Yuzo Yoshida

Urokinase-type plasminogen activator is activated in stratum corneum after barrier disruption

The plasminogen/plasmin system in epidermis is thought to be the major protease involved in the delay of barrier recovery. However, little is known about the mechanism through which this system is activated. In order to clarify this mechanism, we first determined the distribution of proteolytic activity by using in situ zymography. As a result, plasminogen-activator activity was found to be present in the stratum corneum (SC) after barrier disruption. Next, SC subjected to repeated barrier disruption was collected to identify the protease. The protease was identified as urokinase-type plasminogen activator, because flybrinolytic activity of the collected SC was abolished by addition of anti-urokinase antibody. Urokinase activation in SC was confirmed by means of an in vitro assay, in which the precursor of urokinase (pro-uPA) became active after incubation with the insoluble component of SC homogenate. These findings indicated that urokinase-type plasminogen activator is activated in SC after barrier disruption and this activation might trigger the plasminogen/plasmin system in the epidermis.

Localization of Serine Racemase and Its Role in the Skin

D-Serine is an endogenous coagonist of the N-methyl-D-aspartate (NMDA)–type glutamate receptor in the central nervous system and its synthesis is catalyzed by serine racemase (SR). Recently, the NMDA receptor has been found to be expressed in keratinocytes (KCs) of the skin and involved in the regulation of KC growth and differentiation. However, the localization and role of SR in the skin remain unknown. Here, using SR-knockout (SR-KO) mice as the control, we demonstrated the localization of the SR protein in the granular and cornified layer of the epidermis of wild-type (WT) mice and its appearance in confluent WT KCs. We also demonstrated the existence of a mechanism for conversion of L-serine to D-serine in epidermal KCs. Furthermore, we found increased expression levels of genes involved in the differentiation of epidermal KCs in adult SR-KO mice, and alterations in the barrier function and ultrastructure of the epidermis in postnatal day 5 SR-KO mice. Our findings suggest that SR in the skin epidermis is involved in the differentiation of epidermal KCs and the formation of the skin barrier.

Immunohistochemical survey of the distribution of epidermal melanoblasts and melanocytes during the development of UVB-induced pigmented spots

BACKGROUND Repeated exposures to ultraviolet B radiation (UVB) induce pigmented spots on dorsal skin of (HR-1 x HR/De) F(1) hairless mouse. We showed previously that this mouse is suitable for studies of melanocyte function. OBJECTIVE To clarify the mechanism of development of pigmented spots induced by chronic UVB exposure. METHODS We used light and fluorescence microscopy to quantify changes in the numbers of differentiated melanocytes containing melanin pigments (MM) and melanoblasts/melanocytes immunohistochemically positive for tyrosinase-related protein (TRP)-1, TRP-2 (dopachrome tautomerase), and c-kit in epidermis during the development of pigmented spots in hairless mice chronically exposed to UVB (99 mJ/cm(2), 3 times/week, 8 weeks). RESULTS The change in the number of TRP-1-positive cells during chronic UVB exposure was similar to that of MM: both increased dramatically during the stage of acute pigmentation, then decreased sharply after cessation of UVB, concomitantly with depigmentation; subsequently they increased gradually with the development of pigmented spots. In contrast, after two UVB exposures, no c-kit-positive cells were detected, then the number gradually increased during UVB irradiation, and continued to increase after cessation of irradiation; TRP-2-positive cells showed a rather similar pattern, except that they did not disappear initially. CONCLUSION Our results indicate that chronic UVB irradiation induces differentiation and proliferation of melanoblasts, followed by an increase of differentiated melanocytes, leading to the development of pigmented spots. The sequence of expression of markers appeared to be c-kit, TRP-2, TRP-1, and finally melanin, as it is during normal melanocyte differentiation.