异位骨化
医学
细胞外基质
中性粒细胞胞外陷阱
细胞外
神经血管束
病理
髓样
物候学
癌症研究
外伤
坏死
炎症
免疫学
创伤性脑损伤
重组DNA
骨髓
异位表达
体细胞
细胞迁移
体外
内科学
动物研究
药理学
药品
作者
Shan Jiang,Gesine Eis-Janzyk,Ruben Augustin,Holger Kleinertz,Saskia Schröder,Jan Sevecke,Weixin Xie,Haoyan Pan,Isabell Behrens,Samira Weisselberg,Lilly-Charlotte Albertsen,Elena Müller,Simon von Kroge,Assil‐Ramin Alimy,Milad Fal,Michael Amling,Eva Tolosa,Thomas Renné,K H Frosch,Konrad Mader
标识
DOI:10.1126/scitranslmed.ady4761
摘要
After musculoskeletal injury, a considerable proportion of patients develop heterotopic ossification (HO), the formation of bone at ectopic sites. Traumatic HO is a disabling condition, potentially resulting in loss of joint function and compression of neurovascular structures. Available treatment options are often unsuccessful, frequently necessitating surgical resection of HO lesions with a high risk of recurrence. Given that myeloid cells, including neutrophils and macrophages, are among the first cell types to infiltrate injured tissue, the present study explored the relationship of extracellular traps (ETs) with HO formation in humans and mice. Human HO sample analysis revealed the presence of different stages of ETosis, which are clinically associated with increased ET concentrations in the blood. Experimentally, genetic impairment of ET resolution through combined DNase1 and DNase1l3 deficiency led to increased traumatic HO in mice, whereas HO was strongly attenuated by additional deletion of the ET generator Padi4 . Neutrophil depletion impaired local ET formation, reduced HO formation, and blunted genotype-specific differences in HO outcome. In osteogenic precursors, ETs promoted matrix mineralization, and inhibition of ETosis or degradation of cell-free DNA, a major ET component, resulted in reduced osteogenesis. Pharmacological facilitation of ET clearance by dornase alfa, a US Food and Drug Administration–approved recombinant DNase1, or inhibition of ETs by the PADI4 inhibitor GSK484, resulted in inhibition of traumatic HO formation in mice without adversely affecting systemic bone remodeling. Together, our clinical and experimental findings demonstrate that traumatic HO is mediated by targetable neutrophil-dependent mechanisms, with altered ET formation contributing to these effects.