Distal vessel stiffening is an early and pivotal mechanobiological regulator of vascular remodeling and pulmonary hypertension
Fei Liu, Christina Mallarino Haeger, Paul B. Dieffenbach, Delphine Sicard, Izabela Chrobak, Anna Maria F. Coronata, Margarita M. Suárez Velandia, Sally Vitali, Romain A. Colas, Paul C. Norris, Aleksandar Marinković, Xiaoli Liu, Jun Ma, Chase D. Rose, Seon-Jin Lee, Suzy A.A. Comhair, Serpil C. Erzurum, Jacob D. McDonald, Charles N. Serhan, Stephen R. Walsh, Daniel J. Tschumperlin, Laura E. Fredenburgh
Fei Liu, Christina Mallarino Haeger, Paul B. Dieffenbach, Delphine Sicard, Izabela Chrobak, Anna Maria F. Coronata, Margarita M. Suárez Velandia, Sally Vitali, Romain A. Colas, Paul C. Norris, Aleksandar Marinković, Xiaoli Liu, Jun Ma, Chase D. Rose, Seon-Jin Lee, Suzy A.A. Comhair, Serpil C. Erzurum, Jacob D. McDonald, Charles N. Serhan, Stephen R. Walsh, Daniel J. Tschumperlin, Laura E. Fredenburgh
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Research Article Pulmonology Vascular biology

Distal vessel stiffening is an early and pivotal mechanobiological regulator of vascular remodeling and pulmonary hypertension

Abstract

Pulmonary arterial (PA) stiffness is associated with increased mortality in patients with pulmonary hypertension (PH); however, the role of PA stiffening in the pathogenesis of PH remains elusive. Here, we show that distal vascular matrix stiffening is an early mechanobiological regulator of experimental PH. We identify cyclooxygenase-2 (COX-2) suppression and corresponding reduction in prostaglandin production as pivotal regulators of stiffness-dependent vascular cell activation. Atomic force microscopy microindentation demonstrated early PA stiffening in experimental PH and human lung tissue. Pulmonary artery smooth muscle cells (PASMC) grown on substrates with the stiffness of remodeled PAs showed increased proliferation, decreased apoptosis, exaggerated contraction, enhanced matrix deposition, and reduced COX-2–derived prostanoid production compared with cells grown on substrates approximating normal PA stiffness. Treatment with a prostaglandin I2 analog abrogated monocrotaline-induced PA stiffening and attenuated stiffness-dependent increases in proliferation, matrix deposition, and contraction in PASMC. Our results suggest a pivotal role for early PA stiffening in PH and demonstrate the therapeutic potential of interrupting mechanobiological feedback amplification of vascular remodeling in experimental PH.

Authors

Fei Liu, Christina Mallarino Haeger, Paul B. Dieffenbach, Delphine Sicard, Izabela Chrobak, Anna Maria F. Coronata, Margarita M. Suárez Velandia, Sally Vitali, Romain A. Colas, Paul C. Norris, Aleksandar Marinković, Xiaoli Liu, Jun Ma, Chase D. Rose, Seon-Jin Lee, Suzy A.A. Comhair, Serpil C. Erzurum, Jacob D. McDonald, Charles N. Serhan, Stephen R. Walsh, Daniel J. Tschumperlin, Laura E. Fredenburgh

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Figure 6

Iloprost attenuates stiffness-dependent remodeling responses and traction forces in PASMC.

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Iloprost attenuates stiffness-dependent remodeling responses and tractio...
PASMC were plated on discrete stiffness gels and treated with iloprost (3 or 10 μmol/l) or vehicle for 48 hours. (A) Cell density was determined after 48 hours and normalized to 4 hours (n = 3–5; statistical significance determined by 2-way ANOVA, P < 0.0001 stiffness, P < 0.0001 treatment, P = 0.1020 interaction). (B) Collagen concentration was measured in the media of vehicle- and iloprost-treated PASMC after 48 hours and normalized to cell number (n = 2–4; statistical significance determined by 2-way ANOVA, P = 0.0203 stiffness, P = 0.0161 treatment, P = 0.2960 interaction). (CJ) Representative images of immunofluorescent staining for procollagen I (CF) and EDA fibronectin (GJ) in vehicle- and iloprost-treated PASMC. Scale bar: 100 μm. Quantitation of immunostaining for procollagen I (K) (P = 0.0082 stiffness, P = 0.0084 treatment, P = 0.0184 interaction by 2-way ANOVA) and EDA fibronectin (L) (P < 0.0001 stiffness, P = 0.0043 treatment, P = 0.0047 interaction by 2-way ANOVA). (MR) PASMC were plated on polyacrylamide gels with discrete shear moduli of 0.4, 1.6, and 6.4 kPa and, after 24 hours, treated with iloprost (10 μmol/l) or vehicle for 30 minutes. Representative traction fields following treatment with vehicle (row 1, MO) or iloprost (row 2, PR). Each column represents discrete substrate stiffness. Color scale indicates magnitude of traction in kPa. Scale bars: 50 μm. (S) Quantification of traction forces (n = 17–20 cells per group) exerted by vehicle- and iloprost-treated PASMC on discrete stiffness gels (P < 0.0001 stiffness, P < 0.0001 treatment, P < 0.0001 interaction by 2-way ANOVA). Data represent the mean ± SEM.