Exploring compounds to be used as cosmetic agents that activate peroxisome proliferator-activated receptor alpha.

OBJECTIVE: The human epidermis is formed by the proliferation and differentiation of keratinocytes adjacent to the basement membrane. The outermost layer, the stratum corneum, is equipped with a barrier function that prevents water evaporation, and intercellular lipids play an important role in this barrier function. When the barrier is functioning normally, evaporation is prevented; however, when barrier function is impaired, moisture evaporates, resulting in dry and rough skin. Therefore, maintenance of normal barrier function is critical for maintaining normal skin function. Peroxisome proliferator-activated receptor α (PPARα) is mainly not only involved in lipid metabolism in the liver but is also expressed in the epidermis and is involved in inducing keratinocyte differentiation, promoting lipid production, maintaining barrier function and suppressing skin inflammation. Hence, compounds that activate PPARα are expected to control skin function. Therefore, we identified PPARα activators from among extracts of natural resources that have been approved for use in humans and analysed the effects of these extracts on skin function. METHODS: First, extracts of 474 natural resources were screened using a PPARα activator screening cell line independently constructed in our laboratory. Next, reporter assays were performed using the Gal4-chimera system to evaluate whether these extracts act as ligands for PPARα. We then analysed their effect on primary normal human epidermal keratinocyte cells by using real-time RT-PCR. Finally, we evaluated PPARα activation effect by the combination of these extracts. RESULTS: We identified 36 extracts having the effect of activating PPARα. In particular, #419, a Typha angustifolia spike extract, showed concentration-dependent transcriptional activation through PPARα-LBD and was considered to be likely to contain a compound that is a ligand of PPARα. #419 increased the expression of PPARα target genes and genes related to skin function in primary cultured human epidermal keratinocytes. Finally, the use of #419 in combination with nine extracts increased PPAR activity more than twice as much as #419 alone treatment. CONCLUSIONS: These results showed that the reporter cell line could be useful for discovering extracts of natural resources and that the identified Typha angustifolia spike extract could be used in cosmetics that activate PPARα, which expected to improve skin function.

OBJECTIF: L'épiderme humain se forme grâce à la prolifération et à la différenciation des kératinocytes adjacents à la membrane basale. La couche externe, dite « couche cornée ¼, possède une fonction barrière qui empêche l'évaporation de l'eau, dans laquelle les lipides intercellulaires jouent un rôle important. Lorsque la barrière fonctionne normalement, l'évaporation est évitée ; mais lorsqu'elle est altérée, l'évaporation a lieu et la peau, privée d'hydratation, devient sèche et rêche. Par conséquent, il est capital de maintenir cette fonction barrière normale pour que la peau conserve son fonctionnement normal. Le récepteur alpha activé par proliférateurs de peroxysomes (PPARα) intervient surtout non seulement dans le métabolisme lipidique du foie, mais également dans l'épiderme ; il joue en effet un rôle dans l'induction de la différenciation des kératinocytes, la promotion de la production lipidique, le maintien de la fonction barrière et la suppression de l'inflammation de l'épiderme. Par conséquent, les activateurs du PPAR-α devraient être déterminants pour une bonne fonction cutanée. Nous avons donc identifié des activateurs du PPAR-α parmi des extraits de ressources naturelles dont l'utilisation chez l'homme est approuvée, et nous avons analysé les effets de ces extraits sur la fonction cutanée. MÉTHODES: Tout d'abord, des extraits de 474 ressources naturelles ont été sélectionnés à l'aide d'une lignée cellulaire de détection des activateurs du PPAR-α, construite indépendamment dans notre laboratoire. Ensuite, des tests de gènes rapporteurs ont été effectués à l'aide du système Gal4-chimera pour voir si ces extraits jouaient le rôle de ligands pour le PPAR-α. Nous avons ensuite analysé leur effet sur les cellules kératinocytaires épidermiques humaines normales primaires par RT-PCR en temps réel. Enfin, nous avons évalué l'effet d'activation du PPAR-α par l'association de ces extraits. RÉSULTATS: Nous avons identifié 36 extraits ayant pour effet d'activer le PPAR-α. En particulier, le n° 419, un extrait d'épi de Typha angustifolia, a montré une activation transcriptionnelle dépendante de la concentration par le PPAR-α-LBD et a été considéré comme susceptible de contenir un composé qui est un ligand du PPAR-α. Le n° 419 a augmenté l'expression des gènes cibles du PPAR-α et des gènes liés au fonctionnement de la peau dans les kératinocytes épidermiques humains primaires mis en culture. Enfin, l'utilisation du n° 419 en association avec neuf extraits a augmenté de plus du double l'activité du PPAR par rapport au traitement par le n° 419 seul. CONCLUSIONS: Ces résultats ont montré que la lignée cellulaire rapporteuse pourrait être utile pour découvrir des extraits de ressources naturelles et que l'extrait d'épi de Typha angustifolia identifié pourrait être utilisé dans des cosmétiques qui activent le PPAR-α, ce qui devrait améliorer la fonction cutanée.

Structural analysis of adventitial collagen to feature aging and aneurysm formation in human aorta.

