Fermentable metabolite of Zymomonas mobilis controls collagen reduction in photoaging skin by improving TGF-beta/Smad signaling suppression

Solar ultraviolet (UV) irradiation causes damages on human skin and premature skin aging (photoaging). UV-induced reduction of type I collagen in dermis is widely considered primarily induction of wrinkled appearance of photoaging skin. Type I procollagen synthesis is reduced under UV irradiation by blocking transforming growth factor-beta (TGF-beta)/Smad signaling; more specifically, it is down-regulation of TGF-beta type II receptor (T beta RII). Therefore, preventing UV-induced loss of T beta RII results decreased type I collagen reduction in photoaging skin. Zymomonas mobilis is an alcohol fermentable, gram-negative facultative anaerobic bacterium whose effect on skin tissue is scarcely studied. We investigated the protective effects of fermentable metabolite of Z. mobilis (FM of Z. mobilis) against reduction of type I procollagen synthesis of UV-induced down-regulation of T beta RII in human dermal fibroblasts FM of Z. mobilis was obtained from lyophilization of bacterium culture supernatant. The levels of T beta RII and type I procollagen mRNA in human dermal fibroblasts were measured by quantitative real-time RT-PCR, and T beta RII protein levels were assayed by western blotting. T beta RII, type I procollagen, and type I collagen proteins in human dermal fibroblasts or hairless mouse skin were detected by immunostaining. FM of Z. mobilis inhibited down regulation of T beta RII mRNA, and protein levels in UVB irradiated human dermal fibroblasts consequently recover reduced type I procollagen synthesis. These results indicate UVB irradiation inhibits type I procollagen synthesis by suppression of TGF-beta/Smad signaling pathway, and FM of Z. mobilis has inhibitory effect on UVB-induced reduction of type I procollagen synthesis. While short period UVB irradiation decreased both T beta RII and type I procollagen protein levels in hairless mouse skin, topical application of FM of Z. mobilis prevented this decrease. Wrinkle formation in hairless mouse skin surface was accelerated by continuous 5 month UVB irradiation along with a reduction of type I collagen in the dermis, but this change was prevented by topical application of FM of Z. mobilis. From this experimental data, it is suggested that FM of Z. mobilis is effective for suppression of wrinkle formation in photoaging skin by inhibition of type I procollagen synthesis reduction.     

Possible involvement of gelatinases in basement membrane damage and wrinkle formation in chronically ultraviolet B-exposed hairless mouse

A number of studies indicate that matrix metalloproteinase might be involved in photoaging, but little is known about their direct contribution to ultraviolet-induced histologic and morphologic changes in the skin in vivo. This study reports the relationship between changes of matrix metalloproteinase activities and ultraviolet B-induced skin changes in hairless mouse. The role of matrix metalloproteinase in the skin changes was studied by topical application of a specific matrix metalloproteinase inhibitor. The backs of mice were exposed to ultraviolet B three times a week for 10 wk. Histologic studies showed that the basement membrane structure was damaged, with epidermal hyperplasia, in the first 2 wk of ultraviolet B irradiation, followed by the appearance of wrinkles, which gradually extended in the latter half of the ultraviolet B irradiation period. We observed enhancement of type IV collagen degradation activity, but not collagenase or matrix metalloproteinase-3 activity, in extracts of ultraviolet B-irradiated, wrinkle-bearing skin. Gelatin zymographic analysis revealed that gelatinases, matrix metalloproteinase-9 and matrix metalloproteinase-2, were significantly increased in the extract. In situ zymographic study clarified that the activity was specifically localized in whole epidermis of ultraviolet B-irradiated, wrinkled skin in comparison with normal skin. The activity was induced around the basal layer of the epidermis by a single ultraviolet exposure of at least one minimal erythema dose. Furthermore, topical application of a specific matrix metalloproteinase inhibitor, CGS27023A, inhibited ultraviolet B-induced gelatinase activity in the epidermis, and its repeated application prevented ultraviolet B-induced damage to the basement membrane, as well as epidermal hyperplasia and dermal collagen degradation. Ultraviolet B-induced wrinkles were also prevented by administration of the inhibitor. These results, taken together, suggest that ultraviolet B-induced enhancement of gelatinase activity in the skin contributes to wrinkle formation through the destruction of basement membrane structure and dermal collagen in chronically ultraviolet B-exposed hairless mouse, and thus topical application of matrix metalloproteinase inhibitors may be an effective way to prevent ultraviolet B-induced wrinkle formation.     

