Human tyrosinase is able to oxidize both enantiomers of rhododendrol

Racemic RS‐4‐(4‐hydroxyphenyl)‐2‐butanol (rhododendrol, RD) was used as a topical skin‐whitening agent until it was recently reported to induce leukoderma. We then showed that oxidation of RD with mushroom tyrosinase rapidly produces RD‐quinone, which is quickly converted to RD‐cyclic quinone and RD‐hydroxy‐p‐quinone. In this study, we examined whether either or both of the enantiomers of RD can be oxidized by human tyrosinase. Using a chiral HPLC column, racemic RD was resolved optically to R(?)‐RD and S(+)‐RD enantiomers. In the presence of a catalytic amount of l ‐dopa, human tyrosinase, which can oxidize l ‐tyrosine but not d ‐tyrosine, was found to oxidize both R(?)‐ and S(+)‐RD to give RD‐catechol and its oxidation products. S(+)‐RD was more effectively oxidized than l ‐tyrosine, while R(?)‐RD was less effective. These results support the notion that the melanocyte toxicity of RD depends on its tyrosinase‐catalyzed conversion to toxic quinones and the concomitant production of reactive oxygen species.     

Glutathione pool size affects cell survival after hyperthermic treatment

Intracellular glutathione (GSH) concentrations were titrated in Chinese hamster ovary cells by exposure to various concentrations of diethylmaleate (DEM). The various steady state levels of GSH obtained were maintained throughout the experimental time course. Cells were incubated at 42° after DEM addition in order to produce thermal dose response curves using colony formation as the end point. The slope of the dose response curve was subsequently determined and compared to the intracellular GSH concentration. This comparison indicated Chinese hamster ovary cells contain multiple reservoirs of GSH which in turn regulate thermal toxicity in a stepwise manner. Removal of 50% or less of the GSH did not affect thermal sensitivity. A small increase in sensitivity occured when 50 to 80% of the GSH was removed. Removal of greater than 80% of the GSH increased thermal toxicity significantly. The facts that 10 and 20 µM DEM produce extensive GSH depletion and only small changes in survival imply that a threshold concentration of GSH must be removed before thermal toxicity is affected.Abbreviations BCNU 1-3-Bis(2-Chloroethyl)-1-nitrosourea - BSO buthionine sulfoximine - CHO Chinese hamster ovary - DEM diethylmaleate - DMSO dimethyl sulfoxide - HBSS Hanks balanced salt solution - RF radiofrequency     

Modulation of Glutathione and Glutathione Dependent Antioxidant Enzymes in Mouse Heart Following Doxorubicin Therapy

The toxicity of the antineoplastic agent doxorubicin (DOX) has been shown to be moderated by the antioxidant enzyme glutathione peroxidase. It has been reported that acute doses of DOX can cause an inhibition of glutathione peroxidase in cardiac tissue, that may render this tissue especially susceptible to further prooxidant damage. In this study, multiple DOX treatments at a therapeutic dose were assessed for their effect on the antioxidant enzyme status of cardiac and kidney tissue. DOX was administered i.p. (5 mg/kg) once a week for two weeks to male balb/c mice. The activities of the antioxidant enzymes superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase (GPOX) and glutathione reductase (GR) were measured 1, 2 and 7 days following the second DOX treatment in both heart and kidney. Levels of reduced glutathione (GSH) were also measured in cardiac tissue at these same times. Cardiac levels of GPOX and GR showed a time-dependent decrease in activity, with 10% and 12% inhibition for GPOX and GR, respectively, at 7 days post second treatment. Cardiac levels of GSH also showed a significant decrease, approximately 15%, at 7 days post second treatment. Cardiac levels of SOD and CAT as well as kidney levels of all four antioxidant enzymes were not affected by DOX treatment. These data suggest that DOX given in a therapeutic regimen, at a therapeutic dose, can cause decreases in cardiac levels of GPOX, GR and GSH that could render the heart especially susceptible to further oxidative challenge.     

The unfolded protein response in melanocytes: activation in response to chemical stressors of the endoplasmic reticulum and tyrosinase misfolding

Accumulation of proteins in the endoplasmic reticulum (ER) triggers the unfolded protein response (UPR), comprising three signaling pathways initiated by Ire1, Perk and Atf6 respectively. Unfolded protein response activation was compared in chemically stressed murine wildtype melanocytes and mutant melanocytes that retain tyrosinase in the ER. Thapsigargin, an ER stressor, activated all pathways in wildtype melanocytes, triggering Caspase 12-mediated apoptosis at toxic doses. Albino melanocytes expressing mutant tyrosinase showed evidence of ER stress with increased Ire1 expression, but the downstream effector, Xbp1, was not activated even following thapsigargin treatment. Attenuation of Ire1 signaling was recapitulated in wildtype melanocytes treated with thapsigargin for 8 days, with diminished Xbp1 activation observed after 4 days. Atf6 was also activated in albino melanocytes, with no response to thapsigargin, while the Perk pathway was not activated and thapsigargin treatment elicited robust expression of the downstream effector CCAAT-enhancer-binding protein homologous protein. Thus, melanocytes adapt to ER stress by attenuating two UPR pathways.     

