Background Heritable and idiopathic pulmonary arterial hypertension (PAH) are phenotypically identical and associated with mutations in several genes related to TGF beta signaling, including bone morphogenetic protein receptor type 2 (BMPR2), activin receptor-like kinase 1 (ALK1), endoglin (ENG), and mothers against decapentaplegic 9 (SMAD9). Approximately 25% of heritable cases lack identifiable mutations in any of these genes. Methods and Results We used whole exome sequencing to study a three generation family with multiple affected family members with PAH but no identifiable TGF beta mutation. We identified a frameshift mutation in Caveolin-1 (CAV1), which encodes a membrane protein of caveolae abundant in the endothelium and other cells of the lung. An independent de novo frameshift mutation was identified in a child with idiopathic PAH. Western blot analysis demonstrated a reduction in caveolin-1 protein, while lung tissue immunostaining studies demonstrated a reduction in normal caveolin-1 density within the endothelial cell layer of small arteries. Conclusions Our study represents successful elucidation of a dominant Mendelian disorder using whole exome sequencing. Mutations in CAV1 are associated in rare cases with PAH. This may have important implications for pulmonary vascular biology as well as PAH-directed therapeutic development.
R ight ventricular (RV) failure is the predominant cause of death in pulmonary arterial hypertension (PAH), but no RV-specific therapies exist because the underlying mechanisms are poorly understood. Abnormalities of glucose homeostasis and insulin resistance are well described in PAH, 1-4 but less is known about lipid metabolism despite the interrelated nature of glucose and lipid homeostasis. Abnormalities in fatty acid metabolism have been described in experimental models of PAH, 5,6 but systemic and myocardial fatty acid metabolism have not been studied in human PAH. Clinical Perspective on p 1944Given the heart's preference for fatty acids (FAs) as an energy source, 7 understanding FA metabolism may be particularly relevant to understanding RV adaptation to elevated afterload in PAH. We recently showed that RV failure is associated with myocardial steatosis and accumulation of the lipotoxic and proapoptotic mediator ceramide in human heritable PAH because of mutation in bone morphogenetic protein receptor type II (BMPR2). 8 Others and we have also shown indirect evidence of abnormal fatty acid oxidation (FAO) in experimental models of PAH. [9][10][11] The generalizability of these abnormalities in FA metabolism to idiopathic PAH and whether they are a systemic feature in human PAH are unknown.We hypothesized that reduced FA metabolism is ubiquitous in PAH and associated with lipotoxic cardiac steatosis in the RV. We tested this hypothesis by studying blood, RV Background-The mechanisms of right ventricular (RV) failure in pulmonary arterial hypertension (PAH) are poorly understood. Abnormalities in fatty acid (FA) metabolism have been described in experimental models of PAH, but systemic and myocardial FA metabolism has not been studied in human PAH. Methods and Results-We used human blood, RV tissue, and noninvasive imaging to characterize multiple steps in the FA metabolic pathway in PAH subjects and controls. Circulating free FAs and long-chain acylcarnitines were elevated in PAH patients versus controls. Human RV long-chain FAs were increased and long-chain acylcarnitines were markedly reduced in PAH versus controls. With the use of proton magnetic resonance spectroscopy, in vivo myocardial triglyceride content was elevated in human PAH versus controls ( Sample Collection and AnalysisFasting peripheral blood samples were obtained at the time of clinic visits or at the Vanderbilt General Clinical Research Center. Plasma samples were collected into ethylenediaminetetraacetic acid plasma tubes. Ethylenediaminetetraacetic acid tubes were centrifuged within 45 minutes at 4000 rpm and the plasma fraction immediately aliquoted as 20-µL aliquots and stored at -80ºC. Plasma acylcarnitine samples were analyzed as described previously. 13 The Hormone Assay Core of the Mouse Metabolic Phenotypic Center at Vanderbilt University quantified plasma-free fatty acids by using standard enzymatic reactions. RV Gene Expression ArrayRNA isolation and Microarray techniques have been described previously. 8 All array results...