Ultrastructural effects of UVB radiation and subsequent retinoic acid treatment on the skin of hairless mice

The ultrastructure of hairless mouse skin exposed to UVB radiation and followed by retinoic acid treatment was studied to identify alterations induced in both epidermis and dermis. Female mice were irradiated 3 times weekly for 5-6 months; a group of these mice was then treated topically 3 times weekly for 10 weeks with either 25 micrograms all-trans-retinoic acid dissolved in acetone or with acetone alone. Age-matched, unexposed, untreated mice served as controls. Cutaneous changes induced by UVB radiation included keratinocyte mitochondrial inclusions often accompanied by damaged cristae, duplication of basement membrane, increased number of dermal fibroblasts, inflammatory cells and elastic fibers, and abnormal elastic fibers. Subsequent retinoic acid treatment resulted in more prominent mitochondrial inclusions which sometimes coalesced to form irregular contoured bodies. Also observed were lipid droplets in the stratum corneum, glycogen deposits in keratinocytes and granular material in dilated keratinocyte endoplasmic reticulum. Poorly differentiated epidermis with necrotic or apoptotic cells was present in some specimens. Elastic fibers were fewer and usually morphologically normal. Skin exposed to UVB and treated with vehicle appeared similar to control except for the presence of excess basement membrane and occasional small mitochondrial inclusions. Because of the heightened concern regarding UV radiation-induced damage to the human skin and the current topical use of retinoids, the cutaneous changes described are considered worthy of attention.     

Skin rejuvenating effects of chemical peeling: a study in photoaged hairless mice

Background Chemical peeling is a dermatologic treatment for skin aging. However, the mechanism by which the chemical peel achieves its results is not clear. We investigated the effects of chemical peeling and the mechanism of wrinkle reduction in photoaged hairless mice skin. Methods After inducing photoaged skin in hairless mice by repetitive ultraviolet‐B irradiation applied over 14 weeks, we applied trichloroacetic acid (TCA) 30%, TCA 50%, and phenol on areas of the same size on the backs of the mice. Punch biopsies were obtained 7, 14, 28, and 60 days after the procedure for histologic and immunohistochemical analyses. Results Histologic examination showed an increase in dermal thickness, collagen fibers, and elastic fibers in the dermis of intervention groups compared with control groups. These increases were maintained significantly for 60 days. Conclusions This study demonstrates that chemical peeling reduces wrinkles and regenerates skin by increasing dermal thickness and the amount of collagen and elastic fibers in photoaged skin.     

Collagen metabolism in ultraviolet irradiated hairless mouse skin and its correlation to histochemical observations

Early biochemical studies of ultraviolet (UV) irradiated human skin reported a loss of insoluble collagen with a concomitant increase in the soluble fraction. Recent work has described an early increase in type III collagen during chronic irradiation of hairless mice as determined by cyanogen bromide digests of whole skin. In order to understand the correlation of these events and those seen with histochemistry, in the present study we irradiated hairless mice for up to 24 weeks with approximately 4 minimal erythema doses (MEDs) of UVB thrice weekly with Westinghouse FS-40 bulbs. Skin samples were taken at 4-week intervals from irradiated and age-matched control mice. Collagen was isolated from other skin proteins by acid extraction, pepsin digestion, and salt precipitation. Estimates of types I and III collagen were made by interrupted polyacrylamide gel electrophoresis and densitometric scanning. Compared with unirradiated controls, there was a small increase in the ratio of type III to total collagen after 8 weeks of UV. There were no significant increases at later time points until after 24 weeks of radiation. Total collagen in normal mouse skin, determined by hydroxyproline content, remained constant over the 24 weeks, while UV radiation produced significant increases at 4, 8, 12, and 16 weeks, returning to control levels at week 20. There was no change in the degree of hydroxylation at any time point in either group. Thus, chronic UV exposure resulted in increased collagen synthesis until late in the course of irradiation. Because there is a lack of consistent change in the ratio of type III to total collagen, the early increases in collagen content may represent both types I and III, synthesized in relatively unchanging proportions.     