OBJECTIVE: Adventitial collagen structure provides the aorta with tensile strength. Like other collagen-rich tissues, it can be affected by internal factors including aging and location. We determined whether the structural characteristics of human aortic adventitial collagen change with aging, location, and aneurysm formation. METHODS: Nonatherosclerotic nonaneurysmal (NANA) human abdominal aortas were collected from 15 individuals who had died of noncardiovascular diseases (<40 years old, NANA young, n = 5; >60 years old, NANA old, n = 5). The architecture of adventitial collagen in the aortas was assessed by scanning electron microscopy, and fiber orientation was assessed by polarized microscopy with two-dimensional fast Fourier transform. We then analyzed retardation as an anisotropic property of adventitial collagen by polarized light microscopy. The orientation and retardation of NANA aortas were compared with those of abdominal aortic specimens from patients who were surgically treated for abdominal aortic aneurysm (AAA) (>60 years old, n = 11). RESULTS: Adventitial collagen of the abdominal aortas on scanning electron microscopy images appeared as wavy, ropy fibers in aortas from young individuals (NANA young, n = 5) and were essentially flattened in those from older patents (NANA old, n = 5) and from those with AAA. Collagen fibers were thicker but sparser in the adventitia of aortas with AAA. Orientation maintained in the collagen fibers of NANA aortas (n = 15) on two-dimensional fast Fourier transform analysis was unrelated to either location or age and did not differ between NANA aortas and those with AAA. However, collagen fibrils in NANA aortas (n = 15) were significantly less retarded only at the level of the inferior mesenteric artery compared with other aortic locations. In addition, retardation was significantly reduced in abdominal aortas with AAA at the level of the inferior mesenteric artery. CONCLUSIONS: The basic structure of adventitial collagen fiber was maintained in abdominal aortas regardless of location or age. Because the molecular structure at the subfibril level changed at abdominal aorta and enhanced in aortas with AAA, alterations in the molecular structure of adventitial collagen might be associated with aneurysmal formation.

Knockdown of electron transfer flavoprotein ß subunit reduced TGF-ß-induced α-SMA mRNA expression but not COL1A1 in fibroblast-populated three-dimensional collagen gel cultures.

BACKGROUND: The inhibition of transforming growth factor ß (TGF-ß)-induced myofibroblast differentiation is a key objective for the treatment of hypertrophic scarring. We previously reported that knockdown of the electron transfer flavoprotein ß subunit (ETFB) reduced mechanoregulated cell number in fibroblast-populated collagen gel cultures [1]. OBJECTIVE: To characterize the effects of ETFB knockdown, we investigated gel contraction, TGF-ß-induced collagen, α-SMA mRNA expression and stress fiber formation. METHODS: Fibroblasts were transfected with negative control or ETFB-specific siRNAs and embedded in collagen gels in an attached or detached condition. The gel contraction assay was performed in three different concentrations of collagen (0.5, 1.0 or 1.5mg/mL) and was analyzed by measuring the changes in the gel area throughout the culture period. The attached collagen gel culture was performed in the presence of rTGF-ß and the mRNA levels of α-SMA and COL1A1 were measured by qRT-PCR. The effect of ETFB knockdown on proliferation and stress fiber organization in monolayer cultures was investigated by conducting AlamarBlue assays and phalloidin staining. RESULTS: The transfection of ETFB siRNA did not alter gel contraction compared to the negative control in all collagen concentrations. When the cells were treated with TGF-ß under mechanical stress conditions, ETFB knockdown attenuated α-SMA mRNA expression to a level comparable to that observed in the absence of TGF-ß. However, no inhibitory effect on COL1A1 mRNA levels was observed. The AlamarBlue assay indicated that the knockdown had no effect on the proliferation of cells cultured on plastic. Phalloidin staining of a monolayer culture showed that ETFB knockdown weakened the stress fiber organization induced by rTGF-ß. CONCLUSION: ETFB knockdown can affect TGF-ß-induced tissue remodeling and/or fibrotic processes in vitro.

Identification of ETFB as a candidate protein that participates in the mechanoregulation of fibroblast cell number in collagen gel culture.

BACKGROUND: Fibroblast activation is strongly influenced by mechanical environment in the wound-healing process, especially in fibrosis. Mechanically stressed three-dimensional collagen embedded culture is a useful model representing fibroblasts in morphological as well as biochemical situations encountered during fibrosis. OBJECTIVE: To find key proteins involved in reducing the number of fibroblasts during mechanical stress, we performed two-dimensional gel electrophoresis (2DE)-based differential display and siRNA-based functional screening with collagen gel culture focusing on the differences between attached and detached culture environments. METHODS: Membrane extracts of fibroblasts from 1 day of attached or detached cultures were subjected to 2DE. We compared protein expression levels and identified the attached-culture-dominant proteins by MALDI-TOF-MS. Next, fibroblasts were transfected with siRNA and embedded in collagen gel. Cell number was counted after 3 days in culture. RESULTS: Eight attached culture dominant proteins were identified with MALDI-TOF-MS. Transfection of siRNA against these proteins demonstrated that electron transfer flavoprotein ß subunit (ETFB)-specific siRNA reduced the cell number in the attached culture without a decrease in the detached culture. CONCLUSION: ETFB participates in the mechanoregulation of fibroblast cell number in collagen gel culture.