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Axis formation in annual killifish: Nodal and β-catenin regulate morphogenesis without Huluwa prepatterning

Philip B. Abitua, Laura M. Stump, Deniz C. Aksel, Alexander F. Schier

2024Science13 citationsDOIOpen Access PDF

Abstract

Axis formation in fish and amphibians typically begins with a prepattern of maternal gene products. Annual killifish embryogenesis, however, challenges prepatterning models as blastomeres disperse and then aggregate to form the germ layers and body axes. We show that huluwa , a prepatterning factor thought to break symmetry by stabilizing β-catenin, is truncated and inactive in Nothobranchius furzeri . Nuclear β-catenin is not selectively stabilized on one side of the blastula but accumulates in cells forming the aggregate. Blocking β-catenin activity or Nodal signaling disrupts aggregate formation and germ layer specification. Nodal signaling coordinates cell migration, establishing an early role for this signaling pathway. These results reveal a surprising departure from established mechanisms of axis formation: Huluwa-mediated prepatterning is dispensable, and β-catenin and Nodal regulate morphogenesis.

Topics & Concepts

Nodal signalingNODALGerm layerKillifishCell biologyBlastulaWnt signaling pathwayBiologyMorphogenesisBlastomereZebrafishSignal transductionAnatomyEmbryogenesisEmbryoGeneticsEmbryonic stem cellGastrulationGeneFish <Actinopterygii>FisheryInduced pluripotent stem cellDevelopmental Biology and Gene RegulationIchthyology and Marine BiologyFish biology, ecology, and behavior