Epidermal changes caused by chronic low-dose UV irradiation induce wrinkle formation in hairless mouse

To investigate the effects of chronic low-dose UV irradiation on the skin, hairless mice were irradiated with a 1/3 minimal erythemal dose (MED) of UV. We examined the relationship between visible changes and skin damage in the dermis and epidermis. Hairless mice were irradiated with UVB (20 mJ/cm2) and UVA (14 J/cm2) three times a week for 10 weeks, followed by a 24-week non-irradiation period. Visible fine wrinkling was present after 4 weeks of irradiation, and the wrinkling progressively worsened throughout the period of irradiation. The wrinkles remained after irradiation was discontinued. In dermal components, no significant histological changes in the collagen fibers and elastic fibers were found, and the amount of hydroxyproline was also not changed. Thus, in the epidermis, there was a significant increase in the number of stratum corneum layers and the terminal-differentiation marker, filaggrin, positive cells. The intensity of staining for the differentiation marker, keratin 1, was reduced. These changes were accompanied by wrinkle formation, and remained after discontinuance of irradiation. These findings suggested that chronic low-dose UV irradiation induces structural and quantitative changes in the epidermis as a result of keratinization impairment, and that this damage in the epidermis is an important causative factor in wrinkle formation.     

UV-induced DNA damage initiates release of MMP-1 in human skin

Destruction of collagen is a hallmark of photoaging. The major enzyme responsible for collagen 1 digestion, matrix metalloproteinase-1 (MMP-1), is induced by exposure to sunlight. To study the molecular trigger for this induction, human skin was ultraviolet-B (UVB)-irradiated and treated with liposome-encapsulated DNA repair enzymes. The photolyase-mediated DNA repair of epidermal UV damage was associated with a reduction of MMP-1 mRNA and protein expression in both the epidermal and dermal compartments of the skin. The role of the epidermal cells in MMP-1 induction in the fibroblasts was examined when human epidermal keratinocytes were irradiated with UVB and their media were transferred to unirradiated human dermal fibroblasts. Transfer of media from irradiated keratinocytes to unirradiated fibroblasts enhanced MMP-1 mRNA and protein. Thus, UV damage to keratinocytes of the epidermis may participate in the destruction of collagen in the dermis by release of soluble mediators that signal fibroblasts to release MMP-1. The MMP-1 induction was reduced when the keratinocytes were treated with DNA repair enzymes T4 endonuclease V or UV endonuclease prior to transfer of the media to fibroblasts. This implies that UVB, which deposits most of its energy on the chromatin of the epidermal keratinocytes and to a lesser extent in the upper dermis, has a significant role in photoaging. DNA damage in the keratinocytes initiates one of the signals for MMP-1 release, and enhancing DNA repair can reduce MMP-1 expression in human skin cells and tissue.     

The role of Syk kinase in ultraviolet-mediated skin damage

Background Ultraviolet (UV) irradiation is the main cause of skin photodamage; the resulting modulation of matrix metalloproteinases (MMPs) leads to collagen degradation. There is no easily accessible molecular indicator of early skin UV damage. Objectives In this study, we investigated the effects of Syk kinase on MMP expression and evaluated the sensitivity and usefulness of Syk as an early indicator of skin UV damage. Methods Human dermal fibroblasts (HDFs) were transfected with Syk cDNA to overexpress Syk. MMP‐1 expression and Syk activity were determined by Western blot after UV exposure. The effect of Syk on MMP‐1 expression in HDFs was further explored by either Syk siRNA or a selective Syk inhibitor. Possible downstream molecules of Syk were also evaluated in HDFs upon UV exposure. The relationship between Syk and collagenase was further explored in vivo (MMP‐13, hairless mice). Results Our studies in HDFs demonstrated that both a Syk inhibitor and Syk siRNA were able to inhibit MMP‐1 expression in HDFs exposed to UV and that overexpression of Syk increased MMP‐1 expression and the activity of JNK kinase, but not p38 or Erk1/2 MAP kinase. UV exposure enhanced both expression and activity of Syk in HDFs. Experiments with hairless mice suggested that Syk expression is an earlier indicator of UV exposure than MMP‐13 expression. Conclusions Our results demonstrate that Syk expression correlates well with increase of MMPs (MMP‐1 in humans and MMP‐13 in mice) in response to UV exposure. The findings suggest that Syk may be a novel target for the prevention and treatment of skin photodamage by modulating MMPs.     

