The role of keratinocyte growth factor in melanogenesis: a possible mechanism for the initiation of solar lentigines.

Solar lentigines (SLs) are hyperpigmentary lesions presented on sun-exposed areas of the skin and associated with ageing. The molecular mechanism of SL initiation is not completely understood. Ultraviolet B (UVB) stimulates keratinocytes to produce interlukin-1 alpha (IL-1α), which then induces keratinocyte growth factor (KGF) secretion; therefore, we examined their possible roles in the induction of SLs. We found that KGF increases pigment production in both pigmented epidermal equivalents and human skin explants. In addition, UVB exposure increases KGF expression, and KGF treatment induces tyrosinase (TYR) expression in primary melanocytes. The KGF-induced pigmentary changes were confirmed using pigmented Yucatan swine, and human skins grafted onto immuno-deficient mice. In both model systems, the topical treatment with KGF, alone or in combination with IL-1α, resulted in the in vivo formation of hyperpigmentary lesions with increased pigment deposition and elongated rete ridges, which resemble the histological features of human SLs. Preliminary immunohistochemical analysis of human skins showed a moderate increase in KGF, and a strong induction in KGF receptor (KGFR) in SL lesions. In summary, KGF increases pigment production and deposition in vitro and in vivo. Moreover, we show for the first time the in vivo generation of hyperpigmentary lesions with histological resemblance to human SLs and indicate the involvement of KGF/KGFR in the molecular pathology of human SLs.

Melanocortin-5 receptor: a marker of human sebocyte differentiation.

Melanocortin receptors (MC1R-MC5R) and their ligands (melanocyte-stimulating hormone (MSH) and adrenocorticotrophin hormone (ACTH)) have been shown to influence physiological functions of cells and organs, including exocrine glands. Since relatively little is known about MC5R expression and function in the human sebaceous gland, we examined expression of MC5R by immunohistochemistry and RT-PCR in human sebaceous cells in vivo and in vitro. In human skin, MC5R was detected only in differentiating, lipid-laden sebaceous cells but not in basal, undifferentiated sebaceous cells. Similarly, in cultured human sebocytes MC5R was only detectable at the onset of differentiation and in fully differentiated cells displaying prominent lipid granules. The lipid profile of the cultured and differentiated human sebocytes was shown to be human sebum-specific using (14)C-acetate labeling and high performance thin layer chromatography. Our studies suggest that MC5R is a marker of human sebocyte differentiation.

Melanocortin-5 receptor and sebogenesis.

The melanocortins (α-MSH, ß-MSH, γ-MSH, and ACTH) bind to the melanocortin receptors and signal through increases in cyclic adenosine monophosphate to induce biological effects. The melanocortin MC(5) and MC(1) receptors are expressed in human sebaceous glands, which produce sebum, a lipid mixture of squalene, wax esters, triglycerides, cholesterol esters, and free fatty acids that is secreted onto the skin. Excessive sebum production is one of the major factors in the pathogenesis of acne. The expression of melanocortin MC(5) receptor has been associated with sebocyte differentiation and sebum production. Sebaceous lipids are down-regulated in melanocortin MC(5) receptor-deficient mice, consistent with the observation that α-MSH acts as a sebotropic hormone in rodents. These findings, which suggest that melanocortins stimulate sebaceous lipid production through the MC(5) receptor, led to our search for MC(5) receptor antagonists as potential sebum-suppressive agents. As predicted, an antagonist was shown to inhibit sebocyte differentiation in vitro, and to reduce sebum production in human skin transplanted onto immunodeficient mice. The melanocortin MC(5) receptor antagonists may prove to be clinically useful for the treatment of sebaceous disorders with excessive sebum production, such as acne.

A melanocortin receptor 1 and 5 antagonist inhibits sebaceous gland differentiation and the production of sebum-specific lipids.

BACKGROUND: The melanocortin receptor-5 (MC5R) is present in human sebaceous glands, where it is expressed in differentiated sebocytes only. The targeted disruption of MC5R in mice resulted in reduced sebaceous lipid production and a severe defect in water repulsion. OBJECTIVE: To investigate the physiological function of MC5R in human sebaceous glands. METHODS: A novel MC1R and MC5R antagonist (JNJ-10229570) was used to treat primary human sebaceous cells or human skins grafted onto severe combined immunodeficient (SCID) mice. Transcription profiling, lipid analyses, and histological and immunohistochemical staining were used to analyze the effect of MC5R inhibition on sebaceous gland differentiation and sebum production. RESULTS: JNJ-10229570 dose dependently inhibited the production of sebaceous lipids in cultured primary human sebocytes. Topical treatment with JNJ-10229570 of human skins transplanted onto SCID mice resulted in a marked decrease in sebum-specific lipid production, sebaceous gland's size and the expression of the sebaceous differentiation marker epithelial-membrane antigen (EMA). Treatment with flutamide, a known inhibitor of sebum production, gave similar results, validating the human skin/SCID mouse experimental system for sebaceous secretion studies. CONCLUSION: Our data suggest that antagonists of MC1R and MC5R could be effective sebum suppressive agents and might have a potential for the treatment of acne and other sebaceous gland pathologies.

Sebum analysis of individuals with and without acne.

A pilot study was conducted to compare lipid components of sebum from unaffected and acne-affected individuals. Nine males, 15-20 years old, with no acne, or with moderate to severe acne, were recruited. Facial images were taken with regular, polarized and fluorescent lights for each subject. Skin surface lipids were analyzed following collection of sebum using sebutapes. As expected, the subjects with acne had more (59%) sebum than the control subjects. Free fatty acids were the only lipid group that was reduced in the sebum of acne subjects. The specific lipid that differed the most between the two groups was squalene, which was upregulated in acne subjects by 2.2-fold on a quantitative basis. Squalene also represented a significantly greater proportion of the total sebaceous lipids in acne patients compared to controls (20% vs. 15%). The increase in the amount of squalene could represent a lipid marker for acne prone skin.