Abstract
Many tissues of the human body encounter hyperosmotic stress. The effect of extracellular osmotic changes on melanin production has not yet been elucidated. In this study, we determined that hyperosmotic stress induced by organic osmolytes results in reduced melanin production in human melanoma MNT-1 cells. Under hyperosmotic stress, few pigmented mature melanosomes were detected, but there was an increase in swollen vacuoles. These vacuoles were stained with an anti-M6PR antibody that recognizes late endosomal components and with anti-TA99 and anti-HMB45 antibodies, implying that melanosome formation was affected by hyperosmotic stress. Electron microscopic analysis revealed that the M6PR-positive swollen vacuoles were multi-layered and contained melanized granules, and they produced melanin when L-DOPA was applied, indicating that these vacuoles were still capable of producing melanin, but the inner conditions were not compatible with melanin production. The vacuolation phenomenon induced by hyperosmotic conditions disappeared with treatment with the PI3K activator 740 Y-P, indicating that the PI3K pathway is affected by hyperosmotic conditions and is responsible for the proper formation and maturation of melanosomes. The microarray analysis showed alterations of the vesicle organization and transport under hyperosmotic stress. Our findings suggest that melanogenesis could be regulated by physiological conditions, such as osmotic pressure.
Highlights
Many tissues of the human body encounter hyperosmotic stress on a daily basis
Human melanoma MNT-1 cells were treated with 50 mM sucrose, and we analyzed the morphology of the intracellular organelles by immunofluorescence staining with the following antibodies: early endosome antigen 1 (EEA1) for early endosomes, mannose 6phosphate receptor (M6PR) for late endosomes and lysosomal membrane protein 1 (LAMP1) for lysosomes
We observed the down-regulation of melanin production under hyperosmotic stress in human melanoma MNT1 cells
Summary
Many tissues of the human body encounter hyperosmotic stress on a daily basis. Renal cells are normally exposed to hyperosmotic stress and maintain the blood osmolality by transporting organic osmolytes [1,2,3,4,5]. Inositol, betaine, taurine and glycerophosphorylcholine are known to be organic osmolytes in the kidney [2]. Water transport and cell hydration induce osmotic stress [8,9]. Keratinocytes maintain cell volume homeostasis by regulating the expression of organic osmolyte transporters [10,11]. Because organic osmolytes are involved in antioxidant defenses, protein stabilization and stress responses, human dermal fibroblasts sometimes express organic osmolyte transporters, and osmolytes accumulate inside the cells [12]
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