Fermentable metabolite of <Emphasis Type="Italic">Zymomonas mobilis</Emphasis> controls collagen reduction in photoaging skin by improving TGF-β/Smad signaling suppression

Solar ultraviolet (UV) irradiation causes damages on human skin and premature skin aging (photoaging). UV-induced reduction of type I collagen in dermis is widely considered primarily induction of wrinkled appearance of photoaging skin. Type I procollagen synthesis is reduced under UV irradiation by blocking transforming growth factor-β (TGF-β)/Smad signaling; more specifically, it is down-regulation of TGF-β type II receptor (TβRII). Therefore, preventing UV-induced loss of TβRII results decreased type I collagen reduction in photoaging skin. Zymomonas mobilis is an alcohol fermentable, gram-negative facultative anaerobic bacterium whose effect on skin tissue is scarcely studied. We investigated the protective effects of fermentable metabolite of Z. mobilis (FM of Z. mobilis) against reduction of type I procollagen synthesis of UV-induced down-regulation of TβRII in human dermal fibroblasts FM of Z. mobilis was obtained from lyophilization of bacterium culture supernatant. The levels of TβRII and type I procollagen mRNA in human dermal fibroblasts were measured by quantitative real-time RT-PCR, and TβRII protein levels were assayed by western blotting. TβRII, type I procollagen, and type I collagen proteins in human dermal fibroblasts or hairless mouse skin were detected by immunostaining. FM of Z. mobilis inhibited down regulation of TβRII mRNA, and protein levels in UVB irradiated human dermal fibroblasts consequently recover reduced type I procollagen synthesis. These results indicate UVB irradiation inhibits type I procollagen synthesis by suppression of TGF-β/Smad signaling pathway, and FM of Z. mobilis has inhibitory effect on UVB-induced reduction of type I procollagen synthesis. While short period UVB irradiation decreased both TβRII and type I procollagen protein levels in hairless mouse skin, topical application of FM of Z. mobilis prevented this decrease. Wrinkle formation in hairless mouse skin surface was accelerated by continuous 5 month UVB irradiation along with a reduction of type I collagen in the dermis, but this change was prevented by topical application of FM of Z. mobilis. From this experimental data, it is suggested that FM of Z. mobilis is effective for suppression of wrinkle formation in photoaging skin by inhibition of type I procollagen synthesis reduction.     

Red grape (Vitis vinifera L.) flavonoids down‐regulate collagen type III expression after UV‐A in primary human dermal blood endothelial cells

Red grape (Vitis vinifera L.) flavonoids including flavan‐3‐ols (eg, catechin and epicatechin), flavonols (eg, quercetin) and anthocyanins (eg, malvidin) exert anti‐inflammatory and antioxidant activities. In the skin they also have a photoprotective action, and their effects have been extensively investigated in keratinocytes, melanocytes and fibroblasts. Despite their known effects also on blood vasculature, little is known on their activities on human dermal blood endothelial cells (HDBECs), which are critically involved in skin homeostasis as well as in the pathogenesis of neoplastic and inflammatory skin diseases. We sought to study the biological effects of selected red grape flavonoids in preventing the consequences of ultraviolet (UV)‐A irradiation in vitro. Our results show that red grape flavonoids prevent UV‐A‐induced sICAM‐1 release in HDBECs, suggesting that this cell type could represent an additional target of the anti‐inflammatory activity of flavonoids. In addition, flavonoids effectively inhibited UV‐A‐induced synthesis of collagen type III at both RNA and protein level, indicating that dermal blood microvasculature could be actively involved in ECM remodelling as a consequence of skin photo‐ageing, and that this can be prevented by red grape flavonoids.     

Effects of all-trans retinoic acid on UVB-irradiated and non-irradiated hairless mouse skin.

