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Myocardial Afterload Is a Key Biomechanical Regulator of Atrioventricular Myocyte Differentiation in Zebrafish. | LitMetric

AI Article Synopsis

  • Heart valve development is influenced by genetic factors and the mechanical forces of blood flow, particularly oscillating shear stress vital for normal atrioventricular (AV) valve formation.
  • This study uses a zebrafish model to show that increased myocardial afterload, induced by the drug vasopressin, leads to significant changes in embryonic heart growth and structure.
  • The findings indicate that defects in valve formation and function arise from altered signaling in heart cells rather than direct pressure effects on the valve cells, emphasizing the critical role of biomechanical factors in embryonic valve development.

Article Abstract

Heart valve development is governed by both genetic and biomechanical inputs. Prior work has demonstrated that oscillating shear stress associated with blood flow is required for normal atrioventricular (AV) valve development. Cardiac afterload is defined as the pressure the ventricle must overcome in order to pump blood throughout the circulatory system. In human patients, conditions of high afterload can cause valve pathology. Whether high afterload adversely affects embryonic valve development remains poorly understood. Here we describe a zebrafish model exhibiting increased myocardial afterload, caused by vasopressin, a vasoconstrictive drug. We show that the application of vasopressin reliably produces an increase in afterload without directly acting on cardiac tissue in zebrafish embryos. We have found that increased afterload alters the rate of growth of the cardiac chambers and causes remodeling of cardiomyocytes. Consistent with pathology seen in patients with clinically high afterload, we see defects in both the form and the function of the valve leaflets. Our results suggest that valve defects are due to changes in atrioventricular myocyte signaling, rather than pressure directly acting on the endothelial valve leaflet cells. Cardiac afterload should therefore be considered a biomechanical factor that particularly impacts embryonic valve development.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8779957PMC
http://dx.doi.org/10.3390/jcdd9010022DOI Listing

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