Global ETD Search

71	More evidence for H2O2-mediated oxidative stress in vitiligo-increased epidermal DNA damage / repair. Shalbaf, Mohammad January 2009 (has links) Nowdays there is a plethora of evidence for H2O2-mediated oxidative stress in the epidermis as well as in the system in patients with vitiligo (for review see (Schallreuter, Bahadoran et al. 2008). Xanthine dehydrogenase / xanthine oxidase (XDH / XO) catalyses the oxidative hydroxylation of hypoxanthine to xanthine followed by xanthine to uric acid, the last two steps in purine degradation pathway. Under oxidative conditions, XDH is converted to XO. The reactions catalysed by this enzyme generate H2O2 and O2 ¿- , yielding in the presence of ROS accumulation, allantoin from uric acid. Therefore XO has been considered a major biologic source of oxygen-derived free radicals in many organs. The presence of XO in the human epidermis has not been shown so far. In this study several techniques were utilised to nail the presence and activity of XO in epidermal melanocytes and keratinocytes. The enzyme is regulated by H2O2 in a concentration dependent manner, where concentrations of 10-6M upregulate activity. Importantly, the results showed that the activity of XO is little affected by H2O2 in the mM range. H2O2-mediated oxidation of tryptophan and methionine residues in the sequence of XO yields only subtle alterations in the enzyme active site. These findings are in agreement with enzyme kinetics in the presence of 10-3M H2O2. Since uric acid is the end product of XO activity and this can be oxidised to allantoin by H2O2, we wanted to know whether allantoin is formed in the epidermis of patients with vitiligo. In order to address this issue, we utilised HPLC/mass spectrometry analysis. Analysis of epidermal cell extracts from suction blister tissue identified the presence of allantoin in patients with acute vitiligo, while this product was absent in healthy controls. In conclusion, our results provide evidence for functioning epidermal XO in the human epidermis which 4 can be a major source for the production of H2O2 contributing to oxidative stress in vitiligo. In addition, this thesis also demonstrates for the first time the presence of XO in melanosomes, and we showed that both 7BH4 and 7-biopterin inhibit XO activity in a concentration dependent manner. Moreover, XO has the potential to bind to 6/7BH4 and 6/7-biopterin from the pterin/tyrosinase inhibitor complex. This discovery adds another receptor independent mechanism for regulation of tyrosinase within the melanocyte similar to ¿/ß-MSH as shown earlier (Moore, Wood et al. 1999; Spencer, Chavan et al. 2005). Since the entire epidermis of patients with vitiligo is under H2O2-mediated oxidative stress, oxidative DNA damage would be highly expected. This thesis shows for the first time that epidermal 8-oxoG levels as well as plasma level of this oxidised DNA base are significantly increased in patients compared to healthy controls. We have shown that epidermal cells from patients with vitiligo respond to oxidative DNA damage via the overexpression of p21 and Gadd45¿ leading to a functioning increased short-patch base-excision repair (BER), while increased apoptosis can be ruled out due to lower caspase 3 and cytochrome c response compared to healthy controls. Our results show that patients develop effective DNA repair machinery via hOgg1, APE1 and DNA polymeraseß. Taking into consideration that these patients do not have an increased prevalence for solar-induced skin cancers, our data suggest that BER is a major player in the hierarchy to combat H2O2-mediated oxidative stress preventing ROS-induced tumourigenesis in the epidermis of these patients. H2O2-mediated oxidative stress Epidermis Vitiligo Allantoin HPLC/mass spectrometry analysis. DNA damage / repair Melanosomes Tyrosinase regulation
72	Is melanoma associated leucoderma (MAL) a distinct entity compared to classial vitiligo? Elsayed, Marwa A.T.A. January 2015 (has links) Patients with classical vitiligo lose partially their protecting inherited pigment. The cause of the disease is still unknown. Despite massive epidermal oxidative / nitrative stress and signs for DNA-damage in the skin and in the plasma, these patients have no higher prevalence for sun induced non-melanoma skin cancer and increased photo-damage. Protection and DNA-repair have been attributed to a functioning up-regulated wild type p53 / p21 cascade in association with up-regulated p76 MDM2. As some patients with cutaneous melanoma develop depigmentations away from their primary tumour site post surgical excision, it became of our interest, whether this melanoma associated leucoderma (MAL) is the same as classical vitiligo. The purpose of this thesis was two-fold. In part I, we wanted to further substantiate the reasons behind the constantly up-regulated wild-type functioning p53 / p21 cascade in classical vitiligo utilising a panel of proteins with direct and / or indirect action on p53 regulation, including p21, p76MDM2, MDM4/MDM4phospho, SPARC, VEGF-A and TGF-β1. In part II, we wanted to characterize MAL and compare this peculiar leucoderma with classical vitiligo using the same protein panel and methodologies. To achieve our goals, we used in vivo FT-Raman spectroscopy, in vitro cell cultures, in vitro and in situ immuno-fluorescence labelling, Western blot, dot blot and computer modelling techniques. Our data showed distinct differences between classical vitiligo and MAL. Our results in MAL exhibited a concentration dependent protein expression gradient between the basal / suprabasl layers and the upper layers of the epidermal compartment using catalase, ONOO-, p53, p21, MDM4, p76MDM2, TGF-β1 and VEGF-A expression gradient. Moreover, we document for the first time the presence of a nitrated non-fuctional SPARC protein in classical vitiligo which is absent in MAL. Although we show in vivo considerable ROS / RNS- mediated stress in MAL and classical vitiligo documented by FT-Raman spectroscopy, Western blot and in situ immuno-fluorescence, our results prove that MAL and classical vitiligo are two distinct entities.
