Background:Tetralogy of Fallot patients with pulmonary atresia (TOF/PA) present a pulmonary blood supply directly from aortic collateral arteries. Major aorto-pulmonary collateral arteries (MAPCAs) present substantial clinical and surgical management challenges. Surgical operations to reestablish and promote further development of a pulmonary arterial connection preferentially utilize MAPCAs for reconstruction of central pulmonary arteries. However, the propensity of some MAPCAs to develop stenosis rather than growth may impair the response to reconstructions. Methods: Probe sets prepared from MAPCAs, PA, and aorta mRNA were used to interrogate human genome microarrays. We compared expression differences between pairs of the three vessels to determine whether MAPCAs display distinct expression patterns. results: Functional clustering analysis identified differences in gene expression, which were further analyzed by gene ontology classification. A subset of highly regulated genes was validated using quantitative PCR. Expression differences among vessel types were observed for multiple gene classes. Of note, we observed that MAPCAs differentially express several genes at much higher levels than either PA or aorta. conclusion: MAPCAs differ from PA or aorta by significantly altered levels in gene expression, suggesting a transcriptional basis for their physiology that will guide a further understanding of the pathobiology of MAPCAs and TOF.
Background and ObjectiveThe potency of tissue resident stem cells is regulated primarily by inputs from the local microenvironment. Isolation of stem cells through enzymatic digestion of tissue may affect epigenetic regulation of cell fate and performance. Here we employ a non-enzymatic method to harvest and investigate tissue resident stem cells from the adult porcine pulmonary valve.Methods and ResultsThe presence of c-Kit+ stem cells within the valve tissue was confirmed by immunohistochemistry. An in vitro culture of minced valve leaflets was developed under the standard conditions (37°C with 5% CO2). The viability of the cellular outgrowths was evaluated over the subsequent 12 weeks. Under this culture condition, we identified a population of non-adherent c-Kit+ cells and multiple cellular structures mimicking the phenotype of embryonic stem cells at different stages of development. Formation of multinucleated cells through cell fusion provided an active niche area for homing and interaction of the non-adherent c-Kit+ cells. Expression of pluripotency markers Oct-4 and Nanog was detected in the newly formed multinucleated cells but not in mature colonies. Partial cell fusion was shown by fluorescent live-cell tracking, which confirmed intercellular molecular exchange between donor and recipient cells, resulting in altered cytoplasmic protein expression by the recipient cell.ConclusionsThese results suggest a role for the microenvironment in decrypting the potential of the valve somatic stem cells in vitro. In addition, our data provide evidence for cell fusion, which may play a critical role in reversing somatic cell fate and spontaneous cellular reprogramming.
A variety of approaches to heart valve tissue engineering are underway by many groups of investigators. We believe that a thorough understanding of the biophysical and biomolecular interactions that mediate normal leaflet homeostasis will inform improved approaches to the engineering of truly regenerative heart valve grafts. However, our understanding of the fundamental biology of normal valve tissue is still quite limited. This informational gap has led us to develop an ex vivo system for long-term valve culture in order to study the mechanobiology of native tissue. Using this system, we have cultured trileaflet rat heart valves with and without flow-induced valve cycling. We report here the preliminary findings about the effects of both ex vivo culture and of valve cycling on pulmonary leaflet cell gene expression following 7 days of flow culture. Expression of leaflet mRNA was queried using Affymetrix whole genome microarrays and the results analyzed using GeneSpring, EXPLAIN and MetaCore (GeneGO) software. Our analysis revealed 2147 genes whose expression was altered under flow conditions, and 1918 genes under static conditions. 1501 genes were common to both conditions. The effects of culture on gene expression affected multiple pathways, but the most active gene groups involved pathways for cytoskeletal remodeling, development, and cell adhesion. The genes involved in these pathways were altered in both culture conditions. Changes in cytoskeletal and ECM remodeling genes were more prominent in the static condition, while those involved in VEGF signaling were seen under flow condition. Our previously reported histological analyses of cultured rat pulmonary valve leaflet tissue revealed that flow promotes the maintenance of tissue integrity while the lack of flow leads to extracellular matrix remodeling and fibrinoid tissue formation. These gene expression analyses confirm the expected role of flow in maintaining leaflet tissue integrity as evidenced by its induction of VEGF signaling genes, while the lack of flow induces changes in genes involved in extracellular matrix and cytoskeletal remodeling.
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