Rationale Repopulation of the injured heart with new, functional cardiomyocytes remains a daunting challenge for cardiac regenerative medicine. An ideal therapeutic approach would involve an effective method at achieving direct conversion of injured areas to functional tissue in situ. Objective The aim of this study was to develop a strategy that identified and evaluated the potential of specific miRNAs capable of inducing reprogramming of cardiac fibroblasts directly to cardiomyocytes in vitro and in vivo. Methods and Results Using a combinatorial strategy, we identified a combination of microRNAs (miRNA) 1, 133, 208, and 499 capable of inducing direct cellular reprogramming of fibroblasts to cardiomyocyte-like cells in vitro. Detailed studies of the reprogrammed cells, demonstrated that a single transient transfection of the microRNAs can direct a switch in cell fate as documented by expression of mature cardiomyocyte markers, sarcomeric organization, and exhibition of spontaneous calcium flux characteristic of a cardiomyocyte-like phenotype. Interestingly, we also found that miRNA-mediated reprogramming was enhanced 10 fold upon JAK inhibitor I treatment. Importantly, administration of microRNAs into ischemic mouse myocardium resulted in evidence of direct conversion of cardiac fibroblasts to cardiomyocytes in situ. Genetic tracing analysis using Fsp1Cre-traced fibroblasts from both cardiac and non-cardiac cell sources strongly suggests that induced cells are most likely of fibroblastic origin. Conclusion The findings from this study provide the first proof-of-concept that miRNAs have the capability of directly converting fibroblasts to a cardiomyocyte-like phenotype in vitro. Also of significance is that this is the first report of direct cardiac reprogramming in vivo. Our approach may have broad and important implications for therapeutic tissue regeneration in general.
Chronic obstructive pulmonary disease (COPD) is one of the most common causes of death worldwide. We report in an emphysema model of mice chronically exposed to tobacco smoke that pulmonary vascular dysfunction, vascular remodeling, and pulmonary hypertension (PH) precede development of alveolar destruction. We provide evidence for a causative role of inducible nitric oxide synthase (iNOS) and peroxynitrite in this context. Mice lacking iNOS were protected against emphysema and PH. Treatment of wild-type mice with the iNOS inhibitor N(6)-(1-iminoethyl)-L-lysine (L-NIL) prevented structural and functional alterations of both the lung vasculature and alveoli and also reversed established disease. In chimeric mice lacking iNOS in bone marrow (BM)-derived cells, PH was dependent on iNOS from BM-derived cells, whereas emphysema development was dependent on iNOS from non-BM-derived cells. Similar regulatory and structural alterations as seen in mouse lungs were found in lung tissue from humans with end-stage COPD.
Our systematic analysis of anion channels and transporters in idiopathic pulmonary arterial hypertension (IPAH) showed marked upregulation of the Cl− channel TMEM16A gene. We hypothesised that TMEM16A overexpression might represent a novel vicious circle in the molecular pathways causing pulmonary arterial hypertension (PAH).We investigated healthy donor lungs (n=40) and recipient lungs with IPAH (n=38) for the expression of anion channel and transporter genes in small pulmonary arteries and pulmonary artery smooth muscle cells (PASMCs).In IPAH, TMEM16A was strongly upregulated and patch-clamp recordings confirmed an increased Cl− current in PASMCs (n=9–10). These cells were depolarised and could be repolarised by TMEM16A inhibitors or knock-down experiments (n=6–10). Inhibition/knock-down of TMEM16A reduced the proliferation of IPAH-PASMCs (n=6). Conversely, overexpression of TMEM16A in healthy donor PASMCs produced an IPAH-like phenotype. Chronic application of benzbromarone in two independent animal models significantly decreased right ventricular pressure and reversed remodelling of established pulmonary hypertension.Our findings suggest that increased TMEM16A expression and activity comprise an important pathologic mechanism underlying the vasoconstriction and remodelling of pulmonary arteries in PAH. Inhibition of TMEM16A represents a novel therapeutic approach to reverse remodelling in PAH.
In contrast to hypoxia-induced PH, Nox1 but not Nox4 is responsible for pathophysiological proliferation and migration of PASMC in an inflammatory model of MCT-induced PH via increased superoxide production. Thus, different Nox isoforms may be targeted in different forms of PH.
Vascular remodelling is a hallmark of pulmonary hypertension (PH) and is characterized by enhanced proliferation of pulmonary artery smooth muscle cells (PASMCs). Accumulating evidence indicates a crucial role of transcription factors in the vascular remodelling processes. Here, we characterize the involvement of meprin β, a novel activator protein-1 (AP-1) effector molecule, in PH. Fra-2 transgenic (TG) mice exhibited increased right ventricular systolic pressure (RVSP), accompanied by vascular remodelling and activation of the pro-proliferative and pro-fibrotic AKT pathway. Microarray studies revealed the collagen-processing metalloprotease meprin β as the most up-regulated gene in Fra-2 TG mice. Its expression, increased at all investigated time points, preceded the decreased expression of MMPs and increased TGFβ, followed by collagen deposition. Correspondingly, remodelled pulmonary arteries from explanted idiopathic pulmonary arterial hypertension (IPAH) patients' lungs exhibited pronounced expression of meprin β. Fra-2 and meprin β expression in human PASMCs was regulated by PDGF-BB and TGFβ in a complementary fashion. Importantly, PDGF-BB-dependent proliferation was attenuated by silencing AP-1 expression or by meprin β inhibition. This study delineates a novel molecular mechanism underlying PASMCs proliferation and extracellular matrix (ECM) deposition by identifying meprin β as an important mediator in regulating vascular remodelling processes. Thus, meprin β may represent a new molecule that can be targeted in pulmonary hypertension.