73	Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 2: epidermal H2O2/ONOO−-mediated stress in vitiligo hampers indoleamine 2,3-dioxygenase and aryl hydrocarbon receptor-mediated immune response signaling. Schallreuter, Karin U., Salem, Mohamed M.A., Gibbons, Nick C., Maitland, Derek J., Marsch, E., Elwary, Souna M.A., Healey, Andrew R. 06 1900 (has links) No / Vitiligo is characterized by a mostly progressive loss of the inherited skin color. The cause of the disease is still unknown, despite accumulating in vivo and in vitro evidence of massive oxidative stress via hydrogen peroxide (H2O2) and peroxynitrite (ONOO−) in the skin of affected individuals. The most favored hypothesis is based on autoimmune mechanisms. Since depletion of the essential amino acid l-tryptophan (Trp) severely affects various immune responses, we here looked at Trp metabolism and signaling in these patients. Our in vivo and in vitro data revealed total absence of epidermal Trp hydroxylase activities and the presence of H2O2/ONOO− deactivated indoleamine 2,3-dioxygenase. Aryl hydrocarbon receptor signaling is severely impaired despite the ligand (Trp dimer) being formed, as shown by mass spectrometry. Loss of this signal is supported by the absence of downstream signals (COX-2 and CYP1A1) as well as regulatory T-lymphocytes and by computer modeling. In vivo Fourier transform Raman spectroscopy confirmed the presence of Trp metabolites together with H2O2 supporting deprivation of the epidermal Trp pool by Fenton chemistry. Taken together, our data support a long-expressed role for in loco redox balance and a distinct immune response. These insights could open novel treatment strategies for this disease.—Schallreuter, K. U., Salem, M. A. E. L., Gibbons, N. C. J., Maitland, D. J., Marsch, E., Elwary, S., Healey, A. R. Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 2: epidermal H2O2/ONOO−-mediated stress in vitiligo hampers indoleamine 2,3-dioxygenase and aryl hydrocarbon receptor-mediated immune response signaling. Vitiligo Epidermal l-tryptophan metabolism Immune response signaling ROS scavenging Hydrogen peroxide (H2O2) Fenton chemistry Peroxynitrite Treg IDO
74	The Role of Interferon Gamma in Melanocyte Clearance During Vitiligo Strassner, James P. 07 April 2019 (has links) Vitiligo is an autoimmune disease in which CD8+ T cells selectively destroy melanocytes, leading to a patchy, disfiguring depigmentation of the skin. Our group and others have highlighted the central role of IFN-γ-dependent chemokines in the progression of disease; however, IFN-γ is also reported to have pleiotropic effects on melanocyte biology. We examined whether IFN-γ has a direct role in melanocyte killing. We tested the T-cell effector functions IFN-γ, Fas ligand and perforin by deleting them from autoreactive T cells used to induce vitiligo in mice. We found that disease incidence, disease severity and T cell accumulation in the skin was reduced in mice receiving adoptive transfer of either IFN-γ deficient or Fas ligand deficient gp100-specific T cells; however, perforin was dispensable and led to increased disease scores and T cell accumulation. To determine how melanocytes are affected by IFN-γ signaling during vitiligo, we performed single-cell RNA-sequencing on suction blister biopsies obtained from vitiligo and healthy subjects. We discovered that integrin expression and TGFb2 signaling was decreased only in lesional melanocyte transcriptomes. Moreover, melanocytes appear to participate in their own demise by increasing HLA expression and recruiting effector cells through the chemotactic ligand CCL18. The loss of melanocyte retention factors may explain their clean disappearance from the skin during keratinocyte turnover. Taken together, we believe IFN-γ production by autoreactive T cells in the skin leads to clean loss of melanocytes by downregulation of melanocyte retention factors and by increasing their potential to be detected by effector cells during vitiligo. Vitiligo autoimmunity biomarker single-cell RNA-sequencing T cell melanocyte T-cell effector functions Bioinformatics Dermatology Immune System Diseases Immunity Skin and Connective Tissue Diseases Translational Medical Research
