Rosmarinic acid alleviates ultraviolet-mediated skin aging via attenuation of mitochondrial and ER stress responses.

Chronic exposure to Ultraviolet B radiation (UV-B) evokes a myriad of toxic signalling events in the irradiated skin. One of such response is ER stress, which is known to exacerbate photodamage responses. Also, recent literature has highlighted the adverse impact of environmental toxicants on mitochondrial dynamics and mitophagy. Impaired mitochondrial dynamics escalates oxidative damage and causes apoptosis. There have been evidences that support crosstalk between ER stress and mitochondrial dysfunction. However, mechanistic clarification is still needed to verify the interactions between UPR responses and mitochondrial dynamics impairment in UV-B-induced photodamage models. Lastly, plant-based natural agents have garnered attention as therapeutic agents against skin photodamage. Thus, gaining mechanistic insights of plant-based natural agents is required for their application and feasibility in clinical settings. With this aim in view, this study was performed in primary human dermal fibroblasts (HDFs) and Balb/C mice. Different parameters regarding mitochondrial dynamics, ER stress, intracellular damage and histological damage were analyzed using western blot, rt-PCR and microscopy. We demonstrated that UV-B exposure leads to induction of UPR responses, upregulation of Drp-1 and inhibition of mitophagy. Further, 4-PBA treatment leads to reversal of these noxious stimuli in irradiated HDF cells, thereby, indicating an upstream role of UPR induction in mitophagy inhibition. Also, we explored the therapeutic effect of Rosmarinic acid (RA) against ER stress and impaired mitophagy in photodamage models. RA prevents intracellular damage via alleviation of ER stress and mitophagic responses in HDFs and irradiated Balb/C mice skin. The current study summarizes the mechanistic insights into UVB-mediated intracellular damage and role of natural plant-based agent (RA) in ameliorating these toxic responses.

Pharmacological Activation of Autophagy Restores Cellular Homeostasis in Ultraviolet-(B)-Induced Skin Photodamage.

Ultraviolet (UV) exposure to the skin causes photo-damage and acts as the primary etiological agent in photo-carcinogenesis. UV-B exposure induces cellular damage and is the major factor challenging skin homeostasis. Autophagy allows the fundamental adaptation of cells to metabolic and oxidative stress. Cellular dysfunction has been observed in aged tissues and in toxic insults to cells undergoing stress. Conversely, promising anti-aging strategies aimed at inhibiting the mTOR pathway have been found to significantly improve the aging-related disorders. Recently, autophagy has been found to positively regulate skin homeostasis by enhancing DNA damage recognition. Here, we investigated the geno-protective roles of autophagy in UV-B-exposed primary human dermal fibroblasts (HDFs). We found that UV-B irradiation to HDFs impairs the autophagy response in a time- and intensity-independent manner. However, improving autophagy levels in HDFs with pharmacological activators regulates the UV-B-induced cellular stress by decreasing the induction of DNA photo-adducts, promoting the DNA repair process, alleviating oxidative and ER stress responses, and regulating the expression levels of key cell cycle regulatory proteins. Autophagy also prevents HDFs from UV-B-induced nuclear damage as is evident in TUNEL assay and Acridine Orange/Ethidium Bromide co-staining. Salubrinal (an eIF2α phosphatase inhibitor) relieves ER stress response in cells and also significantly alleviates DNA damage and promotes the repair process in UV-B-exposed HDFs. P62-silenced HDFs show enhanced DNA damage response and also disturb the tumor suppressor PTEN/pAKT signaling axis in UV-B-exposed HDFs whereas Atg7-silenced HDFs reveal an unexpected consequence by decreasing the UV-B-induced DNA damage. Taken together, these results suggest that interventional autophagy offers significant protection against UV-B radiation-induced photo-damage and holds great promise in devising it as a suitable therapeutic strategy against skin pathological disorders.