Rationale: Shorter survival in heritable pulmonary arterial hypertension (HPAH), often due to BMPR2 mutation, has been described in association with impaired right ventricle (RV) compensation. HPAH animal models are insulin resistant, and cells with BMPR2 mutation have impaired fatty acid oxidation, but whether these findings affect the RV in HPAH is unknown.Objectives: To test the hypothesis that BMPR2 mutation impairs RV hypertrophic responses in association with lipid deposition.Methods: RV hypertrophy was assessed in two models of mutant Bmpr2 expression, smooth muscle-specific ( Sm22 R899X ) and universal expression (Rosa26 R899X ). Littermate control mice underwent the same stress using pulmonary artery banding (Low-PAB). Lipid content was assessed in rodent and human HPAH RVs and in Rosa26 R899X mice after metformin administration. RV microarrays were performed using human HPAH and control subjects. Conclusions: These data demonstrate that Bmpr2 mutation affects RV stress responses in a transgenic rodent model. Impaired RV hypertrophy and triglyceride and ceramide deposition are present as a function of RV mutant Bmpr2 in mice; fatty acid oxidation impairment in human HPAH RVs may underlie this finding. Further study of how BMPR2 mediates RV lipotoxicity is warranted.
The heritable form of pulmonary arterial hypertension (PAH) is typically caused by a mutation in bone morphogenic protein receptor type 2 (BMPR2), and mice expressing Bmpr2 mutations develop PAH with features similar to human disease. BMPR2 is known to interact with the cytoskeleton, and human array studies in PAH patients confirm alterations in cytoskeletal pathways. The goal of this study was to evaluate cytoskeletal defects in BMPR2-associated PAH. Expression arrays on our Bmpr2 mutant mouse lungs revealed cytoskeletal defects as a prominent molecular consequence of universal expression of a Bmpr2 mutation (Rosa26-Bmpr2(R899X)). Pulmonary microvascular endothelial cells cultured from these mice have histological and functional cytoskeletal defects. Stable transfection of different BMPR2 mutations into pulmonary microvascular endothelial cells revealed that cytoskeletal defects are common to multiple BMPR2 mutations and are associated with activation of the Rho GTPase, Rac1. Rac1 defects are corrected in cell culture and in vivo through administration of exogenous recombinant human angiotensin-converting enzyme 2 (rhACE2). rhACE2 reverses 77% of gene expression changes in Rosa26-Bmpr2(R899X) transgenic mice, in particular, correcting defects in cytoskeletal function. Administration of rhACE2 to Rosa26-Bmpr2(R899X) mice with established PAH normalizes pulmonary pressures. Together, these findings suggest that cytoskeletal function is central to the development of BMPR2-associated PAH and that intervention against cytoskeletal defects may reverse established disease.
DJ, Majka SM. ABCG2 pos lung mesenchymal stem cells are a novel pericyte subpopulation that contributes to fibrotic remodeling.
Pulmonary arterial hypertension (PAH) is a complex, multifactorial disease in which an increase in pulmonary vascular resistance leads to increased afterload on the right ventricle (RV), causing right heart failure and death. Our understanding of the pathophysiology of RV dysfunction in PAH is limited but is constantly improving. Increasing evidence suggests that in PAH RV dysfunction is associated with various components of metabolic syndrome, such as insulin resistance, hyperglycemia, and dyslipidemia. The relationship between RV dysfunction and fatty acid/glucose metabolites is multifaceted, and in PAH it is characterized by a shift in utilization of energy sources toward increased glucose utilization and reduced fatty acid consumption. RV dysfunction may be caused by maladaptive fatty acid metabolism resulting from an increase in fatty acid uptake by fatty acid transporter molecule CD36 and an imbalance between glucose and fatty acid oxidation in mitochondria. This leads to lipid accumulation in the form of triglycerides, diacylglycerol, and ceramides in the cytoplasm, hallmarks of lipotoxicity. Current interventions in animal models focus on improving RV dysfunction through altering fatty acid oxidation rates and limiting lipid accumulation, but more specific and effective therapies may be available in the coming years based on current research. In conclusion, a deeper understanding of the complex mechanisms of the metabolic remodeling of the RV will aid in the development of targeted treatments for RV failure in PAH.Keywords: pulmonary arterial hypertension, metabolic syndrome, fatty acid oxidation, glucose oxidation, right ventricle, fatty acid transporter (CD36), glucose transporters, insulin resistance, right ventricular lipotoxicity, lipotoxic cardiomyopathy. Pulmonary arterial hypertension (PAH) is a devastating disease characterized by progressive obliteration of the pulmonary vasculature, right heart failure, and death. The pathobiology of PAH is complex, and presently there is no curative treatment. Although PAH is classically thought to be a disease of the lungs, the role played by right ventricular (RV) hypertrophy and dysfunction that ultimately results in right heart failure and death is understudied. RV failure is the most common cause of death in PAH, 1 yet there are no specific therapies aimed at improving RV adaptation or function. However, it is well documented that pathological RV remodeling in PAH can be reversed with lung transplantation or with pulmonary thromboendarterectomy in chronic thromboembolic pulmonary hypertension (CTEPH). 2-9 The molecular mechanisms that mediate the transition from adaptive RV compensation to failure or that can promote reversible RV remodeling are presently unknown. Recently, our group and others have found evidence indicating that intracellular lipid accumulation and decreased fatty acid oxidation (FAO) may be features of RV failure related to PAH. [10][11][12][13] This raises a question: In PAH, can accumulation of fatty acids promote RV dysfun...