75	The Development of a Skin-Targeted Interferon-Gamma-Neutralizing Bispecific Antibody for Vitiligo Treatment Hsueh, Ying-Chao 06 June 2022 (has links) Despite the central role of IFNγ in vitiligo pathogenesis, systemic IFNγ neutralization is an impractical treatment option due to strong immunosuppression. However, most vitiligo patients present with less than 20% affected body surface area, which provides an opportunity for localized treatments that avoid systemic side effects. After identifying keratinocytes as key cells that amplify IFNγ signaling during vitiligo, I hypothesized that tethering an IFNγ neutralizing antibody to keratinocytes would limit anti-IFNγ effects to the treated skin for the localized treatment. To that end, I developed a bispecific antibody (BsAb) capable of blocking IFNγ signaling while binding to desmoglein expressed by keratinocytes. I characterized the effect of the BsAb in vitro, ex vivo, and in a mouse model of vitiligo. SPECT/CT biodistribution and serum assays after local footpad injection revealed that the BsAb had improved skin retention, faster elimination from the blood, and less systemic IFNγ inhibition than the non-tethered version. Furthermore, the BsAb conferred localized protection almost exclusively to the treated footpad during vitiligo that was not possible by local injection of the non-tethered anti-IFNγ antibody. Thus, keratinocyte-tethering proved effective while significantly diminishing off-tissue effects of IFNγ blockade, offering a new treatment strategy for localized skin diseases, including vitiligo. vitiligo bispecific antibody IFN-γ tissue targeted drug delivery skin-tethered BsAb autoimmune disease Biotechnology Dermatology Immunotherapy Skin and Connective Tissue Diseases
76	Dissection of Zebrafish Adult Melanocyte Stem Cell Signaling During Regeneration Frantz, William Tyler 26 May 2021 (has links) Tissue-resident stem cells are present in many adult organs, where they are important for organ homeostasis and repair in response to injury. However, the signals that activate these cells and the mechanisms governing how these cells self-renew or differentiate are highly context dependent and incompletely understood, particularly in non-hematopoietic tissues. In the skin, melanocyte stem cells (McSCs) are responsible for replenishing mature pigmented melanocytes. In mammals, these cells reside in the hair follicle bulge and bulb niches where they are activated during homeostatic hair follicle turnover and following melanocyte destruction, as occurs in vitiligo and other skin hypopigmentation disorders. Recently, we identified adult McSCs in the zebrafish. To elucidate mechanisms governing McSC self-renewal and differentiation fates we analyzed individual transcriptomes from thousands of melanocyte lineage cells during the regeneration process. We identified transcriptional signatures for McSCs, deciphered transcriptional changes and intermediate cell states during regeneration, and analyzed cell-cell signaling changes to discover mechanisms governing melanocyte regeneration. We identified KIT signaling via the RAS/MAPK pathway as a regulator of McSC direct differentiation. Analysis of the scRNAseq dataset also revealed a population of mitfa/aox5 co-expressing cells that divides following melanocyte destruction, likely corresponding to cells that undergo self-renewal. Our findings show how different subpopulations of mitfa-positive cells underlie regeneration and differentiation of at least one subpopulation requires reactivation of developmental KIT signaling to properly reconstitute the melanocyte stripe. Melanocytes Melanocyte Stem Cells McSC Zebrafish Danio rerio Melanoma Vitiligo Single cell transcriptomics scRNAseq KIT c-KIT kita Cell Biology Cellular and Molecular Physiology Developmental Biology
