Long-Range Coupling of Posterior Cell Addition and Anterior Vacuolation Provides Robustness in Notochord Elongation
Abstract
Robust tissue growth control requires long-range communication between the rate of progenitor addition and tissue expansion. However, the regulatory mechanisms that couple these two processes are unknown. In zebrafish, notochord morphogenesis is a principal driver of axis extension through the combined actions of posterior progenitor addition and anterior vacuolation. To elucidate how progenitor dynamics and vacuole-driven cell expansion interact to shape notochord development, we first generated a mathematical model that links progenitor addition rate to the progressive expansion of cells from anterior-to-posterior to simulate vacuolation rate. Comparing this with empirical measurements, we find that progenitor incorporation together with vacuolation, produces a linear gradient in nearest neighbour distance. We next explored the role of YAP/TAZ in regulating the rate of progenitor addition in mutants for YAP/TAZ inhibitor vgll4b . We find that vgll4b expression and YAP activity are enriched in posterior midline progenitors. Loss of vgll4b elevates YAP signaling, enhances progenitor addition, restricts vacuole expansion, and—after a transient buffering phase—compromises A-P axis elongation. These results support a long-range feedback mechanism linking progenitor recruitment to vacuolation, enabling the notochord to balance cellular input with volumetric expansion, thereby maintaining tissue proportions.
Graphical abstract. Proposed working model
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A . Schematic representation of the authors’ proposed model illustrating how increased YAP activation in notochord progenitors of vgll4b mutants leads to enhanced progenitor addition to the notochord. This increased incorporation subsequently compromises the ability of notochord cells to undergo proper vacuolation, resulting in reduced axial elongation compared with control embryos.
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