Tyrosinase‐catalyzed oxidation of rhododendrol produces 2‐methylchromane‐6,7‐dione,the putative ultimate toxic metabolite: implications for melanocyte toxicity

RS‐4‐(4‐Hydroxyphenyl)‐2‐butanol (rhododendrol, RD) was used as a skin‐whitening agent until it was reported to induce leukoderma in July 2013. To explore the mechanism underlying its melanocyte toxicity, we characterized the tyrosinase‐catalyzed oxidation of RD using spectrophotometry and HPLC. Oxidation of RD with mushroom tyrosinase rapidly produced RD‐quinone, which was quickly converted to 2‐methylchromane‐6,7‐dione (RD‐cyclic quinone) and RD‐hydroxy‐p‐quinone through cyclization and addition of water molecule, respectively. RD‐quinone and RD‐cyclic quinone were identified as RD‐catechol and RD‐cyclic catechol after NaBH₄ reduction. Autoxidation of RD‐cyclic catechol produced superoxide radical. RD‐quinone and RD‐cyclic quinone quantitatively bound to thiols such as cysteine and GSH. These results suggest that the melanocyte toxicity of RD is caused by its tyrosinase‐catalyzed oxidation through production of RD‐cyclic quinone which depletes cytosolic GSH and then binds to essential cellular proteins through their sulfhydryl groups. The production of ROS through autoxidation of RD‐cyclic catechol may augment the toxicity.     

Mechanism of action of 4‐substituted phenols to induce vitiligo and antimelanoma immunity

Monobenzone is a 4‐substituted phenol that can induce vitiligo and antimelanoma immunity. We investigated the influence of the chemical structure on the biological activity of a series of structurally related 4‐substituted phenols. All phenols inhibited cellular melanin synthesis, and eight of ten phenols inhibited tyrosinase activity, using the MBTH assay. These phenols also induced glutathione (GSH) depletion, indicative of quinone formation and protein thiol binding, which can increase the immunogenicity of melanosomal proteins. Specific T‐cell activation was found upon stimulation with phenol‐exposed pigmented cells, which also reacted with unexposed cells. In contrast, 4‐tertbutylphenol induced immune activation was not restricted to pigment cells, analogous to contact sensitization. We conclude that 4‐substituted phenols can induce specific T‐cell responses against melanocytes and melanoma cells, also acting at distant, unexposed body sites, and may confer a risk of chemical vitiligo. Conversely, these phenols may be applicable to induce specific antimelanoma immunity.     

Tyrosinase‐catalyzed metabolism of rhododendrol (RD) in B16 melanoma cells: production of RD‐pheomelanin and covalent binding with thiol proteins

RS‐4‐(4‐Hydroxyphenyl)‐2‐butanol (rhododendrol, RD) was reported to induce leukoderma of the skin. To explore the mechanism underlying that effect, we previously showed that oxidation of RD with mushroom tyrosinase produces RD‐quinone, which is converted to secondary quinone products, and we suggested that those quinones are cytotoxic because they bind to cellular proteins and produce reactive oxygen species. We then confirmed that human tyrosinase can oxidize both enantiomers of RD. In this study, we examined the metabolism of RD in B16F1 melanoma cells in vitro. Using 4‐amino‐3‐hydroxy‐n‐butylbenzene as a specific indicator, we detected moderate levels of RD‐pheomelanin in B16F1 cells exposed to 0.3 to 0.5 mM RD for 72 h. We also confirmed the covalent binding of RD‐quinone to non‐protein thiols and proteins through cysteinyl residues. The covalent binding of RD‐quinone to proteins was 20‐ to 30‐fold greater than dopaquinone. These results suggest that the tyrosinase‐induced metabolism of RD causes melanocyte toxicity.     

Toxoplasma gondii autophagy‐related protein ATG9 is crucial for the survival of parasites in their host

Autophagy is a conserved, life‐promoting, catabolic process involved in the recycling of nonessential cellular components in response to stress. The parasite Toxoplasma gondii is an early‐diverging eukaryote in which part of the autophagy machinery is not exclusively involved in a catabolic process but instead has been repurposed for an original function in organelle inheritance during cell division. This function, depending essentially on protein TgATG8 and its membrane conjugation system, is crucial for parasite survival and prevented an in depth study of autophagy in the mutants generated so far in Toxoplasma. Thus, in order to decipher the primary function of canonical autophagy in the parasites, we generated a cell line deficient for TgATG9, a protein thought to be involved in the early steps of the autophagy process. Although the protein proved to be dispensable for the development of these obligate intracellular parasites in vitro, the absence of TgATG9 led to a reduced ability to sustain prolonged extracellular stress. Importantly, depletion of the protein significantly reduced parasites survival in macrophages and markedly attenuated their virulence in mice. Altogether, this shows TgATG9 is important for the fate of Toxoplasma in immune cells and contributes to the overall virulence of the parasite, possibly through an involvement in a canonical autophagy pathway.     

