Death is the major fate of medial edge epithelial cells and the cause of basal lamina degradation during palatogenesis

doi:10.1242/dev.00907

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Development ePress online publication date 26 Nov 2003
doi: 10.1242/dev.00907

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Research article

Death is the major fate of medial edge epithelial cells and the cause of basal lamina degradation during palatogenesis

Rodrigo Cuervo and Luis Covarrubias^*
^* Author for correspondence (e-mail: covs{at}ibt.unam.mx)

During mammalian development, a pair of shelves fuses to formthe secondary palate, a process that requires the adhesion ofthe medial edge epithelial tissue (MEE) of each shelf and thedegeneration of the resulting medial epithelial seam (MES).It has been reported that epithelial-mesenchymal transformation(EMT) occurs during shelf fusion and is considered a fundamentalprocess for MES degeneration. We recently found that cell deathis a necessary process for shelf fusion. These findings uncoveredthe relevance of cell death in MES degeneration; however, theydo not discard the participation of other processes. In thepresent work, we focus on the evaluation of the processes thatcould contribute to palate shelf fusion. We tested EMT by traditionallabeling of MEE cells with a dye, by infection of MEE with anadenovirus carrying the lacZ gene, and by fusing wild-type shelveswith the ones from EGFP-expressing mouse embryos. Fate of MEElabeled cells was followed by culturing whole palates, or bya novel slice culture system that allows individual cells tobe followed during the fusion process. Very few labeled cellswere found in the mesenchyme compartment, and almost all wereundergoing cell death. Inhibition of metalloproteinases preventedbasal lamina degradation without affecting MES degenerationand MEE cell death. Remarkably, independently of shelf fusion,activation of cell death promoted the degradation of the basallamina underlying the MEE ('cataptosis'). Finally, by specificlabeling of periderm cells (i.e. the superficial cells thatcover the basal epithelium), we observed that epithelial trianglesat oral and nasal ends of the epithelial seam do not appearto result from MEE cell migration but rather from periderm cellmigration. Inhibition of migration or removal of these peridermcells suggests that they have a transient function controllingMEE cell adhesion and survival, and ultimately die within theepithelial triangles. We conclude that MES degeneration occursalmost uniquely by cell death, and for the first time we showthat this process can activate basal lamina degradation duringa developmental process.

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