Rationale: In heritable pulmonary arterial hypertension with germline mutation in the bone morphogenetic protein receptor type 2 (BMPR2) gene, right ventricle (RV) dysfunction is associated with RV lipotoxicity; however, the underlying mechanism for lipid accumulation is not known.Objectives: We hypothesized that lipid accumulation in cardiomyocytes with BMPR2 mutation occurs owing to alterations in lipid transport and impaired fatty acid oxidation (FAO), which is exacerbated by a high-lipid (Western) diet (WD).Methods: We used a transgenic mouse model of pulmonary arterial hypertension with mutant BMPR2 and generated a cardiomyocyte cell line with BMPR2 mutation. Electron microscopy and metabolomic analysis were performed on mouse RVs.Measurements and Main Results: By metabolomics analysis, we found an increase in long-chain fatty acids in BMPR2 mutant mouse RVs compared with controls, which correlated with cardiac index. BMPR2-mutant cardiomyocytes had increased lipid compared with controls. Direct measurement of FAO in the WD-fed BMPR2-mutant RV showed impaired palmitate-linked oxygen consumption, and metabolomics analysis showed reduced indices of FAO. Using both mutant BMPR2 mouse RVs and cardiomyocytes, we found an increase in the uptake of 14 C-palmitate and fatty acid transporter CD36 that was further exacerbated by WD.Conclusions: Taken together, our data suggest that impaired FAO and increased expression of the lipid transporter CD36 are key mechanisms underlying lipid deposition in the BMPR2-mutant RV, which are exacerbated in the presence of dietary lipids. These findings suggest important features leading to RV lipotoxicity in pulmonary arterial hypertension and may point to novel areas of therapeutic intervention.
Endothelial-to-mesenchymal transition (EndMT) is a process in which endothelial cells lose polarity and cell-to cell contacts, and undergo a dramatic remodeling of the cytoskeleton. It has been implicated in initiation and progression of pulmonary arterial hypertension (PAH). However, the characteristics of cells which have undergone EndMT cells in vivo have not been reported and so remain unclear. To study this, sugen5416 and hypoxia (SuHx)-induced PAH was established in Cdh5-Cre/Gt(ROSA)26Sor/J double transgenic mice, in which GFP was stably expressed in pan-endothelial cells. After 3 wk of SuHx, flow cytometry and immunohistochemistry demonstrated CD144-negative and GFP-positive cells (complete EndMT cells) possessed higher proliferative and migratory activity compared with other mesenchymal cells. While CD144-positive and α-smooth muscle actin (α-SMA)-positive cells (partial EndMT cells) continued to express endothelial progenitor cell markers, complete EndMT cells were Sca-1-rich mesenchymal cells with high proliferative and migratory ability. When transferred in fibronectin-coated chamber slides containing smooth muscle media, α-SMA robustly expressed in these cells compared with cEndMT cells that were grown in maintenance media. Demonstrating additional paracrine effects, conditioned medium from isolated complete EndMT cells induced enhanced mesenchymal proliferation and migration and increased angiogenesis compared with conditioned medium from resident mesenchymal cells. Overall, these findings show that EndMT cells could contribute to the pathogenesis of PAH both directly, by transformation into smooth muscle-like cells with higher proliferative and migratory potency, and indirectly, through paracrine effects on vascular intimal and medial proliferation.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.