The effects of all-trans retinoic acid (t-RA) on photodamaged and normal non-irradiated skin were examined in hairless mice (Skh:HR-1). After being exposed to increasing doses of UVB for 10 weeks (total dose = 1.4 J/cm2), the animals were then treated with 0.1% t-RA in ethanol (50 microliters, five times per week) for another 10 weeks. Several animals (the follow-up group) were further observed after the termination of the t-RA treatment to investigate if the t-RA effect was reversible. Wrinkle effacement induced by t-RA was compared with three other parameters: a) de novo collagen synthesis, b) width of the dermal repair zone, and c) epidermal thickening. Interestingly, t-RA did not stimulate collagen synthesis in animals not exposed to UVB. In the irradiated animals, the time course of wrinkle reduction correlated with the stimulation of collagen synthesis. After a synchronous initial lag phase of 4-6 weeks, the wrinkling decreased from the maximum grade of 4 to a mean grade of 1.3, whereas collagen synthesis was enhanced to 245% of the control at week 10 of t-RA treatment. In contrast, a similar lag phase was not observed for either the appearance of the dermal repair zone or epidermal thickening. In the follow-up group, upon termination of t-RA treatment, collagen synthesis returned to the control level. Wrinkle effacement and thickening of the dermal repair zone, however, did not regress, suggesting the anti-photoaging effect of t-RA was not reversible over this time frame. The correlation between the length of the lag phases for collagen synthesis and wrinkle reduction points to the possibility that collagen plays an important role in tRA-induced wrinkle effacement. Both parameters are thus important endpoints for investigating the mechanism of RA-induced repair of photodamaged skin.     

Cathepsin G Inhibitor Prevents Ultraviolet B- Induced Photoaging in Hairless Mice via Inhibition of Fibronectin Fragmentation

Background: Cathepsin G, a serine protease that is activated by ultraviolet (UV) radiation, increases matrix metalloproteinase-1 (MMP-1) expression in fibroblasts through fibronectin (Fn) fragmentation and promotes the conversion of proMMP-1 to active MMP-1. Objectives: This study investigated whether [2-[3-[[(1-benzoyl-4-piperidinyl)methylamino]carbonyl]-2-naphthalenyl]-1-(1-naphthalenyl)-2-oxoethyl]-phosphonic acid (KPA), a cathepsin G inhibitor, plays any role in extracellular matrix (ECM) damage in an in vitro 3D dermal equivalent (DE) and an in vivo ultraviolet B (UVB)-irradiated hairless mice. Methods: We examined the potential ECM-protective effects of a cathepsin G inhibitor in an in vitro 3D DE model and an in vivo UVB-irradiated hairless mouse skin model. Results: Among five known serine protease inhibitors, KPA showed the strongest potency and selectivity against cathepsin G. KPA inhibited the cathepsin G-mediated MMP-1 increase and alleviated the downregulation of mRNAs encoding collagen and tissue inhibitor of matrix metalloproteinase-1 in an in vitro 3D DE model. Most importantly, topical application of KPA (0.025%) to the dorsal skin of hairless mice enhanced collagen expression and attenuated UVB-induced Fn fragmentation and upregulation of MMP-2 and MMP-9 activities. Conclusions: Cathepsin G inhibitors may be useful for the prevention of UVB-induced photoaging through amelioration of ECM damage and MMP upregulation.     

Topical application of plant extracts containing xanthine derivatives can prevent UV-induced wrinkle formation in hairless mice

