巨噬细胞在健康及其他方面的生物物理信号调节

Discovery immunology Pub Date : 2023-08-10 eCollection Date: 2023-01-01 DOI:10.1093/discim/kyad013
Heather M Wilson
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摘要

巨噬细胞在组织发育和稳态、对微生物或肿瘤的先天免疫防御以及通过感染或损伤后的组织再生恢复稳态中发挥着关键作用。采用这种多样功能的能力是由于它们的异质性,这在很大程度上是由它们的发育起源和对微环境信号的反应所驱动的。驱动巨噬细胞表型和功能的最具特征的信号是生化和代谢信号。然而,巨噬细胞对细胞外生物物理环境的感知和反应方式在机械免疫学领域越来越得到认可。这些生物物理线索可以是来自组织成分的信号,例如细胞外基质的组成和电荷或细胞周围组织的形貌、弹性和硬度;以及诸如剪切应力或拉伸的机械力。巨噬细胞在决定疾病是消退还是变成慢性病方面很重要。衰老和疾病,如癌症或纤维化疾病,与组织生物物理环境的显著变化有关,这提供了与来自生物化学和代谢刺激的信号整合的信号,最终决定巨噬细胞的整体功能。这篇综述简要概述了巨噬细胞极化,随后选择了影响巨噬细胞活性的常见生理和应用生物物理刺激,以及驱动下游反应的潜在信号机制。生物物理线索对巨噬细胞稳态和疾病功能的影响,以及相关的临床意义也得到了强调。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modulation of macrophages by biophysical cues in health and beyond.

Macrophages play a key role in tissue development and homeostasis, innate immune defence against microbes or tumours, and restoring homeostasis through tissue regeneration following infection or injury. The ability to adopt such diverse functions is due to their heterogeneous nature, which is driven largely by their developmental origin and their response to signals they encounter from the microenvironment. The most well-characterized signals driving macrophage phenotype and function are biochemical and metabolic. However, the way macrophages sense and respond to their extracellular biophysical environment is becoming increasingly recognized in the field of mechano-immunology. These biophysical cues can be signals from tissue components, such as the composition and charge of extracellular matrix or topography, elasticity, and stiffness of the tissue surrounding cells; and mechanical forces such as shear stress or stretch. Macrophages are important in determining whether a disease resolves or becomes chronic. Ageing and diseases such as cancer or fibrotic disorders are associated with significant changes in the tissue biophysical environment, and this provides signals that integrate with those from biochemical and metabolic stimuli to ultimately dictate the overall function of macrophages. This review provides a brief overview of macrophage polarization, followed by a selection of commonly recognized physiological and applied biophysical stimuli impacting macrophage activity, and the potential signalling mechanisms driving downstream responses. The effects of biophysical cues on macrophages' function in homeostasis and disease and the associated clinical implications are also highlighted.

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