Rac1 is crucial for hair follicle integrity but is not essential for maintenance of the epidermis

Rac1 is a small GTPase that regulates the actin cytoskeleton but also other cellular processes. To investigate the function of Rac1 in skin, we generated mice with a keratinocyte-restricted deletion of the rac1 gene. Rac1-deficient mice lost nearly all of their hair within a few weeks after birth. The nonpermanent part of mutant hair follicles developed constrictions; lost expression of hair follicle-specific keratins, E-cadherin, and alpha6 integrin; and was eventually removed by macrophages. The permanent part of hair follicles and the sebaceous glands were maintained, but no regrowth of full-length hair follicles was observed. In the skin of mutant mice, epidermal keratinocytes showed normal differentiation, proliferation, cell-cell contacts, and basement membrane deposition, demonstrating no obvious defects of Rac1-deficient epidermis in vivo. In vitro, Rac1-null keratinocytes displayed a strong spreading defect and slightly impaired adhesion. These data show that Rac1 plays an important role in sustaining the integrity of the lower part of hair follicles but not in maintenance of the epidermis.     

Glutathione produced by Rhizobium tropici is important to prevent early senescence in common bean nodules

In this paper, we examine the importance of glutathione in symbiosis, using a glutathione biosynthetic gshB mutant derived from Rhizobium tropici CIAT899, a common bean (Phaseolus vulgaris) endosymbiont. Plants infected with the mutant strain presented a delayed nodulation phenotype and a reduction in the dry weight of aerial part of plants, suggesting diminished nitrogen-fixation activity. In addition, bacterial gshB expression was assayed in wild-type infected nodules, during the different steps of nodulation, and found to increase in mature and early senescent nodules. Conspicuously, nodules induced by gshB mutant bacteria presented an early senescent pattern, which was associated with increased levels of superoxide accumulation. These results provide a direct evidence of the role of bacterial glutathione in protecting nodules from reactive oxygen species, which may determine nodule senescence.     

Cytoplasmic glutathione redox status determines survival upon exposure to the thiol-oxidant 4,4'-dipyridyl disulfide

Dipyridyl disulfide (DPS) is a highly reactive thiol oxidant that functions as electron acceptor in thiol-disulfide exchange reactions. DPS is very toxic to yeasts, impairing growth at low micromolar concentrations. The genes TRX2 (thioredoxin), SOD1 (superoxide dismutase), GSH1 (gamma-glutamyl-cysteine synthetase) and, particularly, GLR1 (glutathione reductase) are required for survival on DPS. DPS is uniquely thiol-specific, and we found that the cellular mechanisms for DPS detoxification differ substantially from that of the commonly used thiol oxidant diamide. In contrast to this oxidant, the full antioxidant pools of glutathione (GSH) and thioredoxin are required for resistance to DPS. We found that DPS-sensitive mutants display increases in the disulfide form of GSH (GSSG) during DPS exposure that roughly correlate with their more oxidizing GSH redox potential in the cytosol and their degree of DPS sensitivity. DPS seems to induce a specific disulfide stress, where an increase in the cytoplasmic/nuclear GSSG/GSH ratio results in putative DPS target(s) becoming sensitive to DPS.     

Glutathione S-transferase is a novel target for mood stabilizing drugs in primary cultured neurons

Oligonucleotide microarray technology was used to analyze gene expression profiles after chronic treatment with the mood stabilizing drug valproate at a therapeutically relevant concentration in primary cultured rat cerebral cortical cells. We discovered that valproate regulates expression of 28 genes, including three isoenzymes (M1, A3 and A4) of glutathione S-transferase (GST), an important protective factor against oxidative stress. Because previous studies in our laboratory found that chronic valproate treatment protected cultured neurons against oxidative stress, further experiments on the regulation of GST were performed. Regulation of GST M1, GST A3 and GST A4 was verified using northern blotting hybridization. Chronic valproate treatment increased mRNA levels of M1 and A4, but decreased the A3 mRNA level dose-dependently, indicating further complexities in the regulation of GST by valproate. The level of GST M1 protein and GST activity were also increased by chronic valproate treatment. In addition, chronic treatment with lithium, another commonly prescribed mood stabilizer, also increased levels of GST M1 mRNA and protein. The present findings suggest that regulation of GST M1, and possibly GST A4, may mediate the anti-oxidative effects of valproate treatment, and regulation of GST may be involved in the mood stabilizing effect of valproate and lithium.     

