Global ETD Search

31	Estudo do papel das proteínas mitocondriais desacopladas na tolerância aos estresses abióticos empregando diferentes abordagens / Nunes, Alessandra Vasconcellos. January 2010 (has links) Orientador: Ivan de Godoy Maia / Banca: Paulo Eduardo Martins Ribolla / Banca: Marcelo Menossi Teixeira / Resumo: As proteínas desacopladoras pertencem à família de carreadores aniônicos mitocondriais. De maneira geral, as proteínas desacopladoras dissipam o gradiente eletroquímico de prótons gerados na respiração na forma de calor, sendo dependentes de ácidos graxos e sensíveis aos nucleotídeos purínicos. O presente estudo visou investigar o comportamento de plantas transgênicas de tabaco que expressam de forma constitutiva o gene AtUCP1, frente aos estresses osmótico e salino, bem como analisar a atividade das regiões promotoras dos genes AtUCP1 e AtUCP2 de Arabidopsis thaliana, em resposta aos estresses osmótico e de baixa temperatura, e ao ácido abscísico. Numa primeira abordagem foram utilizadas sementes selvagens e de duas linhagens transgênicas, germinadas em meio MS adicionados ou não de NaCl e Manitol. O teste de germinação revelou que as linhagens transgênicas apresentam uma maior tolerância aos referidos estresses. Quando o crescimento radicular foi analisado, uma maior inibição foi constatada no controle não transgênico em relação às duas linhagens transgênicas testadas. Adicionalmente, quando submetidas aos estresses, uma maior acumulação de ânion superóxido foi verificada nas folhas de plântulas não transgênicas em relação às plântulas das linhagens transgênicas. Quanto à quantificação de GUS nas plantas transformadas com os promotores dos genes AtUCP1 e AtUCP2, nenhuma alteração significativa foi observada em nenhum dos tratamentos testados / Abstract: The uncoupling proteins belong to the mitochondrial anion carrier family. In general, the uncoupling proteins dissipate the proton electrochemical gradient generated in respiration as heat, being dependent on fatty acids and sensitive to purine nucleotides. In the present study, we investigated the behavior of transgenic tobacco plants that overexpress the AtUCP1 gene when subjected to osmotic and saline stress, as well as the activity of the promoters of the AtUCP1 and AtUCP2 genes of Arabidopsis thaliana, in response to osmotic and cold stress, and abscisic acid. In the first approach, seeds from wild type and two transgenic lines were germinated in MS medium containing (or not) NaCl and mannitol. The germination test showed that the transgenic lines have a higher stress tolerance. When root growth was analyzed, a greater inhibition was observed in non-transgenic control seedlings as compared to seedlings of the two transgenic lines tested. Additionally, when subjected to stress, a greater superoxide anion accumulation was detected in leaves of non-transgenic seedlings as compared to seedlings of transgenic lines. Quantification of GUS activity in the plants transformed with the tested promoters, revealed no treatmentspecific differences / Mestre Genética vegetal. Proteinas - Analise. Alimentos geneticamente modificados. Fumo - Cultivo. Uncoupling proteins. eng Transgenic plants. eng
32	Alterações no metabolismo corporal e mitocondrial promovidas pela suplementação da dieta com ácido linoléico conjugado (CLA) e ácido oléico em camundongos / Changes in body and mitochondrial metabolism promoted by dietary supplementation with conjugated linoleic acid (CLA) and oleic acid in mice Baraldi, Flavia Guariente 31 October 2014 (has links) A obesidade é atualmente um dos problemas públicos de saúde mais visível e negligenciado. Ainda, essa condição pode causar sérios problemas de saúde como doenças cardiovasculares, diabetes, hipertensão arterial e diversos problemas fisiológicos. Dietas alimentares e/ou o uso de fármacos tem demonstrado pouca eficiência (e grandes efeitos colaterais) em reduzir a incidência de sobrepeso e obesidade no mundo. Dessa forma outras estratégias são requeridas para auxiliar no controle desta epidemia global. Nesse contexto, alguns ácidos graxos específicos podem desempenhar um importante papel na regulação da expressão de genes que possuem a habilidade de modular metabolismo. O ácido linoléico conjugado (CLA, 18:2) e o ácido oléico (18:1) tem sido descritos com propriedades anti-obesidade: a respeito de CLA, são bem conhecidos os seus efeitos adipotróficos; quanto ao oléico, são bem conhecidos os seus efeitos anti-diabetes; outros efeitos desses ácidos graxos sobre o metabolismo corporal são desconhecidos ou controversos. Dessa forma, o objetivo deste trabalho foi avaliar os efeitos da suplementação da dieta de camundongos (C57bl6) com esses dois ácidos graxos, individualmente ou em conjunto, na modulação do metabolismo corporal e mitocondrial como uma possível estratégia de combate à obesidade. Foram analisados parâmetros bioquímicos, moleculares, fisiológicos, morfológicos e funcionais. Nossos resultados demonstram que o ácido graxo indutor de aumento do gasto energético corporal e mitocondrial hepático é o CLA e não