Abstract
Regeneration of tissues that have been damaged by cell loss requires new growth, often via proliferation of precursor cells followed by differentiation to replace loss of specific cell types. When regeneration occurs after normal differentiation of the tissue is complete, developmental pathways driving differentiation must be re-activated. How proliferation and differentiation are induced and balanced during regeneration is not well understood. To investigate these processes, we utilized a paradigm for tissue damage and regeneration in the developing Drosophila melanogaster eye. Previous studies have demonstrated that tissue damage resulting from extensive cell death stimulates quiescent, undifferentiated cells in the developing larval eye to re-enter the cell cycle and proliferate. Whether these cells are restricted to certain fates or can contribute to all retinal cell types and thus potentially be fully regenerative is not known. Here we found by fate mapping experiments that these cells are competent to differentiate into all accessory cell types in the retina but do not differentiate into photoreceptors, likely because cell cycle re-entry in response to damage occurs after photoreceptor differentiation has completed. We conclude that the ability to re-enter the cell cycle in response to tissue damage in the developing Drosophila eye is not restricted to precursors of a specific cell type and that cell cycle re-entry following damage does not disrupt developmental programs that control differentiation.