Effect of diazinon exposure on antioxidant reactions in the silkmoth,Bombyx mori

We investigated the effects of exposure to diazinon, an organophosphate insecticide, on the expression of antioxidant and detoxification factors in the silkmoth. Exposure to diazinon resulted in induction of mRNA encoding manganese containing superoxide dismutase (SOD) and omega‐class glutathione S‐transferases (GST), whereas no changes were observed in catalase, other class of GST and acetylcholinesterase. Liquid chromatography showed that the amount of reactive oxygen species was increased, whereas the amount of glutathione was decreased in the silkmoth fat body after exposure to diazinon. These results suggest that SOD and omega‐class GSTs can contribute to organophosphate resistance in Lepidopterans.     

Stepping up melanocytes to the challenge of UV exposure

Exposure to solar ultraviolet radiation (UV) is the main etiological factor for skin cancer, including melanoma. Cutaneous pigmentation, particularly eumelanin, afforded by melanocytes is the main photoprotective mechanism, as it prevents UV-induced DNA damage in the epidermis. Therefore, maintaining genomic stability of melanocytes is crucial for prevention of melanoma, as well as keratinocyte-derived basal and squamous cell carcinoma. A critical independent factor for preventing melanoma is DNA repair capacity. The response of melanocytes to UV is mediated mainly by a network of paracrine factors that not only activate melanogenesis, but also DNA repair, anti-oxidant, and survival pathways that are pivotal for maintenance of genomic stability and prevention of malignant transformation or apoptosis. However, little is known about the stress response of melanocytes to UV and the regulation of DNA repair pathways in melanocytes. Unraveling these mechanisms might lead to strategies to prevent melanoma, as well as non-melanoma skin cancer.     

Responses of Glutathione and Glutathione S-Transferase to Cadmium and Mercury Exposure in Pedunculate Oak (Quercus robur) Leaf Discs

Changes in chlorophyll, non-protein thiol and glutathione (GSH) levels, and the activity of glutathione S-transferase (GST) were investigated in cadmium(ll) and mercury(ll) cchloride treated leaf discs of mature pedunculate oak trees (Quercus robur). Both heavy metals caused decreases in chlorophyll content, but mercury was more toxic than cadmium. Cadmium treatments (30–250μiM) resulted in increasing non-protein thiol levels after 3d, but GSH contents decreased. Mercury (1–20μM) led to a concentration-dependent decline in both non-protein thiol and GSH levels. GST activities were not modified significantly by cadmium, but mercury treatments caused a dose- and time-dependent enzyme induction. Both the phytotoxic- and GST-inducing effect of mercury could be prevented by the cysteine precursor L-2-oxo-4-thiazolidinecarboxylic acid.     

Glutathione contributes to the efflux of selenium from hepatoma cells

Selenite is a selenium source for selenoprotein biosynthesis in mammalian cells. Although previous studies have suggested the involvement of glutathione (GSH) and/or thioredoxin reductase in selenite metabolism, intracellular selenite metabolism remains largely unknown. Here, we report that GSH depletion did not affect the amount of selenoprotein in Hepa 1–6 cells, suggesting that GSH does not play a central role in the reduction of selenite in selenoprotein biosynthesis. On the other hand, we found that GSH is involved in the efflux of low-molecular-weight selenium compounds from cells, presumably via the formation of selenodiglutathione. Moreover, selenite inhibited the efflux of a fluorescent bimane-GS conjugate that is mediated by ATP-dependent multidrug-resistant proteins, implying the existence of an active transporter for selenodiglutathione. This is the first report demonstrating that GSH plays a role in selenium excretion from cells by forming a GSH-conjugate, which may contribute to the distribution, detoxification, and homeostasis of selenium in the body.     

Evaluation of Gambierdiscus survival after exposure to ballast water

The dinoflagellate Gambierdiscus was exposed to ballast water from a trans-oceanic vessel, and maintained at a variety of temperatures in the dark to determine if viability would be maintained. Logarithmically growing Gambierdiscus inocula were admixed (1:6, vol:vol) with ballast water, maintained in the dark at 22.6 °C, 24.6 °C, 26.8 °C and 29.0 °C and assessed for numerical abundance over six days. Calculated growth rates from the biomass time series showed no indication that ballast water negatively impacted Gambierdiscus viability; accompanying microscopic inspections supported this conclusion. Filtration of large volumes of collected ballast water failed to show the presence of any Gambierdiscus cells contained therein. Recovery and microscopic examination of the experimental inocula after 10 weeks in the dark, failed to show cyst development at any temperature regime. This examination of ballast water showed no evidence of cytotoxicity to Gambierdiscus spp.