BACKGROUND: Plants are the source of important products with nutritional and therapeutic value. Topical or oral administration of some plant extracts has been shown to reduce photodamage. Cacao bean and cola nut are popular edible plants that contain polyphenols and xanthine derivatives. These plant extracts possess protective effects against UV-induced erythema when taken orally, and an H(2)O(2)-scavenging effect. METHODS: Plant extracts containing xanthine derivatives and three xanthine derivatives were topically applied to the dorsal skin of hairless mice, and the mice were exposed to a resemblance of solar ultraviolet irradiation at a dose of 13.0 J/cm(2) (UVA) for 15 weeks, five times a week on weekdays. After the final irradiation, histological, and analytical studies were performed. RESULTS: Topical application of plant extracts (cacao beans, cola nuts) and caffeine, theobromine, and theophylline markedly prevented photodamage including wrinkle formation and histological alterations. A significant increase in total hydroxyproline content caused by UV irradiation was observed. In contrast, topical application of plant extracts and xanthine derivatives reduced total hydroxyproline and pepsin-resistant hydroxyproline content in comparison with that of the control (vehicle, UV-irradiation group). Moreover, naphthol AS-D chloroacetate esterase staining and diaminobenzidine staining suggested that leukocytes including neutrophils increased in the UV-exposed skin. In contrast, weak staining was observed in skin treated with xanthine derivatives. CONCLUSION: Topical application of plant extracts and xanthine derivatives suppressed wrinkle formation, dermal connective alteration, and collagen accumulation. It is suggested that xanthine derivatives prevented neutrophil infiltration caused by UV-irradiation.     

Characteristics of skin wrinkling and dermal changes induced by repeated application of squalene monohydroperoxide to hairless mouse skin

We have studied the effect of squalene monohydroperoxides (Sq-OOH), initial products of UV-peroxidated squalene, on the skin of hairless mice. Repeated topical application of 10 mM Sq-OOH to hairless mice for 15 weeks induced definite skin wrinkling. When image analysis was used to compare wrinkle formation induced by ultraviolet B (UVB) irradiation and Sq-OOH treatment, the degree of wrinkling in exposed skin was seen to be similar. However, the characteristics of wrinkles induced by either method differed markedly with regard to direction and distribution. Biochemical analysis revealed a significant decrease in collagen content per unit area and mass in Sq-OOH-treated skin, whereas no changes per unit area and decrease in collagen per unit mass were observed in UVB-irradiated skin. As for glycosaminoglycan (GAG) content per unit area, significant increases were observed in both Sq-OOH-treated skin and UVB-irradiated skin. These changes were not induced by organic hydroperoxides such as TERT-butylhydroperoxide or cumene hydroperoxide treatment. Histological observation revealed epidermal hyperplasia and dermal alterations such as collagen degradation and GAG increases in Sq-OOH-treated skin. Histological changes induced by Sq-OOH were not as pronounced as those induced by UVB irradiation. These results clearly suggest that the wrinkling and changes in dermal collagen content induced by Sq-OOH are qualitatively different to those induced by UVB exposure. This may provide a useful model for the study of skin aging, particularly with regard to collagen content.     

Connective tissue alterations in the skin of ultraviolet irradiated hairless mice

Connective tissue alterations were induced in hairless mouse skin by ultraviolet (UV) irradiation. Hairless mice were irradiated three times a week for 10 weeks with sunlamps (UVA and UVB) and the skin was examined using immunochemical and biochemical techniques. Indirect immunofluorescence was performed with antibodies directed against elastin, microfibrillar proteins, and fibronectin. Increased fluorescence was observed in the actinically damaged skin for elastin, microfibrillar proteins, and fibronectin. The elastic fiber components, elastin and microfibrillar proteins, were then isolated and quantified. Control skin contained approximately 0.1% by dry weight of elastic fiber components, whereas actinically damaged skin contained 0.2% by dry weight. These data are consistent with previous observations of elastic fiber hyperplasia in UV irradiated mice. In addition, irradiated mouse skin contained 1.12 mg of extracted fibronectin per gram wet weight as compared with 0.59 mg in control skin. Irradiated mouse skin contained increased quantities of hyaluronic acid and chondroitin sulfate (uronic acid content). These studies further support the validity of the UV irradiated hairless mouse as a model of human dermal photoaging.     

