Endothelial and Epithelial Cell Transition to a Mesenchymal Phenotype Was Delineated by Nestin Expression.

Endothelial and epithelial cell transition to a mesenchymal phenotype was identified as cellular paradigms implicated in the appearance of fibroblasts and development of reactive fibrosis in interstitial lung disease. The intermediate filament protein nestin was highly expressed in fibrotic tissue, detected in fibroblasts and participated in proliferation and migration. The present study tested the hypothesis that the transition of endothelial and epithelial cells to a mesenchymal phenotype was delineated by nestin expression. Three weeks following hypobaric hypoxia, adult male Sprague-Dawley rats characterized by alveolar and perivascular lung fibrosis were associated with increased nestin protein and mRNA levels and marked appearance of nestin/collagen type I((+))-fibroblasts. In the perivascular region of hypobaric hypoxic rats, displaced CD31((+))-endothelial cells were detected, exhibited a mesenchymal phenotype and co-expressed nestin. Likewise, epithelial cells in the lungs of hypobaric hypoxic rats transitioned to a mesenchymal phenotype distinguished by the co-expression of E-cadherin and collagen. Following the removal of FBS from primary passage rat alveolar epithelial cells, TGF-ß1 was detected in the media and a subpopulation acquired a mesenchymal phenotype characterized by E-cadherin downregulation and concomitant induction of collagen and nestin. Bone morphogenic protein-7 treatment of alveolar epithelial cells prevented E-cadherin downregulation, suppressed collagen induction but partially inhibited nestin expression. These data support the premise that the transition of endothelial and epithelial cells to a mesenchymal cell may have contributed in part to the appearance nestin/collagen type I((+))-fibroblasts and the reactive fibrotic response in the lungs of hypobaric hypoxic rats.

Nestin is a marker of lung remodeling secondary to myocardial infarction and type I diabetes in the rat.

Upregulation of the intermediate filament protein nestin was identified in a subpopulation of fibroblasts during reactive and reparative fibrosis and directly contributed to the enhanced proliferative phenotype. The present study tested the hypothesis that nestin was expressed in lung fibroblasts and the pattern of expression represented a distinct marker of pulmonary remodeling secondary to myocardial infarction and type I diabetes. Nestin((+)) fibroblasts were detected in rat lungs and a subpopulation exhibited a myofibroblast phenotype delineated by the co-expression of smooth muscle α-actin. In the lungs of myocardial infarcted rats, interstitial collagen content and nestin mRNA/protein levels were significantly increased despite the absence of secondary pulmonary hypertension, whereas smooth muscle α-actin protein expression was unchanged. Exposure of rat pulmonary fibroblasts to pro-fibrotic stimuli angiotensin II and transforming growth factor-ß significantly increased nestin protein levels. In the lungs of type I diabetic rats, the absence of a reactive fibrotic response was associated with a significant downregulation of nestin mRNA/protein expression. Nestin was reported a target of miR-125b, albeit miR-125b levels were unchanged in pulmonary fibroblasts treated with pro-fibrotic stimuli. Nestin((+)) cells lacking smooth muscle α-actin/collagen staining were also identified in rodent lungs and a transgenic approach revealed that expression of the intermediate filament protein was driven by intron 2 of the nestin gene. The disparate regulation of nestin characterized a distinct pattern of pulmonary remodeling secondary to myocardial infarction and type I diabetes and upregulation of the intermediate filament protein in lung fibroblasts may have facilitated in part the reactive fibrotic response.

The neurogenic response of cardiac resident nestin(+) cells was associated with GAP43 upregulation and abrogated in a setting of type I diabetes.

