Distinct stem-like cell populations facilitate functional regeneration of theCladonemamedusa tentacle

Abstract

AbstractBlastema formation is a crucial process that provides a cellular source for regenerating tissues and organs. While bilaterians have diversified blastema formation methods, its mechanisms in non-bilaterians remain poorly understood. Cnidarian jellyfish, or medusae, represent early-branching metazoans that exhibit complex morphology and possess defined appendage structures highlighted by tentacles with stinging cells (nematocytes). Here we investigate the mechanisms of tentacle regeneration, using the hydrozoan jellyfishCladonema pacificum. We show that proliferative cells accumulate at the tentacle amputation site and form a blastema composed of cells with stem-like cell morphology. Lineage tracing experiments indicate that repair-specific proliferative cells in the blastema are distinct from resident stem-like cells. We further demonstrate that resident stem-like cells control nematogenesis and tentacle elongation during both homeostasis and regeneration, while repair-specific proliferative cells preferentially differentiate into epithelial cells in the newly formed tentacle, analogous to lineage-restricted stem/progenitor cells observed in salamander limbs. Taken together, our findings reveal a regeneration mechanism that utilizes both resident stem-like cells and repair-specific proliferative cells, which in conjunction efficiently enable functional appendage regeneration, and provide novel insight into the diversification of blastema formation across animal evolution.