Dihydroavenanthramide D prevents UV‐irradiated generation of reactive oxygen species and expression of matrix metalloproteinase‐1 and ‐3 in human dermal fibroblasts

Ultraviolet B (UVB) radiation induces photoageing by upregulating the expression of matrix metalloproteinases (MMPs) in human skin cells. Dihydroavenanthramide D (DHAvD) is a synthetic analog to naturally occurring avenanthramide, which is the active component in oats. Although anti‐inflammatory, anti‐atherosclerotic and antioxidant effects have been reported, the antiphotoageing effects of DHAvD are yet to be understood. In this study, we investigated the inhibitory effects of DHAvD on UVB‐induced production of reactive oxygen species (ROS) and expression of MMPs, and its molecular mechanism in UVB‐irradiated human dermal fibroblasts. Western blot and real‐time PCR analyses revealed that DHAvD inhibited UVB‐induced MMP‐1 and MMP‐3 expression. It also significantly blocked UVB‐induced ROS generation in fibroblasts. Additionally, DHAvD attenuated UVB‐induced phosphorylation of MAPKs, activation of NF‐κB and AP‐1. DHAvD regulates UVB‐irradiated MMP expression by inhibiting ROS‐mediated MAPK/NF‐κB and AP‐1 activation. DHAvD may be a useful candidate for preventing UV light‐induced skin photoageing.     

Ultraviolet A irradiation stimulates collagenase production in cultured human fibroblasts.

This study was designed to investigate the biochemical mechanisms responsible for the connective tissue changes seen in actinically damaged skin, which is characterized histologically by diminution and ultrastructural alterations of collagen fibrils and deposition of elastotic material in the papillary dermis. We hypothesized that ultraviolet light could stimulate synthesis of interstitial collagenase in the skin, resulting in collagen degradation. Monolayer cultures of human fibroblasts or keratinocytes were irradiated with ultraviolet A (UVA) or ultraviolet B (UVB) radiation and interstitial collagenase or its inhibitor, TIMP (tissue inhibitor of metalloproteinases) assessed in the conditioned medium with Western immunoblots 24 h after irradiation. Northern blot analysis of the irradiated fibroblasts with a cDNA probe representing collagenase was also performed. Cell viability was greater than 90% with all doses of UV radiation studied. A dose-related increase in immunoreactive collagenase was detected in the medium of fibroblasts irradiated with 0-10 J/cm2 of UVA radiation as well as a parallel increase in the collagenase mRNA in the irradiated cells. UVA radiation stimulated collagenase synthesis in both neonatal and adult fibroblasts. TIMP production in UVA-irradiated fibroblasts increased to a lesser degree than did collagenase and its increase did not parallel the increase in collagenase. UVB (0-100 mJ/cm2) did not stimulate collagenase production by fibroblasts. In contrast to the stimulation of collagenase production by fibroblasts, a slight decrease in immunoreactive collagenase was seen in UVA-irradiated keratinocytes. These data suggest that direct stimulation of collagenase synthesis by human skin fibroblasts by UVA radiation may contribute to the connective tissue damage induced by ultraviolet radiation leading to photoaging.     

Anti-inflammatory effects of CoQ10 and colorless carotenoids

Background CoQ10 (ubiquinone, coenzyme Q10) and carotenoids are popular antioxidants used in many skin care products to protect the skin from free radical damage. Aim To evaluate the effects of CoQ10 and colorless carotenoids on the production of inflammatory mediators in human dermal fibroblasts treated with UV radiation (UVR) and to investigate the possible synergistic effects of these two antioxidants. Methods Normal human dermal fibroblast cell cultures were exposed to either 50 mJ of UVR or to IL‐1 and then incubated with various concentrations of either CoQ10, the colorless carotenoids, phytoene and phytofluene, or to combinations of these antioxidants. After 24 h in culture, cells and spent medium were harvested and assayed by enzyme‐linked immunosorbent assay for prostaglandin E2 (PGE‐2), interleukin 6 (IL‐6), and matrix metalloproteinase 1 (MMP‐1). In addition, the ability of the carotenoids to protect CoQ10 from oxidation by the reactive oxygen species (ROS), hyperchlorite, was also determined. Results Human fibroblasts respond to UVR or to IL‐1 by increasing the production of various inflammatory mediators including PGE‐2, IL‐1, and IL‐6 and proteases such as collagenase (MMP‐1). Treatment of fibroblasts with 10 µm of CoQ10 suppressed the UVR‐ or IL‐1–induced increase in PGE‐2, IL‐6, and MMP‐1. The combination of carotenoids and CoQ10 produced an enhanced inhibition of these three inflammatory mediators. Furthermore, the colorless carotenoids, phytoene and phytofluene, protected CoQ10 from degradation by the ROS, hypochlorite. Conclusion CoQ10 is able to suppress the UVR‐ or IL‐1–induced inflammatory response in dermal fibroblasts. Furthermore, this compound can block the UVR induction of the matrix‐eroding enzyme, MMP‐1. Finally, the combination of carotenoids plus CoQ10 results in enhanced suppression of inflammation. The results suggest that the combination of carotenoids and CoQ10 in topical skin care products may provide enhanced protection from inflammation and premature aging caused by sun exposure.     