BACKGROUND: Cardiac nestin(+) cells exhibit properties of a neural progenitor/stem cell population characterized by the de novo synthesis of neurofilament-M in response to ischemic injury and 6-hydroxydopamine administration. The induction of growth associated protein 43 (GAP43) was identified as an early event of neurogenesis. The present study tested the hypothesis that the de novo synthesis of neurofilament-M by nestin(+) cells was preceded by the transient upregulation of GAP43 during the acute phase of reparative fibrosis in the infarcted male rat heart. Secondly, a seminal feature of diabetes is impaired wound healing secondary to an inadequate neurogenic response. In this regard, an additional series of experiments tested the hypothesis that the neurogenic response of cardiac nestin(+) cells was attenuated in a setting of type I diabetes. METHODS: The neurogenic response of cardiac nestin(+) cells was examined during the early phase of reparative fibrosis following permanent ligation of the left anterior descending coronary artery in the adult male rat heart. The experimental model of type I diabetes was created following a single injection of streptozotocin in adult male rats. The impact of a type I diabetic environment on the neurogenic response of cardiac nestin(+) cells was examined during myocardial infarction and following the administration of 6-hydroxydopamine. RESULTS: During the early phase of scar formation/healing, the density of GAP43/nestin(+) fibres innervating the peri-infarct/infarct region was significantly increased, whereas neurofilament-M/nestin(+) fibres were absent. With ongoing scar formation/healing, a temporal decrease of GAP43/nestin(+) fibre density and a concomitant increase in the density of innervating neurofilament-M/nestin(+) fibres were observed. The neurogenic response of cardiac nestin(+) cells during scar formation/healing was inhibited following the superimposition of type I diabetes. The de novo synthesis of neurofilament-M by nestin(+) cells after 6-hydroxydopamine administration was likewise attenuated in the heart of type I diabetic rats whereas the density of GAP43/nestin(+) fibres remained elevated. CONCLUSION: The transient upregulation of GAP43 apparently represents a transition event during the acquisition of a neuronal-like phenotype and a type I diabetic environment attenuated the neurogenic response of cardiac nestin(+) cells to ischemia and 6-hydroxydopamine.

Cardiac resident nestin(+) cells participate in reparative vascularisation.

The rodent heart contains a population of nestin((+)) cells derived from the embryonic neural crest and migrate to the scar after myocardial infarction (MI). The present study tested the hypothesis that intron 2 of the nestin gene drives expression and a subpopulation of nestin((+)) cells participate in reparative vascularisation. The directed expression of the green fluorescent protein (GFP) by the second intron of the nestin gene identified GFP/nestin((+)) cells intercalated among ventricular myocytes in the heart of normal transgenic mice. Ischemic injury led to the migration of GFP((+)) cells to the scar and a subpopulation was detected in CD31/nestin((+)) endothelial cells of newly formed blood vessels. The direct contribution to reparative vascularisation provided the impetus to test the hypothesis that increasing the population of nestin((+)) cells in the infarcted heart will improve scar healing. Skin-derived cells isolated from E18 Sprague-Dawley rats grew as spheres, expressed nestin, sox2, neural crest-related transcriptional genes and a panel of peptide growth factors. Skin-derived cells transplanted in the non-infarcted left ventricle of 3-day post-MI rats migrated to the peri-infarct/infarct region and remained engrafted for 21 days. A significantly smaller infarct, increased number of small calibre blood vessels and improved ventricular function were observed in engrafted infarcted rat hearts. Thus, the second intron of the nestin gene drives expression in the mouse heart and a subpopulation of GFP/nestin((+)) cells directly participate in reparative vascularisation. Increasing the population of nestin((+)) cells via the transplantation of skin-derived cells represents a potential approach to limit ischemic damage to the heart.

Role of aldosterone on lung structural remodelling and right ventricular function in congestive heart failure.

BACKGROUND: The mechanisms of benefit of mineralocorticoid receptors antagonists in congestive heart failure (CHF) are still debated. We hypothesized that aldosterone contributes to pulmonary remodelling and right ventricular (RV) dysfunction associated with CHF by stimulation of lung myofibroblasts (MYFs) proliferation. METHODS: Rats with moderate to large myocardial infarcts (MI) and CHF were studied. Two weeks after MI, spironolactone 100 mg/kg/day (n = 21) or no treatment (n = 24) were given for 3 weeks and compared to sham (n = 8). RESULTS: Infarct size was similar by ultrasound and pathologic measures in both MI groups.The MI-untreated group developed important lung remodelling with nearly doubling of dry lung weight (p < 0.01), reduced left ventricular (LV) fractional shortening (16 ± 2% vs. 53 ± 1%; mean ± SEM, p < 0.0001), pulmonary hypertension (RV systolic pressure: 40 ± 3 mmHg vs. 27 ± 1 mmHg, p < 0.01) and RV hypertrophy (RV/(LV + septum): 38 ± 3% vs. 24 ± 1%, p < 0.05). Spironolactone had no effect on these parameters and did not improve LV or RV performance (tricuspid annular plane systolic excursion and RV myocardial performance index) measured by echocardiography. CHF induced a restrictive respiratory syndrome with histological lung fibrosis: this was also unaffected by spironolactone. Finally, isolated lung MYFs did not proliferate after exposure to aldosterone. CONCLUSION: Aldosterone does not significantly contribute to pulmonary remodelling and RV dysfunction associated with CHF. Other mechanisms are responsible for the beneficial effects of spironolactone in CHF.