Bicuspid aortic valve disease is the most common congenital cardiac malformation and indication for surgery for aortic valve patients. The age of onset for the development of stenosis is earlier in bicuspid aortic valves than tricuspid aortic valves. Understanding the cellular mechanisms of this valve lesion, will help to develop novel approaches towards slowing disease progression. This study hypothesizes that bicuspid aortic valve disease develops secondary to a tissue stem cell niche to activate a cross-talk mechanism which induces Notch1 cleavage and Lrp5 mediated bone formation specific to the bicuspid aortic valve. Human ex vivo bicuspid valves versus control aortic valves were tested for Notch1 expression by RTPCR, Western Blot and Immunohistochemistry. eNOS null bicuspid mice: control (n=20), cholesterol (n=20), cholesterol + Atorvastatin (n=20), were tested for the development of aortic stenosis by Visual Sonics Echo, Immunohistochemistry for Notch1, Wnt, Lrp5, Osteocalcin, PCNA and RTPCR for Notch1, Lrp5, Cbfa1, Osteocalcin. In vitro studies were performed to characterize Wnt secretion from aortic valve endothelial cells and gene expression for Notch1, Lp5 and osteocalcin from the valve myofibroblast cells. This study characterizes the secretion of Wnt3a (>300-fold, p<0.01) from aortic valve endothelium in the presence of abnormal nitric oxide regulation and lipids as measured by eNOS enzymatic activity and tissue nitrite levels. Osteoblastogenesis in the adjacent myofibroblast cell is activated via Notch1 cleavage(p<0.001) and upregulation of the Wnt3a/Lrp5 receptor. Human ex vivo valves express Notch1 cleavage as compared to normal valves from heart transplant(p<0.01). Cholesterol treated eNOS mice develop severe stenosis with cleavage of Notch1, increase in Lrp5, Wnt3a, cyclin, Cbfa1, and Osteopontin,(3-fold increase(p<0.01) which was not present in the controls and normalized in the statin treated valves. Targeting the Notch1/Wnt3a/Lrp5 pathway in bicuspid valvular calcification presents a novel approach towards treating this disease. The importance of this cross talk mechanism is demonstrated in three models of aortic valve disease and will have important clinical implications.
This research has received full or partial funding support from the American Heart Association, AHA National Center.