o oléico; quando suplementados em conjunto, os efeitos metabólicos do CLA se sobrepõem aos do oléico, mantendo esses metabolismos elevados. O aumento de metabolismo mitocondrial está relacionado ao aumento de expressão/atividade de proteínas desacopladoras, as quais parecem ser controladas por espécies reativas de O2 mitocondriais. Demonstramos também que no tecido adiposo branco o ácido oléico não exerce efeitos atróficos como o CLA, os quais estão relacionados a inibição da expressão de PPAR1. Por outro lado, verificamos que a suplementação conjunta com ácido oléico previne efeitos adversos da suplementação da dieta com CLA, como a hipertrofia hepática e resistência a insulina. Concluímos dessa forma que a suplementação da dieta com CLA aumenta o metabolismo corporal e mitocondrial; a suplementação com ácido oléico em conjunto não potencializa os efeitos do CLA, porém previne seus efeitos adversos como a hipertrofia hepática e resistência a insulina. Em conjunto esses ácidos graxos constituem uma boa estratégia alimentar contra o ganho de peso corporal. / Obesity is one of the major public health problems. This condition can leads to the development of other complications such as cardiovascular disease, diabetes and hypertension. Diet and/or drug treatments have shown low efficiency (and major side effects) in reducing the incidence of overweight and obesity in worldwide. On the other hand, some specific fatty acids may play an important role regulating the expression of genes that modulate the metabolism. Conjugated linoleic acid (CLA, 18:2) and oleic acid (18:1) have been known for their anti-obesity properties: CLA is well described inducer of atrophy in adipose tissue, while oleic acid is known by its anti-diabetic effects; other effects of these fatty acids on body metabolism are unknown or controversial. Therefore, the aim of this study was to evaluate the effects of a murine diet supplemented with CLA and oleic acid, individually or together, in the modulation of body and mitochondrial metabolism. Biochemical, molecular, physiological, morphological and functional parameters were analyzed in mice. Our results show that CLA, and not oleic acid, is the fatty acid inductor of increase in body metabolism and liver mitochondrial energy expenditure; when supplemented together, the metabolic effects of CLA overlap the oleic effects, maintaining the high metabolism. Increased mitochondrial metabolism is associated with an increased expression/activity of uncoupling proteins, which appear to be controlled by mitochondrial oxygen reactive species. It was also demonstrated that, in white adipose tissue, oleic acid exerts no atrophic effects as compared to CLA, which are related to inhibition of PPAR1 expression. On the other hand, we demonstrated that the supplementation with oleic acid prevents adverse effects of dietary supplementation with CLA, such as liver hypertrophy and insulin resistance in mice. In conclusion, supplementing the murine diet with CLA increases body and mitochondrial metabolism and reduces the adiposity; in addition, supplementation with oleic acid does not potentialize the metabolic effects of CLA, but prevents its adverse effects. Together CLA and oleic in conjunction appears as a good dietary strategy against the excessive weight gain. ácido oléico CLA CLA mitochondria mitocôndria oleic acid. proteína desacopladora uncoupling protein
33	Efeitos da suplementação da dieta com ácido linoleico conjugado (CLA) e óleo de peixe isolados ou em conjunto sobre o metabolismo energético mitocondrial, celular e corporal / Effects of dietary supplementation with conjugated linoleic acid (CLA) and fish oil either alone or in combination on mitochondrial, cellular and body energy metabolism Rossignoli, Camila Pederiva 07 July 2016 (has links) Atualmente no Brasil mais da metade da população adulta tem excesso de peso e 21% estão obesos. A obesidade é uma doença que se encontra em evidente crescimento, sendo considerada a epidemia do século XXI. Como alternativa de tratamento e prevenção, o uso de ácidos graxos que possuem habilidade de induzir a expressão de genes com importante papel em modulações metabólicas e mitocondriais têm sido estudados. O ácido linoleico conjugado (CLA, 18:2) é da família ômega-6, descrito por sua propriedade antiobesidade relacionada à diminuição da adiposidade e ao aumento do metabolismo corporal. O óleo de peixe (OP) é uma mistura de ácidos graxos poli-insaturados eicosapentaenóico (EPA, 20:5) e docosahexaenóico (DHA, 22:6) da família ômega-3, conhecido por aumentar a sensibilidade à insulina, o colesterol-HDL, pelas suas propriedades antiinflamatórias e sua ação protetora sobre o sistema nervoso. O objetivo deste estudo foi verificar os efeitos da suplementação da dieta de camundongos C57BL6 com CLA em conjunto com OP durante 60 dias sobre aspectos bioquímicos, moleculares e fisiológicos do metabolismo mitocondrial e corporal. Verificamos que a suplementação da dieta com CLA e OP in vivo: aumenta o metabolismo corporal, efeito atribuído à ambos os óleos; prejudica o metabolismo da glicose circulante, proporcionado exclusivamente pelo CLA; reduz o nível de movimentação, proporcionado exclusivamente pelo OP. No fígado: aumenta a expressão de UCP2, a atividade de proteínas desacopladoras e a ?