Emily J. Farrar

Inflammatory Cytokines Promote Mesenchymal Transformation in Embryonic and Adult Valve Endothelial Cells

Objective—Inflammatory activation of valve endothelium is an early phase of aortic valve disease pathogenesis, but subsequent mechanisms are poorly understood. Adult valve endothelial cells retain the developmental ability to undergo endothelial-to-mesenchymal transformation (EndMT), but a biological role has not been established. Here, we test whether and how inflammatory cytokines (tumor necrosis factor-&agr; and interleukin-6) regulate EndMT in embryonic and adult valve endothelium. Methods and Results—Using in vitro 3-dimensional collagen gel culture assays with primary cells, we determined that interleukin-6 and tumor necrosis factor-&agr; induce EndMT and cell invasion in dose-dependent manners. Inflammatory-EndMT occurred through an Akt/nuclear factor-&kgr;B–dependent pathway in both adult and embryonic stages. In embryonic valves, inflammatory-EndMT required canonical transforming growth factor-&bgr; signaling through activin receptor-like kinases 2 and 5 to drive EndMT. In adult valve endothelium, however, inflammatory-induced EndMT still occurred when activin receptor-like kinases 2 and 5 signaling was blocked. Inflammatory receptor gene expression was significantly upregulated in vivo during embryonic valve maturation. Endothelial-derived mesenchymal cells expressing activated nuclear factor-&kgr;B were found distal to calcific lesions in diseased human aortic valves. Conclusion—Inflammatory cytokine–induced EndMT in valve endothelium is present in both embryonic and adult stages, acting through Akt/nuclear factor-&kgr;B, but differently using transforming growth factor-&bgr; signaling. Molecular signatures of valve EndMT may be important diagnostic and therapeutic targets in early valve disease.

The mechanobiology of mitral valve function, degeneration, and repair

In degenerative valve disease, the highly organized mitral valve leaflet matrix stratification is progressively destroyed and replaced with proteoglycan rich, mechanically inadequate tissue. This is driven by the actions of originally quiescent valve interstitial cells that become active contractile and migratory myofibroblasts. While treatment for myxomatous mitral valve disease in humans ranges from repair to total replacement, therapies in dogs focus on treating the consequences of the resulting mitral regurgitation. The fundamental gap in our understanding is how the resident valve cells respond to altered mechanical signals to drive tissue remodeling. Despite the pathological similarities and high clinical occurrence, surprisingly little mechanistic insight has been gleaned from the dog. This review presents what is known about mitral valve mechanobiology from clinical, in vivo, and in vitro data. There are a number of experimental strategies already available to pursue this significant opportunity, but success requires the collaboration between veterinary clinicians, scientists, and engineers.

Heterogeneous Susceptibility of Valve Endothelial Cells to Mesenchymal Transformation in Response to TNFα

Lack of understanding of the early mechanisms of aortic valve stenosis and calcification hinders the development of diagnostic and therapeutic intervention strategies. Inflammation is a known component of early aortic valve disease and can induce mesenchymal transformation in a subset of aortic valve endothelial cells. Here we present a three-dimensional culture system that allows transforming and non-transforming cells to be independently isolated and analyzed. We have used the system to identify and characterize the dynamic invasion and phenotypic transition of two distinct subsets of endothelial cells: those that invade and transform under TNFα treatment, and those that resist mesenchymal transformation and remain endothelial. We determine that non-transformed cells maintain control levels of endothelial genes VE-cadherin and eNOS, while transformed cells lose these endothelial characteristics and upregulate α-smooth muscle actin. Both subsets of cells have an inflammatory phenotype marked by increased ICAM-1, but transformed cells have increased MMP-9, Notch1, TGF-β, and BMP-4, while non-transformed cells do not. Transformed cells also have distinct effects on alignment of collagen fibers as they invade the hydrogel system, which is not found in control endothelial or interstitial valve cells. Understanding the role of transforming and non-transforming endothelial cells in valve disease will provide an important pathological link between early inflammation and later stages of disease. Discovery of the molecular signature of transformation-resistant endothelial cells could inform development of treatment strategies that promote survival of the valve endothelium.

Endothelial-Derived Oxidative Stress Drives Myofibroblastic Activation and Calcification of the Aortic Valve