77	Blunted epidermal l-tryptophan metabolism in vitiligo affects immune response and ROS scavenging by Fenton chemistry, part 1: epidermal H2O2/ONOO−-mediated stress abrogates tryptophan hydroxylase and dopa decarboxylase activities, leading to low serotonin and melatonin levels. Schallreuter, Karin U., Salem, Mohamed M.A., Gibbons, Nick C., Martinez, A., Slominski, Radomir, Lüdemann, J., Rokos, Hartmut 06 1900 (has links) No / Vitiligo is characterized by a progressive loss of inherited skin color. The cause of the disease is still unknown. To date, there is accumulating in vivo and in vitro evidence for massive oxidative stress via hydrogen peroxide (H2O2) and peroxynitrite (ONOO−) in the skin of affected individuals. Autoimmune etiology is the favored theory. Since depletion of the essential amino acid l-tryptophan (Trp) affects immune response mechanisms, we here looked at epidermal Trp metabolism via tryptophan hydroxylase (TPH) with its downstream cascade, including serotonin and melatonin. Our in situ immunofluorescence and Western blot data reveal significantly lower TPH1 expression in patients with vitiligo. Expression is also low in melanocytes and keratinocytes under in vitro conditions. Although in vivo Fourier transform-Raman spectroscopy proves the presence of 5-hydroxytryptophan, epidermal TPH activity is completely absent. Regulation of TPH via microphthalmia-associated transcription factor and l-type calcium channels is severely affected. Moreover, dopa decarboxylase (DDC) expression is significantly lower, in association with decreased serotonin and melatonin levels. Computer simulation supports H2O2/ONOO−-mediated oxidation/nitration of TPH1 and DDC, affecting, in turn, enzyme functionality. Taken together, our data point to depletion of epidermal Trp by Fenton chemistry and exclude melatonin as a relevant contributor to epidermal redox balance and immune response in vitiligo. Vitiligo Epidermal l-tryptophan metabolism Melatonin Immune response signaling ROS scavenging Hydrogen peroxide (H2O2) Fenton chemistry Peroxynitrite MITF Calcium channel DNA Oxidative stress
78	Enhanced DNA binding capacity on up-regulated epidermal wild-type p53 in vitiligo by H2O2-mediated oxidation: a possible repair mechanism for DNA damage Salem, Mohamed M.A., Shalbaf, Mohammad, Gibbons, Nick C., Chavan, Bhavan, Thornton, M. Julie, Schallreuter, Karin U. January 2009 (has links) No / Vitiligo is characterized by a patchy loss of inherited skin color affecting approximately 0.5% of individuals of all races. Despite the absence of the protecting pigment and the overwhelming evidence for hydrogen peroxide (H(2)O(2))-induced oxidative stress in the entire epidermis of these patients, there is neither increased photodamage/skin aging nor a higher incidence for sun-induced nonmelanoma skin cancer. Here we demonstrate for the first time increased DNA damage via 8-oxoguanine in the skin and plasma in association with epidermal up-regulated phosphorylated/acetylated p53 and high levels of the p53 antagonist p76(MDM2). Short-patch base-excision repair via hOgg1, APE1, and polymerasebeta DNA repair is up-regulated. Overexpression of Bcl-2 and low caspase 3 and cytochrome c levels argue against increased apoptosis in this disease. Moreover, we show the presence of high epidermal peroxynitrite (ONOO(-)) levels via nitrotyrosine together with high nitrated p53 levels. We demonstrate by EMSA that nitration of p53 by ONOO(-) (300 x 10(-6) M) abrogates DNA binding, while H(2)O(2)-oxidized p53 (10(-3) M) enhances DNA binding capacity and prevents ONOO(-)-induced abrogation of DNA binding. Taken together, we add a novel reactive oxygen species to the list of oxidative stress inducers in vitiligo. Moreover, we propose up-regulated wild-type p53 together with p76(MDM2) as major players in the control of DNA damage/repair and prevention of photodamage and nonmelanoma skin cancer in vitiligo. Adult Apoptosis Physiology Ataxia Telangiectasia Mutated Proteins Caspase 3 Biosynthesis Cell cycle proteins Metabolism Cytochromes c DNA DNA damage Drug effects DNA repair DNA-binding proteins Electrophoretic mobility shift assay Epidermis Guanosine Analogs & derivatives Humans Hydrogen peroxide Pharmacology Middle aged Oxidation-reduction Oxidative stress Peroxynitrous acid Protein-Serine-Threonine Kinases Proto-Oncogene Proteins c-bcl-2 Proto-Oncogene Proteins c-mdm2 Tumor Suppressor Protein p53 Tumor Suppressor Proteins Up-Regulation Vitiligo p300-CBP Transcription Factors REF 2014

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