Acute respiratory disorders and permissive hypercapnic strategy may lead to alveolar hypoxia and hypercapnic acidosis. However, the effects of hypercapnia with or without acidosis on hypoxic pulmonary vasoconstriction (HPV) and oxygen diffusion capacity of the lung are controversial. We investigated the effects of hypercapnic acidosis and hypercapnia with normal pH (pH corrected with sodium bicarbonate) on HPV, capillary permeability, gas exchange, and ventilation-perfusion matching in the isolated ventilated-perfused rabbit lung. No alteration in vascular tone was noted during normoxic hypercapnia with or without acidosis compared with normoxic normocapnia. Hypercapnia with normal pH resulted in a transient increase in HPV during the course of consecutive ventilation maneuvers, whereas hypercapnic acidosis increased HPV over time. Hypercapnic acidosis decreased exhaled NO during hypoxia more than hypercapnia with normal pH and normocapnia, whereas intravascular NO release was unchanged. However, inhibition of NO synthesis by nitro-L-arginine (L-NNA) resulted in a loss of the increased HPV caused by hypercapnic acidosis but not that caused by hypercapnia with normal pH. Furthermore, capillary permeability increased during hypoxic hypercapnia with normal pH but not hypoxic hypercapnic acidosis. This effect was NO-dependent because it disappeared during L-NNA administration. Ventilation-perfusion matching and arterial PO2 were improved according to the strength of HPV in hypercapnia compared with normocapnia during Tween nebulization-induced lung injury. In conclusion, the increased HPV during hypercapnic acidosis is beneficial to lung gas exchange by improving ventilation-perfusion matching and preserving the capillary barrier function. These effects seem to be linked to NO-mediated pathways.hypoxia; hypercapnic acidosis; pH; capillary permeability ACUTE RESPIRATORY DISORDERS such as acute obstructive pulmonary diseases and depression of the respiratory control center may induce alveolar hypoxia and hypercapnic acidosis, which can affect systemic regulatory processes and pulmonary function. However, the use of sodium bicarbonate, one of the most essential extracellular buffers for the normalization of pH in different pathological conditions of respiratory acidosis, is controversial. During resuscitation, application of sodium bicarbonate is generally not recommended for just correction of pH due to severe side effects (40). Furthermore, in permissive hypercapnic strategy, beneficial effects of acidosis have been discussed in the literature (5). In animal studies, a decreased development of pulmonary edema and reduced hypoxemia during hypercapnic acidosis suggests valuable effects of acidosis (13,14,(25)(26)(27), whereas from other studies it could not be distinguished whether the effects were related to hypercapnia or acidosis (12,43). In addition, the mechanisms of improvement of oxygenation and reduced lung edema formation are not known. Improvement in ventilation-perfusion matching and/or of gas diffusion acro...
Rationale: Remodeling and fibrosis of the right ventricle (RV) may cause RV dysfunction and poor survival in patients with pulmonary hypertension. Objectives: To investigate the consequences of RV fibrosis modulation and the accompanying cellular changes on RV function. Methods: Expression of fibrotic markers was assessed in the RV of patients with pulmonary hypertension, the murine pulmonary artery banding, and rat monocrotaline and Sugen5416/hypoxia models. Invasive hemodynamic and echocardiographic assessment was performed on galectin-3 knockout or inhibitor-treated mice. Measurements and Main Results: Established fibrosis was characterized by marked expression of galectin-3 and an enhanced number of proliferating RV fibroblasts. Galectin-3 genetic and pharmacologic inhibition or antifibrotic treatment with pirfenidone significantly diminished RV fibrosis progression in the pulmonary artery banding model, without improving RV functional parameters. RV fibrotic regions were populated with mesenchymal cells coexpressing vimentin and PDGFRa (platelet-derived growth factor receptor-a), but generally lacked aSMA (a-smooth muscle actin) positivity. Serum levels of galectin-3 were increased in patients with idiopathic pulmonary arterial hypertension but did not correlate with cardiac function. No changes of galectin-3 expression were observed in the lungs. Conclusions: We identified extrapulmonary galectin-3 as an important mediator that drives RV fibrosis in pulmonary hypertension through the expansion of PDGFRa/vimentinexpressing cardiac fibroblasts. However, interventions effectively targeting fibrosis lack significant beneficial effects on RV function.
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