Laurent Calvier1,2,3,4, Philippe Boucher5, Joachim Herz3,4,6,7,8, Georg Hansmann1,2. 1. From the Department of Pediatric Cardiology and Critical Care (L.C., G.H.), Hannover Medical School, Germany. 2. Pulmonary Vascular Research Center (L.C., G.H.), Hannover Medical School, Germany. 3. Department of Molecular Genetics (L.C., J.H.), University of Texas Southwestern Medical Center, Dallas. 4. Center for Translational Neurodegeneration Research (L.C., J.H.), University of Texas Southwestern Medical Center, Dallas. 5. UMR CNRS 7021, University of Strasbourg, Illkirch Cedex, France (P.B.). 6. Department of Neuroscience (J.H.), University of Texas Southwestern Medical Center, Dallas. 7. Department of Neurology and Neurotherapeutics (J.H.), University of Texas Southwestern Medical Center, Dallas. 8. Department of Neuroanatomy, Center for Neuroscience, Albert-Ludwigs-University, Freiburg, Germany (J.H.).
Abstract
RATIONALE: Arterial remodeling-a hallmark of many cardiovascular pathologies including pulmonary arterial hypertension (PAH)-is regulated by TGFβ1 (transforming growth factor-β1)-TGFβ receptors and the antagonistic, vasoprotective BMPR2 (bone morphogenetic protein receptor 2)-PPARγ (peroxisome proliferator-activated receptor-γ) axis. However, it is unclear which factors drive detrimental TGFβ1 pathways in the hypertensive pulmonary vasculature. OBJECTIVE: We hypothesized that LRP1 (low-density lipoprotein receptor-related protein 1) expression is decreased in PAH, leading to enhancement (disinhibition) of TGFβ1 signals and that the PPARγ agonist pioglitazone can restore vascular homeostasis and prevent PAH resulting from LRP1 deletion in vascular smooth muscle cells (SMCs). METHODS AND RESULTS: Targeted deletion of LRP1 in vascular SMC (smLRP1-/-) in mice disinhibited TGFβ1-CTGF (connective tissue growth factor) signaling, leading to spontaneous PAH and distal pulmonary arterial muscularization as assessed by closed-chest cardiac catheterization and anti-αSMA staining. Pioglitazone inhibited the canonical TGFβ1-CTGF axis in human pulmonary artery SMC and smLRP1-/- main pulmonary artery (CTGF and NOX4) and reversed PAH in smLRP1-/- mice. TGFβ1 boosted pSmad3 in PASMC from smLRP1-/- mice versus controls. Pioglitazone-activated PPARγ binds to Smad3 in human pulmonary artery SMC (coimmunoprecipitation), thereby blocking its phosphorylation and overriding LRP1 deficiency. Finally, mRNA and protein expression of LRP1 was decreased in pulmonary plexiform lesions of patients with end-stage idiopathic PAH (laser capture microdissection, qPCR, and immunohistochemistry). Downregulation of LRP1 protein was also demonstrated in explanted PASMC from patients with PAH and accompanied by enhanced TGFβ1-pSmad3-CTGF signaling and increased TGFβ1-induced PASMC proliferation that was prevented by pioglitazone. CONCLUSIONS: Here, we identify LRP1 as an integrator of TGFβ1-mediated mechanisms that regulate vascular remodeling in mice and clinical PAH and PPARγ as a therapeutic target that controls canonical TGFβ1 pathways. Hence, pharmacologic PPARγ activation represents a promising new therapy for patients with PAH who lack the vasoprotective LRP1 in vascular SMC.
RATIONALE: Arterial remodeling-a hallmark of many cardiovascular pathologies including pulmonary arterial hypertension (PAH)-is regulated by TGFβ1 (transforming growth factor-β1)-TGFβ receptors and the antagonistic, vasoprotective BMPR2 (bone morphogenetic protein receptor 2)-PPARγ (peroxisome proliferator-activated receptor-γ) axis. However, it is unclear which factors drive detrimental TGFβ1 pathways in the hypertensive pulmonary vasculature. OBJECTIVE: We hypothesized that LRP1 (low-density lipoprotein receptor-related protein 1) expression is decreased in PAH, leading to enhancement (disinhibition) of TGFβ1 signals and that the PPARγ agonist pioglitazone can restore vascular homeostasis and prevent PAH resulting from LRP1 deletion in vascular smooth muscle cells (SMCs). METHODS AND RESULTS: Targeted deletion of LRP1 in vascular SMC (smLRP1-/-) in mice disinhibited TGFβ1-CTGF (connective tissue growth factor) signaling, leading to spontaneous PAH and distal pulmonary arterial muscularization as assessed by closed-chest cardiac catheterization and anti-αSMA staining. Pioglitazone inhibited the canonical TGFβ1-CTGF axis in humanpulmonary artery SMC and smLRP1-/- main pulmonary artery (CTGF and NOX4) and reversed PAH in smLRP1-/- mice. TGFβ1 boosted pSmad3 in PASMC from smLRP1-/- mice versus controls. Pioglitazone-activated PPARγ binds to Smad3 in humanpulmonary artery SMC (coimmunoprecipitation), thereby blocking its phosphorylation and overriding LRP1 deficiency. Finally, mRNA and protein expression of LRP1 was decreased in pulmonary plexiform lesions of patients with end-stage idiopathic PAH (laser capture microdissection, qPCR, and immunohistochemistry). Downregulation of LRP1 protein was also demonstrated in explanted PASMC from patients with PAH and accompanied by enhanced TGFβ1-pSmad3-CTGF signaling and increased TGFβ1-induced PASMC proliferation that was prevented by pioglitazone. CONCLUSIONS: Here, we identify LRP1 as an integrator of TGFβ1-mediated mechanisms that regulate vascular remodeling in mice and clinical PAH and PPARγ as a therapeutic target that controls canonical TGFβ1 pathways. Hence, pharmacologic PPARγ activation represents a promising new therapy for patients with PAH who lack the vasoprotective LRP1 in vascular SMC.
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