Merkel Cells as Putative Regulatory Cells in Skin Disorders: An In Vitro Study

Merkel cells (MCs) are involved in mechanoreception, but several lines of evidence suggest that they may also participate in skin disorders through the release of neuropeptides and hormones. In addition, MC hyperplasias have been reported in inflammatory skin diseases. However, neither proliferation nor reactions to the epidermal environment have been demonstrated. We established a culture model enriched in swine MCs to analyze their proliferative capability and to discover MC survival factors and modulators of MC neuroendocrine properties. In culture, MCs reacted to bFGF by extending outgrowths. Conversely, neurotrophins failed to induce cell spreading, suggesting that they do not act as a growth factor for MCs. For the first time, we provide evidence of proliferation in culture through Ki-67 immunoreactivity. We also found that MCs reacted to histamine or activation of the proton gated/osmoreceptor TRPV4 by releasing vasoactive intestinal peptide (VIP). Since VIP is involved in many pathophysiological processes, its release suggests a putative regulatory role for MCs in skin disorders. Moreover, in contrast to mechanotransduction, neuropeptide exocytosis was Ca2+-independent, as inhibition of Ca2+ channels or culture in the absence of Ca2+ failed to decrease the amount of VIP released. We conclude that neuropeptide release and neurotransmitter exocytosis may be two distinct pathways that are differentially regulated

The whole epidermis as the forefront of the sensory system

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Mechanisms of the sensory effects of tacrolimus on the skin

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Presence of putative stem cells in Merkel cell carcinomas.

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Rat Merkel cells are mechanoreceptors and osmoreceptors.

Merkel cells (MCs) associated with nerve terminals constitute MC-neurite complexes, which are involved in slowly-adapting type I mechanoreception. Although MCs are known to express voltage-gated Ca2+ channels and hypotonic-induced membrane deformation is known to lead to Ca2+ transients, whether MCs initiate mechanotransduction is currently unknown. To answer to this question, rat MCs were transfected with a reporter vector, which enabled their identification.Their properties were investigated through electrophysiological studies. Voltage-gated K+, Ca2+ and Ca2+-activated K+ (KCa)channels were identified, as previously described. Here, we also report the activation of Ca2+ channels by histamine and their inhibition by acetylcholine. As a major finding, we demonstrated that direct mechanical stimulations induced strong inward Ca2+ currents in MCs. Depolarizations were dependent on the strength and the length of the stimulation. Moreover, touch-evoked currents were inhibited by the stretch channel antagonist gadolinium. These data confirm the mechanotransduction capabilities of MCs. Furthermore, we found that activation of the osmoreceptor TRPV4 in FM1-43-labeled MCs provoked neurosecretory granule exocytosis. Since FM1-43 blocks mechanosensory channels, this suggests that hypo-osmolarity activates MCs in the absence of mechanotransduction. Thus, mechanotransduction and osmoreception are likely distinct pathways

Effects of sangre de drago in an in vitro model of cutaneous neurogenic inflammation.

International audienceSangre de drago (SD) is a viscous bright red resin collected from Croton lechleri trees that grow in the South American jungle. This sap is used extensively in the native pharmacopoeia to treat skin disorders. Its effectiveness as an inhibitor of neurogenic inflammation has been recently demonstrated. To understand the underlying mechanisms of these effects, we examined the ability of SD to reduce substance P (SP) release in an in vitro model of cutaneous neurogenic inflammation (CNI). This model is based on an enzyme immunoassay of SP (an inducer of CNI) in a porcine co-culture of dorsal root ganglion neurons and keratinocytes. After incubation with different concentrations of SD, we noted an immediate and significant dose-dependent decrease in basal SP release, with average values of 32% at 1% SD (v/v) and 26% at 0.1% (v/v). On the other hand, pretreatment (72 or 1 h) of the co-culture with 1% SD (v/v) was sufficient to induce a 111% (72 h) or 65% (1 h) inhibition of capsaicin-induced SP release, while 0.1% SD (v/v) triggered a 109% (72 h) or 30% (1 h) inhibition. We conclude that sangre de drago is a potent inhibitor of CNI through direct inhibition of neuropeptide release by sensory afferent nerves