ABSTRACT
ß-catenin has been widely studied in many animal and organ systems across evolution, and gain or loss of function has been linked to a number of human diseases. Yet fundamental knowledge regarding its protein expression and localization remains poorly described. Thus, we sought to define whether there was a temporal and cell-specific regulation of ß-catenin activities that correlate with distinct cardiac morphological events. Our findings indicate that activated nuclear ß-catenin is primarily evident early in gestation. As development proceeds, nuclear ß-catenin is down-regulated and becomes restricted to the membrane in a subset of cardiac progenitor cells. After birth, little ß-catenin is detected in the heart. The co-expression of ß-catenin with its main transcriptional co-factor, Lef1, revealed that Lef1 and ß-catenin expression domains do not extensively overlap in the cardiac valves. These data indicate mutually exclusive roles for Lef1 and ß-catenin in most cardiac cell types during development. Additionally, these data indicate diverse functions for ß-catenin within the nucleus and membrane depending on cell type and gestational timing. Cardiovascular studies should take into careful consideration both nuclear and membrane ß-catenin functions and their potential contributions to cardiac development and disease.
ABSTRACT
Non-syndromic mitral valve prolapse (MVP) is the most common heart valve disease affecting 2.4% of the population. Recent studies have identified genetic defects in primary cilia as causative to MVP, although the mechanism of their action is currently unknown. Using a series of gene inactivation approaches, we define a paracrine mechanism by which endocardially-expressed Desert Hedgehog (DHH) activates primary cilia signaling on neighboring valve interstitial cells. High-resolution imaging and functional assays show that DHH de-represses smoothened at the primary cilia, resulting in kinase activation of RAC1 through the RAC1-GEF, TIAM1. Activation of this non-canonical hedgehog pathway stimulates α-smooth actin organization and ECM remodeling. Genetic or pharmacological perturbation of this pathway results in enlarged valves that progress to a myxomatous phenotype, similar to valves seen in MVP patients. These data identify a potential molecular origin for MVP as well as establish a paracrine DHH-primary cilium cross-talk mechanism that is likely applicable across developmental tissue types.
