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.
Background Heterogeneity in response to treatment of pulmonary arterial hypertension (PAH) is a major challenge to improving outcome in this disease. Although vasodilator responsive PAH (VR-PAH) accounts for a minority of cases, VR-PAH has a pronounced response to calcium channel blockers and better survival than non-responsive PAH (VN-PAH). We hypothesized that VR-PAH has a different molecular etiology from VN-PAH that can be detected in the peripheral blood. Methods and Results Microarrays of cultured lymphocytes from VR-PAH and VN-PAH patients followed at Vanderbilt University were performed with quantitative PCR performed on peripheral blood for the 25 most different genes. We developed a decision tree to identify VR-PAH patients based on the results with validation in a second VR-PAH cohort from the University of Chicago. We found broad differences in gene expression patterns on microarray analysis including cell-cell adhesion factors, cytoskeletal and rho/GTPase genes. 13/25 genes tested in whole blood were significantly different: EPDR1, DSG2, SCD5, P2RY5, MGAT5, RHOQ, UCHL1, ZNF652, RALGPS2, TPD52, MKNL1, RAPGEF2 and PIAS1. Seven decision trees were built using expression levels of two genes as the primary genes: DSG2, a desmosomal cadherin involved in Wnt/β-catenin signaling, and RHOQ, which encodes a cytoskeletal protein involved in insulin-mediated signaling. These trees correctly identified 5/5 VR-PAH in the validation cohort. Conclusions VR-PAH and VN-PAH can be differentiated using RNA expression patterns in peripheral blood. These differences may reflect different molecular etiologies of the two PAH phenotypes. This biomarker methodology may identify PAH patients that have a favorable treatment response.
Background Pulmonary arterial hypertension (PAH) is a proliferative disease of the pulmonary vasculature which preferentially affects females. Estrogens, such as the metabolite 16α-hydroxyestrone (16αOHE), may contribute to PAH pathogenesis; and, alterations in cellular energy metabolism associate with PAH. We hypothesized that 16αOHE promotes heritable PAH (HPAH) via miR-29 family upregulation, and that antagonism of miR-29 would attenuate pulmonary hypertension in transgenic mouse models of Bmpr2 mutation. Methods and Results MicroRNA (miR) array profiling of human lung tissue found elevation of miRs associated with energy metabolism, including the miR-29 family, among HPAH patients. miR-29 expression was 2-fold higher in Bmpr2 mutant mice lungs at baseline compared to controls, and 4 to 8-fold higher in Bmpr2 mice exposed to 16αOHE 1.25 μg/hr for 4 weeks. Blot analyses of Bmpr2 mouse lung protein showed significant reductions in PPARγ and CD36 in those mice exposed to 16αOHE, as well as from protein derived from HPAH lungs compared to controls. Bmpr2 mice treated with anti-miR-29 (α-miR29) (20mg/kg injections for 6 weeks) had improvements in hemodynamic profile, histology, and markers of dysregulated energy metabolism compared to controls. PASMCs derived from Bmpr2 murine lungs demonstrated mitochondrial abnormalities, which improved with α-miR29 transfection in vitro; endothelial-like cells derived from HPAH patient iPS cell lines were similar, and improved with α-miR29 treatment. Conclusions 16αOHE promotes the development of HPAH via upregulation of miR-29, which alters molecular and functional indices of energy metabolism. Antagonism of miR-29 improves in vivo and in vitro features of HPAH, and reveals a possible novel therapeutic target.
Pulmonary hypertension (PH) is a frequent complication of left heart disease and parenchymal lung disease, and it portends increased mortality. A growing number of medications are approved for the treatment of World Health Organization (WHO) group 1 pulmonary arterial hypertension (PAH). However, they are not well studied in PH of other etiologies (WHO groups 2-5). We sought to assess treatment approaches used by PAH referral centers in this diverse group of patients. We developed a semiquantitative online survey designed to evaluate the use of PAH-approved therapy by pulmonary vascular disease centers in the United States for management of nongroup 1 PH. Thirty of 50 centers completed the survey. Almost all centers (93%) reported using PAH therapy for patients with non-group 1 PH, including 77% with group 2 PH and 80% with group 3 PH. Elevated transpulmonary gradient or pulmonary vascular resistance and the presence of right ventricular (RV) dysfunction were commonly cited as supporting use of PAH therapy in patients with PH secondary to left heart disease. For patients with PH and concomitant parenchymal lung disease, degree of pulmonary function impairment and RV dysfunction were most important in influencing use of PAH therapy. In conclusion, pulmonary vascular disease treatment centers use PAH-approved therapy for patients with WHO group 2-5 PH, mostly relying on hemodynamics and assessment of RV function to identify candidates for therapy. Clinical trials designed to test the efficacy of PAH therapy in PH due to left heart and lung disease are needed, as clinical practice has extended beyond the evidence for these etiologies of PH.
