Neutrophil extracellular traps promote fibrous vascular occlusions in chronic thrombosis

Acute pulmonary embolism generally resolves within 6 months. However, if the thrombus is infected, venous thrombi transform into fibrotic vascular obstructions leading to chronic deep vein thrombosis and/or chronic thromboembolic pulmonary hypertension (CTEPH), but precise mechanisms remain unclear. Neutrophils are crucial in sequestering pathogens; therefore, we investigated the role of neutrophil extracellular traps (NETs) in chronic thrombosis. Because chronic pulmonary thrombotic obstructions are biologically identical to chronic deep venous thrombi, the murine inferior vena cava ligation model was used to study the transformation of acute to chronic thrombus. Mice with staphylococcal infection presented with larger thrombi containing more neutrophils and NETs but less resolution. Targeting NETs with DNase1 diminished fibrosis and promoted thrombus resolution. For translational studies in humans, we focused on patients with CTEPH, a severe type of deep venous and pulmonary artery fibrotic obstruction after thrombosis. Neutrophils, markers of neutrophil activation, and NET formation were increased in CTEPH patients. NETs promoted the differentiation of monocytes to activated fibroblasts with the same cellular phenotype as fibroblasts from CTEPH vascular occlusions. RNA sequencing of fibroblasts isolated from thrombo-endarterectomy specimens and pulmonary artery biopsies revealed transforming growth factor-beta (TGF-beta) as the central regulator, a phenotype which was replicated in mice with fibroblast-specific TGF-beta overactivity. Our findings uncover a role of neutrophil-mediated inflammation to enhance TGF-beta signaling, which leads to fibrotic thrombus remodeling. Targeting thrombus NETs with DNases may serve as a new therapeutic concept to treat thrombosis and prevent its sequelae.

Automated summary

The study reveals the significant role of neutrophil extracellular traps (NETs) in chronic thrombosis, with targeting these NETs potentially serving as a new therapeutic concept to treat thrombosis and prevent its sequelae.