The ability of the novel water-soluble provitamin E, alpha-tocopherol-6-O-phosphate, to protect against ultraviolet B-induced damage in cultured mouse skin was investigated and compared with the protectiveness of alpha-tocopherol acetate in cultured mouse skin. Pretreatment of skin with 0.5% (9.4 mM) alpha-tocopherol-6-O-phosphate in medium for 3 h significantly prevented such photodamage as sunburn cell formation, DNA degradation, and lipid peroxidation, which were induced in control cultured skin by a single dose of ultraviolet B irradiation at 0 to 40 kJ per m2 (290-380 nm, maximum 312 nm). This protection was greater than that seen with alpha-tocopherol acetate, the most common provitamin E that is used in commercial human skin care products. The concentration of alpha-tocopherol in cultured skin pretreated with 0.5% alpha-tocopherol-6-O-phosphate rose to approximately two to three times that found in the control skin and the reduction in cutaneous alpha-tocopherol that was induced by ultraviolet irradiation was significantly inhibited. In the group pretreated with 0.5% alpha-tocopherol acetate, however, conversion of alpha-tocopherol acetate to alpha-tocopherol was not observed, although the level of provitamin incorporated into the cultured skin was the same as that for alpha-tocopherol-6-O-phosphate. These findings indicated that the enhanced ability of alpha-tocopherol-6-O-phosphate to protect against ultraviolet B-induced skin damage compared with alpha-tocopherol acetate may have been due to alpha-tocopherol-6-O-phosphate's conversion to alpha-tocopherol. Moreover, following pretreatment with a 0.5% alpha-tocopherol-6-O-phosphate, alpha-tocopherol-6-O-phosphate was incorporated into the human skin in a three-dimensional model and 5% of the incorporated alpha-tocopherol-6-O-phosphate was converted to alpha-tocopherol. These results suggest that treatment with the novel provitamin E, alpha-tocopherol-6-O-phosphate may be useful in preventing ultraviolet-induced human skin damage.
Accumulated evidence suggests that Parp-1 is involved in DNA repair processes, including base excision repair, single-strand and double-strand break repairs. To understand the precise role of Parp-1 in genomic stability in vivo, we carried out mutation analysis using Parp-1 knockout (Parp-1 À/À ) mice harboring two marker genes, gpt and red/gam genes. Spontaneous mutant frequencies of both genes in the bone marrows and livers did not differ significantly between Parp-1 À/À and Parp-1 þ / þ mice (P>0.05). After treatment with an alkylating agent, Nnitrosobis(2-hydroxypropyl)amine (BHP), the mutant frequency of the red/gam genes in the liver in Parp-1 À/À mice was 1.6-fold higher than that in Parp-1 þ / þ mice (Po0.05). Categorization of the mutations revealed that deletions larger than 1 kb or those accompanying 1-5 bp insertions at the deletion junctions, as well as rearrangements, were more frequently observed in Parp-1 À/À than in Parp-1 þ / þ mice (Po0.05, respectively). In contrast, mutant frequencies of the gpt gene in the livers of Parp-1 À/À and Parp-1 þ / þ mice after BHP treatment were both elevated and there was no significant difference between the genotypes. These results indicate that Parp-1 is implicated in suppressing deletion mutations in vivo, especially those accompanying small insertions or rearrangements.
Protective Effect of Magnesium‐L‐Ascorbyl‐2 Phosphate Against Skin Damage Induced by UVB Irradiation
The protective effect of magnesium-L-ascorbyl-2-phosphate (MAP) on cutaneous photodamage such as lipid peroxidation and inflammation induced by ultraviolet B (UVB) exposure (290-320 nm, max. 312 nm) was investigated using hairless mice. When MAP was administered intraperitoneally to mice at a dose of 100 mg of ascorbic acid (AS) per kg body weight base immediately before irradiation (15 kj/m2), the expected increases in thiobarbituric acid reactive substance (TBARS) formation in skin and serum sialic acid, indices of lipid peroxidation and inflammatory reaction, respectively, were significantly reduced. However, the expected decrease in the level of cutaneous AS was unchanged. Similar results were observed for animals given 100 mg of AS-Na per kg body weight before UVB irradiation. When MAP was administered intracutaneously immediately before irradiation, the expected UVB-induced increases in TBARS and sialic acid were again significantly prevented. Ascorbic acid-Na had a less protective effect than intracutaneous MAP administration. The cutaneous AS level was significantly higher in the MAP-treated mice than in the controls, and the UVB-induced decrease in tissue AS was prevented by intracutaneous MAP administration. These results suggest that MAP protects against UVB irradiation-induced lipid peroxidation and inflammation in cutaneous tissue, regardless of the drug administration route. We found, in an in vitro experiment, that MAP was converted to AS as it crossed the epidermis, but that AS-Na did not pass through the epidermis. Furthermore, MAP was also converted to AS in serum. These results suggest that the protective effect of MAP on UVB-induced cutaneous damage is due to conversion of MAP to AS.
