the journal covers the wide range of physical, biological and chemical sciences that underpin the design of biomaterials and the clinical disciplines in which they are used. These sciences include polymer synthesis and characterization, drug and gene vector design, the biology of the host response, immunology and toxicology and self assembly at the nanoscale. Clinical applications include the therapies of medical technology and regenerative medicine in all clinical disciplines, and diagnostic systems that reply on innovative contrast and sensing agents. The journal is relevant to areas such as cancer diagnosis and therapy, implantable devices, drug delivery systems, gene vectors, bionanotechnology and tissue engineering.