Aims Oxidative stress is present in and contributes to calcification of the aortic valve, but the driving factors behind the initiation of valve oxidative stress are not well understood. We tested whether the valve endothelium acts as an initiator and propagator of oxidative stress in aortic valve disease. Methods and Results Calcified human aortic valves showed side-specific elevation of superoxide in the endothelium, co-localized with high VCAM1 expression, linking oxidative stress, inflammation, and valve degeneration. Treatment with inflammatory cytokine TNFα increased superoxide and oxidative stress and decreased eNOS and VE-cadherin acutely over 48 hours in aortic valve endothelial cells (VEC) and chronically over 21 days in ex vivo AV leaflets. Co-treatment of VEC with tetrahydrobiopterin (BH4) but not apocynin mitigated TNFα-driven VEC oxidative stress. Co-treatment of ex vivo AV leaflets with TNFα+BH4 or TNFα+peg-SOD rescued endothelial function and mitigated inflammatory responses. Both BH4 and peg-SOD rescued valve leaflets from the pro-osteogenic effects of TNFα treatment, but only peg-SOD was able to mitigate the fibrogenic effects, including increased collagen and αSMA expression. Conclusions Aortic valve endothelial cells are a novel source of oxidative stress in aortic valve disease. TNFα-driven VEC oxidative stress causes loss of endothelial protective function, chronic inflammation, and fibrogenic and osteogenic activation, mitigated differentially by BH4 and peg-SOD. These mechanisms identify new targets for tailored antioxidant therapy focused on mitigation of oxidative stress and restoration of endothelial protection.

Notch-Tnf signalling is required for development and homeostasis of arterial valves

Aims Congenital anomalies of arterial valves are common birth defects, leading to valvar stenosis. With no pharmaceutical treatment that can prevent the disease progression, prosthetic replacement is the only choice of treatment, incurring considerable morbidity and mortality. Animal models presenting localized anomalies and stenosis of congenital arterial valves similar to that of humans are critically needed research tools to uncover developmental molecular mechanisms underlying this devastating human condition. Methods and results We generated and characterized mouse models with conditionally altered Notch signalling in endothelial or interstitial cells of developing valves. Mice with inactivation of Notch1 signalling in valvar endothelial cells (VEC) developed congenital anomalies of arterial valves including bicuspid aortic valves and valvar stenosis. Notch1 signalling in VEC was required for repressing proliferation and activating apoptosis of valvar interstitial cells (VIC) after endocardial-to-mesenchymal transformation (EMT). We showed that Notch signalling regulated Tnf&agr; expression in vivo, and Tnf signalling was necessary for apoptosis of VIC and post-EMT development of arterial valves. Furthermore, activation or inhibition of Notch signalling in cultured pig aortic VEC-promoted or suppressed apoptosis of VIC, respectively. Conclusion We have now met the need of critical animal models and shown that Notch-Tnf signalling balances proliferation and apoptosis for post-EMT development of arterial valves. Our results suggest that mutations in its components may lead to congenital anomaly of aortic valves and valvar stenosis in humans.

Valve interstitial cell tensional homeostasis directs calcification and extracellular matrix remodeling processes via RhoA signaling

AIMS Valve interstitial cells are active and aggressive players in aortic valve calcification, but their dynamic mediation of mechanically-induced calcific remodeling is not well understood. The goal of this study was to elucidate the feedback loop between valve interstitial cell and calcification mechanics using a novel three-dimensional culture system that allows investigation of the active interplay between cells, disease, and the mechanical valve environment. METHODS & RESULTS We designed and characterized a novel bioreactor system for quantifying aortic valve interstitial cell contractility in 3-D hydrogels in control and osteogenic conditions over 14 days. Interstitial cells demonstrated a marked ability to exert contractile force on their environment and to align collagen fibers with the direction of tension. Osteogenic environment disrupted interstitial cell contractility and led to disorganization of the collagen matrix, concurrent with increased αSMA, TGF-β, Runx2 and calcific nodule formation. Interestingly, RhoA was also increased in osteogenic condition, pointing to an aberrant hyperactivation of valve interstitial cells mechanical activity in disease. This was confirmed by inhibition of RhoA experiments. Inhibition of RhoA concurrent with osteogenic treatment reduced pro-osteogenic signaling and calcific nodule formation. Time-course correlation analysis indicated a significant correlation between interstitial cell remodeling of collagen fibers and calcification events. CONCLUSIONS Interstitial cell contractility mediates internal stress state and organization of the aortic valve extracellular matrix. Osteogenesis disrupts interstitial cell mechanical phenotype and drives disorganization, nodule formation, and pro-calcific signaling via a RhoA-dependent mechanism.

Empowering early mastery of spatial visualization skills in under represented minority engineering students

Students entering university-level engineering programs must be adept at spatial visualization and reasoning. The Cornell University Engineering Success (CUES) program used the NSF ENGAGE curriculum to introduce spatial visualization basics through an innovative project-based course to a select group of first year students. Students in the course were chosen to participate based on multiple background characteristics that place them at risk and may hinder their persistence in engineering. Course results were strong, with an overall 13% improvement in tested skills. Additionally, our teaching team believed that skills application in authentic spatial visualization projects would provide deeper learning. Student teams worked with biomedical researchers who asked for professional-level visualizations. We employed an action research methodology (observations, instructor journals, expert responses, and e-portfolios), tracking their acquisition of spatial concepts, representations and critical stances. Our hope was to give students a competitive edge, taking advanced visualization techniques and professional skills into future projects.