Lesional psoriatic epidermis displays reduced neurofibromin immunoreactivity.

Neurofibromin enhances the inactivation of protooncogene p21ras and has been suggested to function as a regulator of cell growth and differentiation. In normal skin, neurofibromin is particularly abundant in the basal keratinocytes of epidermis. The present study utilized antibodies raised against two synthetic peptides corresponding to different regions of neurofibromin. One of the antibodies recognized all forms of neurofibromin and the other was specific for type II neurofibromin. The following specimens were analyzed for neurofibromin immunoreactivity: 1) skin of apparently healthy volunteers, 2) active lesions of 15 psoriatic patients, 3) apparently healthy skin of the same patients at the time of the active phase of the disease, and 4) the previously lesional areas after anti-psoriatic treatment of the same patients. The presence of neurofibromin mRNA in normal epidermis and in keratinocytes cultured from normal skin was demonstrated by reverse transcriptase-polymerase chain reaction or by Northern hybridization. In marked contrast to normal epidermis, active psoriatic lesions were characterized by a weak immunosignal for types I and II neurofibromin in the basal cell layer of the epidermis. Previously lesional, clinically healed areas displayed variable, yet clearly detectable, expression of neurofibromin. Our results demonstrate that the epidermis of psoriatic lesions displays reduced immunostaining for type I and II neurofibromins compared to normal epidermis, and that neurofibromin immunoreactivity is partially restored concomitant with clinical healing of the lesions. The question whether the changes in neurofibromin expression in psoriasis are causal or consequential with respect to the pathogenesis of psoriasis remains to be elucidated.

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