Pulmonary arterial hypertension (PAH) is associated with metabolic derangements including insulin resistance, although their effects on the cardiopulmonary disease are unclear. We hypothesized that insulin resistance promotes pulmonary hypertension (PH) development and mutations in type 2 bone morphogenetic protein receptor (BMPR2) cause cellular insulin resistance. Using a BMPR2 transgenic murine model of PAH and two models of inducible diabetes mellitus, we explored the impact of hyperglycemia and/or hyperinsulinemia on development and severity of PH. We assessed insulin signaling and insulin-mediated glucose uptake in human endothelial cells with and without mutations in BMPR2. PH developed in control mice fed a Western diet and PH in BMPR2 mutant mice was increased by Western diet. Pulmonary artery pressure correlated strongly with fasting plasma insulin but not glucose. Reactive oxygen species were increased in lungs of insulin-resistant animals. BMPR2 mutation impaired insulin-mediated endothelial glucose uptake via reduced glucose transporter translocation despite intact insulin signaling. Experimental hyperinsulinemia is strongly associated with PH in both control and BMPR2-mutant mice, though to a greater degree in those with BMPR2 mutation. Human pulmonary endothelial cells with BMPR2 mutation have evidence of reduced glucose uptake due to impaired glucose transporter translocation. These experiments support a role for hyperinsulinemia in pulmonary vascular disease.
Pulmonary hypertension (PH) occurs when the pulmonary vasculature is itself diseased or becomes affected secondarily by comorbid conditions, commonly left heart or lung disease. The high prevalence of chronic cardiopulmonary conditions among patients served by Veterans Health Administration (VHA) suggests this population may be particularly susceptible to PH. We sought to identify clinical features and outcomes in veterans diagnosed with PH. We utilized the VHA Corporate Data Warehouse to identify veterans diagnosed between January 1, 2003 and September 30, 2015, assess relevant patient characteristics and their survival time. The effects of PH subtype and baseline factors on outcome were estimated by Cox modeling. There were 110,564 veterans diagnosed with PH during the study period. These veterans were predominantly male, had median age 70.2, and had a high burden of comorbid conditions. PH was frequently due to left heart and/or lung disease. Average survival after PH diagnosis was 3.88 years. Compared with other types, PH due to left heart disease, lung disease or both had shorter survival. This large retrospective study of veterans demonstrates the significance of PH due to left heart and/or lung disease which was common and had high risk of death. Multi-comorbidity was common and added to risk. These findings underscore the need for risk assessment tools for subjects with non-Group 1 PH and novel management strategies to improve their outcome. This study details the largest retrospective cohort assembled for evaluation of secondary PH and allows hypothesis-generating inquiries into these common conditions that are rarely prospectively studied.
Pulmonary hypertension affects about one in four patients with advanced chronic kidney disease and significantly increases the risk of death. Kidney transplantation is the recommended management option for patients with progressive or end‐stage kidney disease. However, the resource‐limited nature of kidney transplantation and its intensive peri‐operative and posttransplantation management motivates careful consideration of potential candidates’ medical conditions to optimally utilize available graft organs. Since pulmonary hypertension is known to increase peri‐operative morbidity and mortality among patients living with chronic kidney disease, we performed a retrospective cohort study to assess the impact of pretransplantation pulmonary hypertension on posttransplantation outcome. All patients who underwent single‐organ kidney transplantation at our center in calendar years 2010 and 2011 were identified and the presence of pulmonary hypertension was determined from pretransplantation echocardiography. Outcome was assessed at 5 years following kidney transplantation. Of 350 patients who were included, 117 (33%) had evidence of pulmonary hypertension. The risk of death, graft dysfunction, or graft failure at 5 years after kidney transplantation was higher among those with pulmonary hypertension, primarily owing to an increased risk of graft dysfunction. Importantly, in this institutional cohort of kidney transplant recipients, pretransplant pulmonary hypertension was not associated with a difference in posttransplant survival at 5 years. While institutional and regional differences in outcome can be expected, this report suggests that carefully selected patients with pulmonary hypertension receive similar long‐term benefits from kidney transplantation.
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