Decreased mitochondrial function in UVA-irradiated dermal fibroblasts causes the insufficient formation of type I collagen and fibrillin-1 fibers.

BACKGROUND: Decreases of collagen fibers and the disappearance of oxytalan fibers are typical symptoms of photoaged skin. Although a low quality of mitochondria (MT) in photoaged skin cells has been observed, it is unknown whether the decreased quality of MT is responsible for the insufficient formation of dermal fibers. OBJECTIVE: To identify the role of mitochondrial quality in skin photoaging focusing on the formation of dermal fibers. METHODS: Type I collagen and fibrillin-1 fibers in normal human dermal fibroblasts (NHDFs) were observed by immunostaining. Type I collagen and fibrillin-1 proteins in NHDFs were quantified by ELISA. Mitochondrial quality was evaluated by measuring levels of intracellular ATP and MITOL, which regulate mitochondrial quality. RESULTS: UVA-irradiated NHDFs formed insufficient type I collagen and fibrillin-1 fibers and had a decreased ratio of extracellular versus intracellular levels of those proteins. Although expression levels of motor proteins that transport those proteins intracellularly were not affected by UVA, intracellular ATP levels, which is the driving force of motor proteins, were decreased by UVA along with decreased MITOL protein. Knockdown of MITOL in NHDFs decreased the level of intracellular ATP and caused the insufficient formation of type I collagen and fibrillin-1 fibers due to interfering with the secretion of those proteins. CONCLUSION: These results indicate that a low quality of MT with ATP depletion in dermal fibroblasts caused by irradiation with UVA induces the insufficient formation of type I collagen and fibrillin-1 fibers due to the decreased extracellular secretion of those proteins.

Xanthophyll Carotenoids Reduce the Dysfunction of Dermal Fibroblasts to Reconstruct the Dermal Matrix Damaged by Carbonylated Proteins.

Although extracellular carbonylated proteins (CPs) are found at higher levels in sun-exposed skin, their impact on the cellular functions of fibroblasts and their involvement in the progression of photoaging skin are not fully clarified. In our previous study, we reported that extracellular CPs increase levels of intracellular oxidative stress and result in the accumulation of newly synthesized CPs in normal human dermal fibroblasts (NHDF). Furthermore, fibroblasts exposed to CP-BSA, which is a model of extracellular CPs, had upregulated expression levels of mRNAs encoding matrix metalloproteinase-1 (MMP-1) and interleukin-8/CXCL8 (IL-8/CXCL8). These facts suggested the possibility that extracellular CPs induce a fragile structure in the dermis through the degradation of collagen and elastin. The purpose of this study was to characterize the efficacy of natural carotenoids, such as astaxanthin analogs, produced by Hematococus pluvialis (CHPs) to improve the impaired functions of fibroblasts exposed to CPs. CHPs suppressed the intracellular CP levels elevated by CP-BSA, restored mRNA expression levels of factors involved in the formation and assembly of collagen and elastin fibers and improved the formation of those fibers impaired by CP-BSA. We conclude that CHPs function as antiaging substances due to their restoration of the impaired formation of collagen and elastin fibers caused by extracellular soluble CPs.

Pyridoxine (VB6 ) restores the down-regulation of serine palmitoyltransferase mRNA expression in keratinocytes cultured in highly oxidative conditions through enhancement of the intracellular antioxidant system.

BACKGROUND: Pyridoxine (VB6 ), which acts as a coenzyme in the biosynthesis of niacin, is formulated in pharmaceuticals to treat skin roughness. However, the mechanism of action of VB6 is not known precisely. OBJECTIVE: This study was conducted to clarify the influence of highly oxidative conditions on the expression of skin moisture-related mRNAs and to evaluate the preventive effects of VB6 focusing on antioxidant behaviour. METHODS: Intracellular levels of reactive oxygen species (ROS) in normal human epidermal keratinocytes (NHEKs) were determined using the 2',7'-dichlorofluorescein diacetate assay. Real-time PCR was employed to investigate the influence of higher oxidative conditions on the expression of mRNAs encoding serine palmitoyl transferase (SPT) and filaggrin, and to characterize the mechanism of the antioxidant effect of VB6 . Intracellular glutathione was quantified using an assay based on the glutathione recycling system with 5,5'-dithiobis (2-nitrobenzoic acid) reagent and glutathione reductase. Carbonylated proteins (CPs) were semi-quantified by detecting aldehyde residues. RESULTS: Treatment of NHEKs with BSO increased the level of intracellular CPs by interfering with intracellular glutathione synthesis. Further, treatment with BSO down-regulated the expression level of SPT mRNA, but VB6 restored SPT mRNA expression in BSO-treated NHEKs. VB6 decreased the level of intracellular CPs with or without BSO treatment in a dose-dependent manner. In addition, VB6 increased levels of intracellular NADH/NADPH and glutathione through the activation of nuclear factor E2-related factor 2 (Nrf2) signalling. CONCLUSION: These results suggest that highly oxidative conditions cause an impaired skin barrier function due to the down-regulation of SPT that results in skin roughness. VB6 improved the down-regulation of SPT mRNA expression initiated by highly oxidative conditions by enhancing the intracellular antioxidant system.

The impact of carbonylated proteins on the skin and potential agents to block their effects.

Carbonylated proteins (CPs) are synthesized by reactions between amino groups in proteins and reactive aldehyde compounds (RAC) yielded from lipid peroxidation initiated by reactive oxygen species (ROS). In the skin, CPs are detected in a higher frequency at sun-exposed sites of the skin in elderly subjects. Since CPs in the stratum corneum (SC) have been reported to correlate with skin water content and transepidermal water loss, it is considered that the accumulation of CPs in the SC involves the loss of skin moisture functions. However, the roles of CPs in the dermis on skin physiology are still unclear. The purpose of this study was to investigate the roles of CPs in the dermis during the progression of photoaged skin and to propose a method to prevent or reduce the synthesis of CPs. The exposure of human normal dermal fibroblasts to CPs increased intracellular ROS levels and the synthesis of intracellular CPs. In addition, CPs caused morphological changes of fibroblasts. Furthermore, CPs caused alterations of mRNA expression levels of dermal matrix-related proteins, such as upregulating MMP-1 and IL-8. These results indicated that CPs disrupt construction of the dermal matrix. On the other hand, α-tocopherol and ß-carotene suppressed the synthesis of RAC during lipid peroxidation which resulted in the reduction of UVA-induced CPs in the SC. From these results, we propose that extracellular CPs increase intracellular ROS levels and contribute to alterations of the dermal matrix. To prevent the synthesis of CPs, the application of α-tocopherol or ß-carotene could be effective.