Sean M. Dawes scite author profile

IL-17C is a functionally distinct member of the IL-17 family that binds IL-17RE/A to promote innate defense in epithelial cells and regulate Th17 cell differentiation. We demonstrate that IL-17C (not IL-17A) is the most abundant IL-17 isoform in lesional psoriasis skin (1058pg/ml vs. 8pg/ml; p<0.006) and localizes to keratinocytes (KCs), endothelial cells (ECs) and leukocytes. ECs stimulated with IL-17C produce increased TNFα and KCs stimulated with IL-17C/TNFα produce similar inflammatory gene response patterns as those elicited by IL-17A/TNFα, including increases in IL-17C, TNFα, IL-8, IL-1α/β, IL-1F5, IL-1F9, IL-6, IL-19, CCL20, S100A7/A8/A9, DEFB4, LCN2 and PI3 (p<0.05); indicating a positive pro-inflammatory feedback loop between the epidermis and ECs. Psoriasis patients treated with etanercept rapidly decrease cutaneous IL-17C levels, suggesting IL-17C/TNFα-mediated inflammatory signaling is critical for psoriasis pathogenesis. Mice genetically engineered to overexpress IL-17C in KCs develop well-demarcated areas of erythematous, flakey “involved” skin adjacent to areas of normal appearing “uninvolved” skin despite increased IL-17C expression in both areas (p<0.05). Uninvolved skin displays increased angiogenesis and elevated S100A8/A9expression (p<0.05) but no epidermal hyperplasia; whereas involved skin exhibits robust epidermal hyperplasia, increased angiogenesis and leukocyte infiltration and upregulated TNFα, IL-1α/β, IL-17A/F, IL-23p19, VEGF, IL-6 and CCL20 (p<0.05) suggesting that IL-17C, when coupled with other pro-inflammatory signals, initiates the development of psoriasiform dermatitis. This skin phenotype was significantly improved following 8 weeks of TNFα inhibition. These findings identify a role for IL-17C in skin inflammation and suggest a pathogenic function for the elevated IL-17C observed in lesional psoriasis skin.

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Racial disparities in melanoma survival

Dawes

Tsai

Gittleman

et al. 2016

Journal of the American Academy of Dermatology

151

140

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Vitamin C distribution and retention in the mouse brain

et al. 2010

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Vitamin C (VC) is a crucial antioxidant in the brain. To assess whether different brain regions vary in their sensitivity to oxidative stress induced by VC depletion, we used the gulonolactone oxidase (gulo) knockout mouse. This mouse, like humans, cannot synthesize VC and thus its tissue VC levels can be varied by dietary VC intake. Gulo knockout mice were fed drinking water containing standard (0.33 g/L), low (0.033 g/L) or zero (0 g/L) VC supplementation levels. After 4 weeks, mice were sacrificed and different brain regions removed for assay of VC and malondialdehyde, a marker of lipid peroxidation. Compared to age-matched wild-type controls, the cerebellum, olfactory bulbs and frontal cortex had the highest VC content, whereas the pons and spinal chord had the lowest. However, in mice that did not receive VC, area differences were no longer significant as all values trended towards zero. Malondialdehyde increased in the cortex as VC supplementation was decreased. The same changes were not observed in the cerebellum or pons, suggesting that cortex is more susceptible to oxidative damage from low VC. These results suggest enhanced susceptibility of the cortex to oxidative stress induced by low VC compared to other brain regions.

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Low vitamin C and increased oxidative stress and cell death in mice that lack the sodium-dependent vitamin C transporter SVCT2

Harrison

Dawes

Meredith

et al. 2010

Free Radical Biology and Medicine

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The Sodium-dependent Vitamin C Transporter (SVCT2) is responsible for the transport of vitamin C into cells in multiple organs, either from the blood or cerebrospinal fluid. Mice null for SVCT2 (SVCT2(−/−)) do not survive past birth but cause of death has not yet been ascertained. Following mating of SVCT2(+/−) males and SVCT2(+/−) females, fewer SVCT2(−/−) and (+/−) were observed than would be expected according to Mendelian ratios. Vitamin C levels in SVCT2(−/ −), (+/−) and (+/+) were genotype-dependent. SVCT2(−/−) fetuses had significantly lower vitamin C levels than littermates in placenta, cortex, and lung but not in liver (the site of vitamin C synthesis). Low vitamin C levels in placenta and cortex were associated with elevations in several different markers of oxidative stress; malondialdehyde, isoketals, F 2 -isoprostanes, and F 4 -neuroprostanes. Oxidative stress was not elevated in fetal SVCT2(−/−) lung tissue despite low vitamin C levels. In addition to the expected severe hemorrhage in cortex, we also found hemorrhage in the brain stem, which was accompanied by cell loss. We found evidence of increased apoptosis in SVCT2(−/−) mice and disruption of the basement membrane in fetal brain. Together these data show that vitamin C is critical for maintaining vitamin C levels in fetal and placental tissues and that lack of SVCT2, and resulting low vitamin C levels, results in fetal death, and in SVCT(−/−) that survive the gestation period, in oxidative stress and cell death.

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Ascorbic acid attenuates scopolamine-induced spatial learning deficits in the water maze

Harrison

Hosseini

Dawes

et al. 2009

Behavioural Brain Research

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Vitamin C (ascorbate) has important antioxidant functions that can help protect against oxidative stress in the brain and damage associated with neurodegenerative disorders such as Alzheimer's disease. When administered parenterally ascorbate can bypass saturable uptake mechanisms in the gut and thus higher tissue concentrations can be achieved than by oral administration. In the present study we show that ascorbate (125 mg/kg) administered intraperitoneally (i.p.) 1-hour before testing, partially attenuated scopolamine-induced (1 mg/kg i.p.) cognitive deficits in Morris water maze performance in young mice. Cumulative search error, but not escape latency nor path length, was significantly improved during acquisition in ascorbate plus scopolamine-treated mice although performance did not equal that of control mice. During the probe trial, scopolamine led to increased search error and chance level of time spent in the platform quadrant, whereas mice pre-treated with ascorbate prior to scopolamine did not differ from control mice on these measures. Ascorbate had no effect on unimpaired, control mice and neither did it reduce the peripheral, activity-increasing effects of scopolamine. Ascorbate alone increased acetylcholinesterase activity in the medial forebrain area but had no effect in cortex or striatum. This change, and its action against the amnestic effects of the muscarinic antagonist scopolamine, suggest that ascorbate may be acting in part via altered cholinergic signaling. However, further investigation is necessary to isolate the cognitionenhancing effects of ascorbate.

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Sean M. Dawes

Keratinocyte Overexpression of IL-17C Promotes Psoriasiform Skin Inflammation

Racial disparities in melanoma survival

Vitamin C distribution and retention in the mouse brain

Low vitamin C and increased oxidative stress and cell death in mice that lack the sodium-dependent vitamin C transporter SVCT2

Ascorbic acid attenuates scopolamine-induced spatial learning deficits in the water maze

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