Friday, May 9, 2025
5/9/2025
Investigating collective myocardial cell movement during heart tube formation - Project Summary Organ formation is critically regulated by inter-tissue communication. The architecture of the mature heart is a result of sequential morphogenetic events, starting with the primitive heart tube, which is the foundation upon which the rest of the heart is built. The process of building the primitive heart tube starts with the collective movement of myocardial cells from bilateral locations in the anterior lateral plate mesoderm to the midline, a process called cardiac fusion which is conserved in all vertebrates. Genetic analysis has revealed that the adjacent endoderm is critical for these movements. However, the signals or molecules by which the endoderm communicates to the myocardium remain unknown. Furthermore, the molecular mechanism by which myocardial cells in vertebrates respond to these signals and collectively move towards the midline is also poorly understood. To elucidate these mechanisms, undergraduate and graduate students from the University of Mississippi will take a multi-dimensional approach examining cardiac fusion at the tissue, molecular, cellular and biomechanical level. We have found that mutations in the Platelet-derived growth factor receptor alpha (Pdgfra) leads to cardiac fusion defects in both zebrafish and mice. Myocardial movement appears to occur in response to a localized source of the PDGF ligand pdgf-aa, which we found is expressed in the endoderm medially adjacent to pdgfra expression in the myocardium. Furthermore, our preliminary data reveals that disruption of PI3K signaling in zebrafish also causes cardiac fusion defects. And that myocardial cells exhibit protrusions and display heterogenous changes in cell shape during cardiac fusion. Together, this data suggests the hypothesis that paracrine PDGF signals from the endoderm activates Pdgfra-mediated PI3K signaling in the myocardium to create medial oriented migratory protrusions which create asymmetric biomechanical tension in the myocardium facilitating medial movement. We will test this hypothesis by using tissue- specific genetic techniques to determine the tissues in which pdgfra and pdgf-aa function (Aim 1) as well as determine whether PI3K signaling and migratory protrusions are activated downstream of Pdgfra (Aim2). Additionally, we will use micro-rheology and micro-laser ablation in combination with pdgfra mutants to examine the biomechanical properties in the myocardium controlled by PDGF signaling (Aim 3). In summary, these studies are likely to elucidate the molecular mechanisms that underlie how myocardial cells sense and respond to their local environment and in the long-term identify the fundamental principles that underlie cardiac morphogenesis in both development and disease. Furthermore, this proposal will help to establish a research program that intertwines student research opportunities with the discovery of fundamental molecular mechanisms underlying inter-tissue communication during organ morphogenesis.
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