UTP increases wound healing in the self assembled skin substitute (SASS)

The therapeutic potential of purinergic signaling has been explored for a wide variety of diseases, including those related to the skin. In this study, we used the self-assembled skin substitutes (SASS), a highly functional reconstructed human skin model, which shares many properties with normal human skin, to study the impact of purinergic receptors agonists, such as ATP, UTP and a P2Y receptor antagonist, Reactive Blue 2 during wound healing. After treating the wounded skins, we evaluated the wound area, reepithelialization, length of migrating tongues toward the wound, quality of the skins through the cytokeratin 10 and laminin-5 expression, epidermal and dermal cell proliferation. In addition, the expression of the main ectoenzymes capable of hydrolyzing nucleotides were investigated through the wounded SASS regions: unwounded region, wound margin, intermediate region and migrating epidermal tongue. After 3 days, under the UTP treatment, the wounded SASS showed an increase in the reepithelialization and in the proliferation of keratinocytes and fibroblasts, without altering the quality of the skin. We also identified the presence of the ectoenzymes NTPDase1 and NPP1 in the reconstructed human skin model, suggesting their involvement in wound healing. Considering the need for new therapies capable of promoting healing in complex wounds, although these results are still preliminary, they suggest the involvement of extracellular nucleotides in human skin healing and the importance to understand their role in this mechanism. New experiments it will be necessary to determine the mechanisms by which the purinergic signaling is involved in the skin wound healing. [Graphics]

Automated summary

In this study, the impact of purinergic receptor agonists on wound healing was investigated using self-assembled skin substitutes (SASS). The results showed that treatment with UTP accelerated wound healing, increased proliferation of keratinocytes and fibroblasts, and did not affect skin quality. Furthermore, the presence of ectoenzymes NTPDase1 and NPP1 in the wounded skin suggests their involvement in the wound healing process. Although these results are preliminary, they highlight the importance of understanding the role of extracellular nucleotides in skin healing and the need for further experiments to determine the underlying mechanisms.