Characterization of a newt tenascin cDNA and localization of tenascin mRNA during newt limb regeneration by in situ hybridization.

We previously showed that tenascin, a large, extracellular matrix glycoprotein, exhibits a temporally and spatially restricted distribution during urodele limb regeneration. To further investigate the role of tenascin in regeneration, we cloned a newt tenascin cDNA, NvTN.1, that has 70% homology to the chicken tenascin sequence. A deduced amino acid sequence of NvTN.1 showed a modular structure unique to tenascin characterized by epidermal growth factor-like and fibronectin type III repeats. To determine the cellular origin of tenascin protein during limb regeneration, we localized tenascin transcripts by in situ hybridization using a riboprobe synthesized from NvTN.1. Transcripts could not be detected in normal limb tissues but first became detectable in the wound epithelium at 2 days and in the distal mesoderm at 5 days after amputation. These wound epithelial cells are probably the source of tenascin protein found within and immediately underneath the wound epithelium. At preblastema stages, hybridization was seen in cells associated with most of the distal mesodermal tissues but not in dermis. At blastema stages, essentially every mesenchymal cell contained tenascin transcripts. Thus, regardless of origin, blastemal mesenchymal cells may share a common regulatory mechanism that results in tenascin gene transcription. Finally, during redifferentiation stages of regeneration, tenascin gene transcription was associated with both differentiation and growth. The results show that initiation of tenascin gene expression is an early event in regeneration and continued tenascin gene transcription is associated with some of the important processes of regeneration, namely wound epithelial-mesenchymal interactions, dedifferentiation, initiation of cell cycling, blastema outgrowth, and cellular differentiation.