Lung vaso-occlusion in sickle cell disease mediated by arteriolar neutrophil-platelet microemboli
Margaret F. Bennewitz, Maritza A. Jimenez, Ravi Vats, Egemen Tutuncuoglu, Jude Jonassaint, Gregory J. Kato, Mark T. Gladwin, Prithu Sundd
Margaret F. Bennewitz, Maritza A. Jimenez, Ravi Vats, Egemen Tutuncuoglu, Jude Jonassaint, Gregory J. Kato, Mark T. Gladwin, Prithu Sundd
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Research Article Hematology Inflammation

Lung vaso-occlusion in sickle cell disease mediated by arteriolar neutrophil-platelet microemboli

Abstract

In patients with sickle cell disease (SCD), the polymerization of intraerythrocytic hemoglobin S promotes downstream vaso-occlusive events in the microvasculature. While vaso-occlusion is known to occur in the lung, often in the context of systemic vaso-occlusive crisis and the acute chest syndrome, the pathophysiological mechanisms that incite lung injury are unknown. We used intravital microscopy of the lung in transgenic humanized SCD mice to monitor acute vaso-occlusive events following an acute dose of systemic lipopolysaccharide sufficient to trigger events in SCD but not control mice. We observed cellular microembolism of precapillary pulmonary arteriolar bottlenecks by neutrophil-platelet aggregates. Blood from SCD patients was next studied under flow in an in vitro microfluidic system. Similar to the pulmonary circulation, circulating platelets nucleated around arrested neutrophils, translating to a greater number and duration of neutrophil-platelet interactions compared with normal human blood. Inhibition of platelet P-selectin with function-blocking antibody attenuated the neutrophil-platelet interactions in SCD patient blood in vitro and resolved pulmonary arteriole microembolism in SCD mice in vivo. These results establish the relevance of neutrophil-platelet aggregate formation in lung arterioles in promoting lung vaso-occlusion in SCD and highlight the therapeutic potential of targeting platelet adhesion molecules to prevent acute chest syndrome.

Authors

Margaret F. Bennewitz, Maritza A. Jimenez, Ravi Vats, Egemen Tutuncuoglu, Jude Jonassaint, Gregory J. Kato, Mark T. Gladwin, Prithu Sundd

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Figure 3

Neutrophil-platelet aggregation is higher in steady state sickle cell disease (SCD) human blood.

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Neutrophil-platelet aggregation is higher in steady state sickle cell di...
African American control (AA) and steady-state SCD (SS) human whole blood was perfused through micro-channels presenting P-selectin, ICAM-1, and IL-8, and interactions of platelets with arrested neutrophils were monitored using quantitative microfluidic fluorescence microscopy (qMFM). (A and B) qMFM images of the same field of view (FOV) at 2 different time points (0 and 120 seconds) showing freely flowing platelets interacting with arrested neutrophils in control (A) and SCD (B) blood. Schematic above each column shows the qMFM step (1 or 2) used to acquire the images in that column. Step 1 of qMFM was used to visualize the footprints of arresting neutrophils (purple) at t = 0 seconds, and step 2 was used to visualize nucleation of freely flowing platelets (green) on top of arrested neutrophils (purple) at t = 120 seconds. The complete time series is shown in Supplemental Videos 17 and 18, respectively. White arrows denote the direction of blood flow. (C) Pseudocolored scanning electron micrograph showing platelets (green) nucleated on top of arrested neutrophils (purple) in SCD blood. Erythrocytes (red) are sequestered within the neutrophil-platelet aggregates. Arrow denotes the direction of flow. Scale bars: 20 μm. (D) Platelet interactions with arrested neutrophils shown as total interactions per minute in a FOV. (E) Total number of neutrophils arresting per minute in a FOV. (F) Platelet interactions with arrested neutrophils shown as the number of platelet interaction events per arrested neutrophil over a 2-minute observation period in a FOV. (G) Lifetime of platelet-neutrophil interactions shown as a cumulative probability distribution. The median lifetime was 2 seconds (control) and 14 seconds (SCD). AE are representative of 6 experiments with 3 control and 3 SCD patients. F and G are representative of 8 experiments with 4 control and 4 SCD patients. Data in DF represent mean ± SEM; means were compared using Student’s t test. Distributions in G were compared using the nonparametric Kruskal-Wallis H test. Each data point in D and E represents a single FOV. Observations were made using multiple FOVs in individual experiments. Each data point in F represents a single neutrophil. #P < 0.05 when comparing control with SCD. Wall shear stress 6 dyn/cm2.FOV: ~14,520 μm2. See Supplemental Methods for details.