Intra-Amniotic Sildenafil Treatment Promotes Lung Growth and Attenuates Vascular Remodeling in an Experimental Model of Congenital Diaphragmatic Hernia.

BACKGROUND: Defective lung development resulting in lung hypoplasia and an attenuated and hypermuscularized pulmonary vasculature contributes to significant postnatal mortality in congenital diaphragmatic hernia (CDH). We hypothesize that deficient embryonic pulmonary blood flow contributes to defective lung development in CDH, which may therefore be ameliorated via enhancement of embryonic pulmonary blood flow. METHODS: The mouse nitrofen model of CDH was utilized to measure embryonic pulmonary blood flow by in utero intracardiac injection of FITC-labeled tomato lectin and color-flow Doppler ultrasound. The effect of prenatal intra-amniotic treatment with sildenafil on survival, lung growth, and vascular morphology in the nitrofen model was determined. RESULTS: Nitrofen-treated embryos exhibited decreased blood flow in the lung periphery compared to controls, and intra-amniotic sildenafil significantly improved embryonic pulmonary blood flow. Similar to nitrofen alone, pups delivered after nitrofen treatment and intra-amniotic injection of dextrose control exhibited respiratory distress and never survived beyond 6 h. Intra-amniotic sildenafil ameliorated respiratory distress in nitrofen-treated pups and improved postnatal survival to 82%. Following intra-amniotic sildenafil treatment at embryonic day (E)10.5, nitrofen-treated P0 lungs were larger with increased left lobe weight, reduced small pulmonary arterial wall muscularization, and increased airway branching complexity compared to controls. Intra-amniotic sildenafil treatment later at E15.5 also resulted in improved survival, lung growth, and attenuation of vascular remodeling in nitrofen-treated embryos. CONCLUSIONS: Defective embryonic pulmonary blood flow may contribute to lung maldevelopment in CDH. Enhancement of embryonic pulmonary blood flow via intra-amniotic sildenafil results in lung growth and attenuation of pulmonary vascular remodeling and may have therapeutic potential for CDH.

Intra-amniotic Sildenafil Treatment Modulates Vascular Smooth Muscle Cell Phenotype in the Nitrofen Model of Congenital Diaphragmatic Hernia.

The etiology of pulmonary vascular abnormalities in CDH is incompletely understood. Studies have demonstrated improvement in pulmonary vasculature with prenatal therapy in animal models. We hypothesize that prenatal sildenafil may attenuate defective pulmonary vascular development via modulation of vSMC phenotype from undifferentiated, proliferative phenotype to differentiated, contractile phenotype. We utilized the nitrofen model of CDH to examine the effect of IA sildenafil on pulmonary vSMC phenotype during lung development. Timed-pregnant CD-1 mice were gavage fed 25 mg nitrofen or olive oil (control) at E8.5 of gestation. Single IA injections of Sildenafil (Revatio; 10 µL of 4 mg/4 ml solution) or dextrose control were performed at E12.5. Mice were sacrificed on various gestational days for embryonic lung harvest. Markers of vSMC development of undifferentiated and differentiated phenotypes were analyzed by immunostaining and western blot. Across all time points in gestation, nitrofen-treated embryonic lungs demonstrated increased vSMC expression of NOTCH3, Hes-5, PDGFR-ß, desmin and α-SMA and decreased expression of calponin and SMMHC, compared to oil controls. IA dextrose treatment had no effect on expression levels. However, IA Sildenafil treatment resulted in down-regulation of NOTCH3, Hes-5, PDGFR-ß, desmin and α-SMA and upregulation of calponin and SMMHC, comparable to oil controls. In the nitrofen model, vSMC express markers consistent with more undifferentiated proliferative phenotype, resulting in hypermuscularization of intrapulmonary arterioles in CDH. A single dose of IA Sildenafil treatment early in gestation, results in sustained normalization of vSMC phenotype. Pharmacologic modulation of the vSMC phenotype at key gestational points may have therapeutic potential.

Defective parasympathetic innervation is associated with airway branching abnormalities in experimental CDH.

