Authors: Ya Guan, Min Zhang, Jiyeon Song, Marcos Negrete, Tyler Adcock, Reeva Kandel, Luigi Racioppi, Sharon Gerecht
Published: 2025-03-12
Source: Full article
AbstractMacrophages are essential for immune responses and maintaining tissue homeostasis, exhibiting a wide range of phenotypes depending on their microenvironment. The extracellular matrix (ECM) is a vital component that provides structural support and organization to tissues, with matrix stiffness acting as a key regulator of macrophage behavior. Using physiologically relevant 3D stiffening hydrogel models, it is found that increased matrix stiffness alone promoted macrophage polarization toward a pro‐regenerative phenotype, mimicking the effect of interleukin‐4(IL‐4) in softer matrices. Blocking Calcium/calmodulin‐dependent kinase kinase 2 (CaMKK2) selectively inhibited stiffness‐induced macrophage polarization without affecting IL‐4‐driven pro‐regenerative pathways. In functional studies, CaMKK2 deletion prevented M2‐like/pro‐tumoral polarization caused by matrix stiffening, which in turn hindered tumor growth. In a murine wound healing model, loss of CaMKK2 impaired matrix stiffness‐mediated macrophage accumulation, ultimately disrupting vascularization. These findings highlight the critical role of CaMKK2 in the macrophage mechanosensitive fate determination and gene expression program, positioning this kinase as a promising therapeutic target to selectively modulate macrophage responses in pathologically stiff tissues.