Pulsatile flow dynamics maintain pulmonary artery architecture
Stephen B. Spurgin, Lauren Thai, Tina C. Wan, Christopher P. Chaney, Mitzy A. Cowdin, Surendranath Veeram Reddy, Tarique Hussain, Munes Fares, M. Luisa Iruela-Arispe, Thomas Carroll, Andrew D. Spearman, Ondine Cleaver
Stephen B. Spurgin, Lauren Thai, Tina C. Wan, Christopher P. Chaney, Mitzy A. Cowdin, Surendranath Veeram Reddy, Tarique Hussain, Munes Fares, M. Luisa Iruela-Arispe, Thomas Carroll, Andrew D. Spearman, Ondine Cleaver
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Research Article Cardiology Vascular biology

Pulsatile flow dynamics maintain pulmonary artery architecture

Abstract

Single-ventricle congenital heart disease (SV-CHD) is a uniformly lethal condition requiring the Glenn surgery, which as a side effect eliminates arterial pulsatility and contributes to pulmonary vascular complications. In Glenn patients, we quantified pulsatility loss in each dimension of force (flow, pressure, and stretch) using cardiac catheterization and MRI. To model and investigate the individual impact of each dimension of pulsatility loss on the pulmonary vasculature, we applied isolated pulsatile and non-pulsatile mechanical stimuli to pulmonary artery endothelial cells (ECs) in vitro. We found that each dimension of force triggered distinct transcriptional responses, revealing force-specific regulation of structural and signaling pathways. Pulsatile stretch uniquely stimulated EC secretion of PDGFB, a key driver of vascular smooth muscle cell (vSMC) recruitment. In a rat Glenn model, loss of pulsatility led to vascular wall thinning, loss of EC PDGFB, and reduced activation of smooth muscle PDGFBRβ, confirming in vivo relevance. Our findings uncover a mechanistic link between endothelial stretch sensing and PDGFB-mediated EC-vSMC crosstalk, essential for maintaining pulmonary artery architecture. Clinically, these insights suggest that restoring or mimicking pulsatile forces may help preserve vascular integrity and prevent remodeling in patients with SV-CHD.

Authors

Stephen B. Spurgin, Lauren Thai, Tina C. Wan, Christopher P. Chaney, Mitzy A. Cowdin, Surendranath Veeram Reddy, Tarique Hussain, Munes Fares, M. Luisa Iruela-Arispe, Thomas Carroll, Andrew D. Spearman, Ondine Cleaver

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Figure 6

Loss of smooth muscle layer in pulmonary arteries of rats after Glenn surgery.

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Loss of smooth muscle layer in pulmonary arteries of rats after Glenn su...
(A) Example sagittal sections of lung tissue from sham- and Glenn-operated rats, stained by immunohistochemistry for αSMA. Black boxes show typical perihilar location of analysis of the most proximal portions of pulmonary arteries examined. Scale bars: 2 mm. (B) Left: Example images of αSMA+ media thickness from 3 different sham-operated rats. Ten distributed measurements per vessel were taken and the mean thickness was used; yellow bars show example measurements. Right: Example images of αSMA+ media thickness from 3 different Glenn rats. Scale bars: 20 μm. (C) Quantification of αSMA+ tunica media from proximal arteries versus veins. (D) Schematic showing approximate location of pulmonary vessels assayed in A, B, and E. (E) Examples of images of αSMA+ media thickness in distal arterioles from 3 different sham (left panels) and Glenn (right panels). Scale bar: 25 μm. Artery regions analyzed were chosen as those vessels near lung periphery and <50 μm in size. Distal vessels <1 mm were identified using immunofluorescent staining for CDH5 (green) in sham (n = 3 rats, n = 42 vessels) and Glenn (n = 3 rats, n = 56 vessels) rat lungs. (F and G) Staining of αSMA (pink) was used to quantify the circumferential coverage (F) and intensity (G) αSMA surrounding these arterioles. **P ≤ 0.01; ***P ≤ 0.001 by unpaired, 2-tailed Student’s t test with Welch’s correction (C, F, and G).