Developmental mechanisms leading to lung hypoplasia in congenital diaphragmatic hernia (CDH) remain poorly defined. Pulmonary innervation is defective in the human disease and in the rodent models of CDH. We hypothesize that defective parasympathetic innervation may contribute to airway branching abnormalities and, therefore, lung hypoplasia, during lung development in CDH. The murine nitrofen model of CDH was utilized to study the effect of the cholinergic agonist carbachol on embryonic day 11.5 (E11.5) lung explant cultures. Airway branching and contractions were quantified. In a subset of experiments, verapamil was added to inhibit airway contractions. Sox9 immunostaining and 5-bromo-2-deoxyuridine incorporation were used to identify and quantify the number and proliferation of distal airway epithelial progenitor cells. Intra-amniotic injections were used to determine the in vivo effect of carbachol. Airway branching and airway contractions were significantly decreased in nitrofen-treated lungs compared with controls. Carbachol resulted in increased airway contractions and branching in nitrofen-treated lungs. Nitrofen-treated lungs exhibited an increased number of proliferating Sox9-positive distal epithelial progenitor cells, which were decreased and normalized by treatment with carbachol. Verapamil inhibited the carbachol-induced airway contractions in nitrofen-treated lungs but had no effect on the carbachol-induced increase in airway branching, suggesting a direct carbachol effect independent of airway contractions. In vivo treatment of nitrofen-treated embryos via amniotic injection of carbachol at E10.5 resulted in modest increases in lung size and branching at E17.5. These results suggest that defective parasympathetic innervation may contribute to airway branching abnormalities in CDH.

PanIN-specific regulation of Wnt signaling by HIF2α during early pancreatic tumorigenesis.

Hypoxia promotes angiogenesis, proliferation, invasion, and metastasis of pancreatic cancer. Essentially, all studies of the hypoxia pathway in pancreatic cancer research to date have focused on fully malignant tumors or cancer cell lines, but the potential role of hypoxia inducible factors (HIF) in the progression of premalignant lesions has not been critically examined. Here, we show that HIF2α is expressed early in pancreatic lesions both in human and in a mouse model of pancreatic cancer. HIF2α is a potent oncogenic stimulus, but its role in Kras-induced pancreatic neoplasia has not been discerned. We used the Ptf1aCre transgene to activate Kras(G12D) and delete Hif2α solely within the pancreas. Surprisingly, loss of Hif2α in this model led to markedly higher, rather than reduced, number of low-grade pancreatic intraepithelial neoplasia (mPanIN) lesions. These lesions, however, failed to progress to high-grade mPanINs, and displayed exclusive loss of ß-catenin and SMAD4. The relationship among HIF2α, ß-catenin, and Smad4 was further confirmed in vitro, where silencing of Hif2α resulted in reduced ß-catenin and Smad4 transcript levels. Thus, with oncogenic Ras expressed in the pancreas, HIF2α modulates Wnt-signaling during mPanIN progression by maintaining appropriate levels of both Smad4 and ß-catenin.

Induction of mouse pancreatic ductal differentiation, an in vitro assay.

Despite recent technical advances for studying lineage tracing and gene functions, our knowledge of pancreatic duct progenitor cells and mechanisms involved in their differentiation remains a huge void in our understanding of pancreatic development. A deeper insight into ductal differentiation is needed because ductal cells may harbor pancreatic stem/progenitor cells that could give rise to new islets. Also, since the most common pancreatic tumors form structures expressing ductal cell-specific markers, studies of ductal development may provide better markers for pancreatic tumor classification. One major longstanding problem in the study of pancreatic ductal differentiation has been the lack of an effective in vitro model. We thus wished to develop an in vitro system for the study of pancreatic duct development. In doing so, we have developed a specific culture condition to promote ductal differentiation of E11.5 pancreatic rudiments. Normally, pancreatic explants cultured in vitro develop to form endocrine, acinar, as well as ductal cells. Here, we report that addition of a combination of EGF, fibroblast growth factor-10, and platelet-derived growth factor-AA to the explant cultures promotes ductal differentiation, while preventing endocrine and acinar differentiation. This culture system for differentiation and enrichment of pancreatic ductal cells may allow identification of gene(s) involved in ductal development.