Abstract
Axolotls ( Ambystoma mexicanum ) are known for their remarkable limb-regeneration abilities, which involve the formation of the blastema, a specialized structure consisting of progenitor cells contributed by all major tissues of the limb. Lateral plate mesoderm (LPM)-derived connective tissue (CT) cells dedifferentiate and play a critical role in blastema formation and subsequent limb regeneration. However, the complexity of the blastema's cellular composition and the extent of CT participation and necessity have not been rigorously explored. To address this gap, we conducted spatial transcriptomics using a select array of probes, revealing that CT cells constitute up to 75% of the blastema cells at their peak. Genetic ablation of CT cells significantly delays or truncates limb regeneration, underscoring their necessity during this process. Finally, we analyzed the molecular profile of CT cells throughout the stages of blastema formation and made it accessible through an interactive web platform. Our work reaffirms the central role of CT cells in axolotl limb regeneration and lays the foundation for identifying molecular mechanisms that govern blastema formation during the initial phases of limb regeneration.