Alpha and beta adrenergic receptors modulate keratinocyte migration.

Keratinocyte migration into skin wounds is the step of the healing process that correlates with the wound closure rate. Keratinocyte migration, and wound epithelialization are decreased when beta 2-adrenergic receptors (B2AR) are activated by 1 µM epinephrine/adrenaline, resulting in delayed wound healing in human and mouse skin. In the present study, we found paradoxically, that in a subset of keratinocyte strains exposure to low concentrations of epinephrine (0.1 nM) increased, rather than decreased, their migratory rate. We find that both the alpha- and the beta-adrenergic receptors are expressed in human keratinocytes, and expression of alpha-2 AR subtypes demonstrated for the first time. Therefore, we tested if the alpha-AR could be modulating the increased migratory response observed in these cell strains. By using specific inhibitors to alpha-AR, we demonstrated that blocking A2B-AR could reverse the rapid cell migration induced by the 0.1 nM epinephrine. Phosphorylation of ERK was elevated after 1-10 minutes of the low epinephrine treatment and the A2B-AR inhibitor blocked the ERK phosphorylation. The results suggest that both the A2B-AR and B2AR mediate keratinocyte migration, in which with a low level of epinephrine treatment, A2B-AR could alter the B2AR signals and regulate the migration rate.

Recovery and Cultivation of Keratinocytes From Shipped Mouse Skin.

Murine keratinocyte culture from neonatal skin is an important tool for studying the functional role of specific genes in epithelial biology. However, when the transgenic animal is only available in a geographically distant local, obtaining viable keratinocytes can be problematic. A method for transferring the isolated murine skin from collaborating labs could decrease the cost of shipping live animals, and would allow the efficient use of the tissues from the transgenic animals. Here we optimized shipping conditions and characterized the cells retrieved and cultured from mouse skin shipped for 48 h at 0 °C. The cultured keratinocytes from the control, non-shipped skin and the 2-day shipped skin were 43.6 +/- 7.8% viable, doubled every 2 days, and expressed comparable amounts of heat shock proteins and CD29/integrin beta-1. However, under the same shipping conditions, the 3-day shipped tissue failed to establish colonies in the culture. Therefore, this 2-day shipping technique allows the transfer mouse skin from distant locations with recovery of viable, propagatable keratinocytes, facilitating long-distance collaborations.