Topical Application of a Novel, Hydrophilic γ-Tocopherol Derivative Reduces Photo-Inflammation in Mice Skin
We previously demonstrated that a novel hydrophilic gamma-tocopherol (gamma-Toc) derivative, gamma-tocopherol-N,N-dimethylglycinate hydrochloride (gamma-TDMG) converts to gamma-Toc in the mouse skin and has a higher bioavailability than gamma-Toc itself. In the present study, we determined whether gamma-TDMG could reduce photo-inflammation in mouse skin, and compared its effectiveness to that of alpha-Toc acetate (alpha-TA). Topical pre- or post-application of 5% gamma-TDMG significantly reduced the formation of edema and tempered the increase in cyclooxygenase-2 (COX-2)-catalyzed synthesis of prostaglandin E2 (PGE2) that were induced by a single dose of UV irradiation of 2 kJ/m2 (290-380 nm, maximum 312 nm). The pre-treatment of mouse skin with 10% alpha-TA had the same anti-inflammatory effect as did gamma-TDMG. In spite of same having the ability to reduce PGE2 levels, the effect of gamma-TDMG pre-treatment on the inhibition of COX-2 mRNA/protein expression was less than that seen with 10% alpha-TA. In contrast, the increase in COX-2 activity seen after UV exposure was reduced more by gamma-TDMG than by alpha-TA, suggesting that the reduction in PGE2 levels might have been due to the direct inhibition of COX-2 activity by gamma-TDMG-derived gamma-Toc. Both Toc derivatives strongly suppressed inducible nitric oxide synthase (iNOS) mRNA expression and nitric oxide (NO) production, both of which play important roles in UV-induced inflammation. Both derivatives also significantly reduced lipid peroxidation in response to UV exposure, though gamma-TDMG's ability in this regard was less than that seen with alpha-TA, which correlated with their abilities to suppress COX-2 expression. Thus, the gamma-TDMG-derived gamma-Toc acts as an antioxidant, suppresses iNOS expression and directly inhibits COX-2 activity, all of which likely play a role in mediating its suppressive effects on photo-inflammation. Our data further suggest that the topical application of gamma-TDMG, a novel hydrophilic gamma-Toc derivative, may be efficacious in preventing and reducing UV-induced inflammation in humans.
Mouse milk fat globule-EGF factor 8, MFG-E8, is the ortholog to the human mammary tumor marker, lactadherin, and comprises two spliced variants, the L and S forms. Recent studies have suggested that MFG-E8-L produced by macrophages and Langerhans cells in the skin serves as a linker between phagocytic cells and apoptotic cells, and that MFG-E8-S, also termed SED1, facilitates sperm-egg interaction for fertilization. However, Mfge8 gene expression occurs in various tissues apparently unrelated to these critical events. Our in situ hybridization study has revealed that Mfge8 is expressed in the periderm (the premature epidermis) on embryonic day-14, well before Langerhans cells begin to grow in the prenatal phase. Mfge8 transcript is detectable in the basal and spinous layers throughout skin development, whereas immunostaining has revealed MFG-E8 protein accumulation in the spinous layer. Cultured keratinocyte stem cells consistently express Mfge8-L and -S mRNAs and produce the L protein, which is primarily detectable in the culture supernatant, and the S protein, which is mostly associated with the cells. Upon Ca(2+)-stimulated differentiation, which is detected by a decrease in keratinocyte stem cell marker p63(p51) and the induction of keratin1, we have observed suppression of Mfge8, and the protein becomes localized to the cell-cell borders. Papillomas and carcinomas caused by chronic UV-B irradiation produce MFG-E8 as determined by immunostaining. Thus, undifferentiated and poorly differentiated keratinocytes produce the L and S forms of MFG-E8 during normal and pathological tissue development, probably to support an as yet unidentified membrane function.
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