Characterization and in vitro neural differentiation of human dental pulp stem cells

Post-natal stem cells have been isolated from a multiple source of tissues, as bone marrow, brain, skin, hair follicle and muscle. Many works have shown that these cells exhibit plasticity higher than the first believed and are able to transdifferentiate into cells from other germ layer origin. From dental pulp tissue is possible to isolate a population of multipotent stem cell which have mesenchymal origin and are supposed to be derived from neural crest. They can be induced to differentiate into mesodermal cell types, like chondrocyte, osteocyte and adipocyte. It has been also reported that they are able to transdifferentiate into neural cells. However, increasing data suggests that neural transdifferentiation of cells from mesenchymal origin, actually, may be an artifact of culture, due to cellular stress, for example. In front of this, it becomes of great importance to show that the expected differentiated cells exhibit functional responses, by the investigation of electrophysiological properties. Here we describe a population of undifferentiated human dental pulp stem cell that can be induced to differentiate into adipocytes and osteocytes in vitro. When treated with retinoic acid they showed neural cell like morphology, expressed neural markers and were able to fire action potentials. However, curiously, undifferentiated cells also exhibited the same responses, limiting the interpretation of neural treatment effect and, therefore, restricting the use of IDPSCs as a model for neural differentiation in vitro. Although the question of whether or not DPSC are able to become a neuron remains unsolved, these cells were able to direct neural differentiation of embryonic stem cells in co-culture assays. These findings in conjunction with previous works which shows DPSCs can exercise neuroprotective and neurotrophic effects indicate they may be a feasible candidate for cellular therapy. (AU)