Ultraviolet B radiation and reactive oxygen species modulate interleukin-31 expression in T lymphocytes, monocytes and dendritic cells

Background Interleukin (IL)‐31 is a novel Th2 T‐cell cytokine that induces pruritus and dermatitis in transgenic mice. While enhanced mRNA expression of this cytokine is detected in skin samples of inflammatory skin diseases, the regulation of IL‐31 expression is poorly understood. Objectives To assess the effects of ultraviolet (UV) B radiation and H₂O₂ on IL‐31 mRNA and protein expression in skin and different peripheral blood mononuclear cells (PBMCs). Methods The effects of UVB radiation and H₂O₂, as a prototypic reactive oxygen species, on IL‐31 mRNA and protein expression were analysed in various inflammation‐related cells and murine skin tissue. Results Treatment of cells with UVB radiation and H₂O₂ strongly induced IL‐31 mRNA and protein expression in human PBMCs and in the skin of SKH‐1 mice. Following exposure to UVB or H₂O₂, we observed increased expression of IL‐31 mRNA in T cells, monocytes, macrophages, and immature and especially mature dendritic cells. H₂O₂ treatment but not UVB radiation led to a moderate upregulation of IL‐31 mRNA expression in epidermal keratinocytes and dermal fibroblasts. Pretreatment of T lymphocytes with the MAPK p38 inhibitor SB203580 or the MEK1 inhibitor U0126 reduced the stimulatory effect of H₂O₂. These experiments suggest that p38 is involved in the regulation of IL‐31 expression in human skin. Conclusions Our studies reveal that UVB and reactive oxygen species stimulate the expression of IL‐31 in PBMCs and skin, especially in T cells, monocytes and monocyte‐derived dendritic cells.     

Glucocorticoid effects on contact hypersensitivity and on the cutaneous response to ultraviolet light in the mouse

A single exposure to 254 nm ultraviolet irradiation (UV) can systemically suppress experimental sensitization to the simple allergen 2,4-dinitro, 1-chlorobenzene (DNCB) in the mouse. We show here that topical application at the site of irradiation of the 21-oic acid methyl ester derivative of the synthetic glucocorticoid triamcinolone acetonide (TAme) prevents UV suppression of sensitization. That is, mice painted with TAme at the site of UV exposure developed normal contact hypersensitivity (CH); mice exposed to UV only, like mice treated with the parent compound triamcinolone acetonide (TA), failed to be sensitized by DNCB applied to a distal site. TAme is inactivated rapidly by plasma esterases, so its effect is thought to be confined to the skin. Apparently, TAme blocked the cutaneous signal(s) for systemic suppression of CH. Histologically, irradiated skin exhibited mild inflammation and hyperproliferation, but these effects were greatly exaggerated and prolonged in the UV + TAme-treated skin, independent of sensitization at the distal site. The infiltrate consisted mostly of neutrophils and lacked the round cells characteristic of cell-mediated immunity. Apparently, normal immune suppression by UV prevented this vigorous reaction to irradiated skin. Applied together with DNCB. TAme blocked sensitization. It also prevented response to challenge by DNCB in previously sensitized animals. However, unlike the parent compound triamcinolone acetonide (TA), Budesonide or Beclomethasone diproprionate, each of which can penetrate the epidermis in active form, TAme had no effect on sensitization when applied at a distal site. Likewise, TAme did not affect plasma B (17-desoxycortisol) levels, whereas the other three compounds reduced plasma B tenfold, as expected of compounds causing adrenal-pituitary suppression. The results as a whole show that glucocorticoids can specifically inhibit cutaneous steps in induction of cell-mediated immunity or its suppression, and can, at the site of challenge, prevent its expression in CH.