Neutrophil accumulation and NET release contribute to thrombosis in HIT
Kandace Gollomp, … , M. Anna Kowalska, Mortimer Poncz
Kandace Gollomp, … , M. Anna Kowalska, Mortimer Poncz
Published September 20, 2018
Citation Information: JCI Insight. 2018;3(18):e99445. https://doi.org/10.1172/jci.insight.99445.
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Research Article Hematology Inflammation

Neutrophil accumulation and NET release contribute to thrombosis in HIT

Abstract

Heparin-induced thrombocytopenia (HIT) is an immune-mediated thrombocytopenic disorder associated with a severe prothrombotic state. We investigated whether neutrophils and neutrophil extracellular traps (NETs) contribute to the development of thrombosis in HIT. Using an endothelialized microfluidic system and a murine passive immunization model, we show that HIT induction leads to increased neutrophil adherence to venous endothelium. In HIT mice, endothelial adherence is enhanced immediately downstream of nascent venous thrombi, after which neutrophils undergo retrograde migration via a CXCR2-dependent mechanism to accumulate into the thrombi. Using a microfluidic system, we found that PF4 binds to NETs, leading them to become compact and DNase resistant. PF4-NET complexes selectively bind HIT antibodies, which further protect them from nuclease digestion. In HIT mice, inhibition of NET formation through Padi4 gene disruption or DNase treatment limited venous thrombus size. PAD4 inactivation did affect arterial thrombi or severity of thrombocytopenia in HIT. Thus, neutrophil activation contributes to the development of venous thrombosis in HIT by enhancing neutrophil-endothelial adhesion and neutrophil clot infiltration, where incorporated PF4-NET-HIT antibody complexes lead to thrombosis propagation. Inhibition of neutrophil endothelial adhesion, prevention of neutrophil chemokine-dependent recruitment of neutrophils to thrombi, or suppression of NET release should be explored as strategies to prevent venous thrombosis in HIT.

Authors

Kandace Gollomp, Minna Kim, Ian Johnston, Vincent Hayes, John Welsh, Gowthami M. Arepally, Mark Kahn, Michele P. Lambert, Adam Cuker, Douglas B. Cines, Lubica Rauova, M. Anna Kowalska, Mortimer Poncz

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Figure 4

Microfluidic studies illustrating PF4-NET interactions.

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Microfluidic studies illustrating PF4-NET interactions. (A) Representati...
(A) Representative confocal images of NETs exposed to PF4 or buffer, demonstrating change in morphology. PF4 specifically adhered to the NET DNA, visualized by labeling with a polyclonal anti-PF4 antibody (α-PF4 Ab), causing the NETs to become compact. An arrow indicating direction of flow is included. Scale bar: 100 μ. Same microscope and acquisition software as in Figure 1A. (B) Mean ± 1 SD of area covered by NETs exposed to the indicated PF4 concentration. NET area and mean fluorescent intensity (MFI) of SYTOX-labeled cfDNA are shown. n = 8–15 channels per PF4 concentration, with visualization of 30–60 NETs per channel, was used in the NET area analysis. n = 3–6 channels per PF4 concentration, with visualization of 30–60 NETs per channel, was used in the analysis of MFI. Comparative statistical analysis was performed by Kruskal-Wallis 1-way ANOVA. (C) Representative wide-field images of NETs with or without PF4 (10 μg/ml), simultaneously infused with DNase I (100 U/ml). Near-complete digestion of NETs not exposed to PF4 occurred within 2 minutes, whereas NETs compacted with PF4 remained intact. An arrow indicating direction of flow is included. Scale bar: 100 μ. (D) Graph showing representative changes in NET fluorescent intensity observed over a 5-minute infusion of DNase I (100 U/ml) in the presence of 0–10 μg/ml PF4. These studies were based on analysis of 3–4 channels for each condition, with 30–60 NETs observed in each channel. (E) Confocal images were taken of 3 channels per condition following digestion, and the residual mean volume ± 1 SD of 30–100 NETs per channel was measured. Comparative statistical analysis was done by Kruskal-Wallis 1-way ANOVA.