- oxidação, efeito atribuído à ambos os óleos; aumenta o número de mitocôndrias, proporcionado exclusivamente pelo OP. CLA aumenta a produção de espécies reativas de O2 (EROs) a qual é revertida pelo OP em conjunto. No músculo sóleo: aumenta a biogênese mitocondrial via PGC- 1? e a expressão de UCP2, proporcionados pelo OP. Por fim, no hipocampo: aumenta o número de mitocôndrias, estimulo dado por ambos os óleos; aumenta a atividade desacopladora e reduz a produção de EROs, proporcionados exclusivamente pelo CLA. Concluímos que na suplementação conjunta os efeitos do OP são predominantes nos metabolismos corporal, hepático e muscular, e na movimentação corporal, enquanto que o efeito predominante do CLA é a diminuição na sensibilidade à insulina. Já no cérebro, o OP potencializa os efeitos do CLA. / Currently in Brazil more than a half of adult population has overweight, and 21% are obese. This evident growing disease is considered the 21th century\'s epidemy. Some fatty acids have been considered an alternative treatment and prevention strategy for obesity due to their ability to stimulate gene expression with important role in cellular and mitochondrial metabolisms. Conjugated linoleic acid (CLA, 18:2) from omega-6 family, with anti-obesity properties related to diminution of adiposity and increments in body metabolism. The fish oil (FO) is a mixture of the poli-unsaturated fatty acids eicosapentaenoic (EPA, 20:5) and docosahexaenoic (DHA, 22:6) from omega-3 family, known for improving insulin sensibility and HDL-cholesterol, anti-inflammatory properties and protective action over the central nervous system. The objective of this study was to examine the effects of dietary supplementation of CLA in conjunction with FO during 60 days over biochemical, molecular and physiological aspects of mitochondrial and body metabolism in C57BL6 mice. Diet supplementation with CLA and FO in vivo: raise body metabolism, an effect attributed to both oils; affect glucose metabolism, exclusively proportionate by CLA; diminish the level of mice movement, exclusively proportionate by FO. In liver: increase UCP2 expression, uncoupling proteins activity and ?-oxidation, stimulated by both oils; increase mitochondrial density, exclusively proportionate by FO. CLA also raises the reactive oxygen species (ROS) production, which is reversed by FO in conjunction. In soleus muscle: increase mitochondrial biogenesis through PGC-1? and the UCP2 expression, exclusively proportionate by FO. Lastly, in hippocampus: increase mitochondrial density, stimulated by both oils; stimulate uncoupling activity and diminish ROS production, exclusively proportionate by CLA. In conclusion, in the dietary supplementation with CLA and FO in conjunction the FO effects are prevalent in metabolisms of body, liver and muscle, and in body movement, while the CLA effects are prevalent in decreasing insulin sensitivity. However in the brain, the FO potentiates the effects of CLA. Ácido linoleico conjugado Biogênese Biogenesis Conjugated linoleic acid Desacoplamento Fish oil Mitochondria Mitocôndria Óleo de peixe Uncoupling
34	Perfil de expressÃo e anÃlise filogenÃtica dos genes da proteÃna desacopladora mitocondrial durante o desenvolvimento e estresse em soja [Glycine max (L.) Merr.] / Expression and Analysis of phylogenetic profile of genes of mitochondrial uncoupling protein during development and stress in soybean [Glycine max (L.) Merr.] AntÃnio Edson Rocha Oliveira 30 April 2015 (has links) CoordenaÃÃo de AperfeÃoamento de Pessoal de NÃvel Superior / Diversos estudos tÃm evidenciado que a principal funÃÃo da proteÃna desacopladora mitocondrial de plantas (pUCP) estÃ relacionada a regulaÃÃo de espÃcies reativas de oxigÃnio (EROs). AnÃlises in silico sugerem a existÃncia de famÃlias multigÃnicas para a codificaÃÃo de pUCPs, porÃm novos estudos ainda sÃo necessÃrios para estabelecer o perfil de expressÃo gÃnica das pUCPs, assim como a quantidade de genes em cada espÃcie e suas relaÃÃes filogenÃticas. O presente trabalho teve como objetivo caracterizar, analisar filogeneticamente e avaliar o perfil de expressÃo da famÃlia multigÃnica da pUCP em diferentes tecidos durante o desenvolvimento da soja [Glycine max (L.) MERR.] e em condiÃÃes de estresse. Foi realizada uma anÃlise in silico no genoma da soja e de outras leguminosas disponÃveis no banco de dados WGS, revelando uma famÃlia multigÃnica codificadora da pUCP, UCP1 e 2 com nove Ãxons, UCP 3 com 2 Ãxons, e UCP 4 e 5 com apenas um Ãxon. Dentre as leguminosas analisadas a soja se destacou com o maior nÃmero de genes, 10 genes no total, sendo quatro genes GmUCP1, uma GmUCP2, uma GmUCP3, dois GmUCP4 e dois GmUCP5, alÃm da presenÃa de um splicing alternativo no gene GmUCP1b1. Primers especÃficos foram desenhados para cada membro da GmUCP a fim de analisar os perfis de expressÃo em diferentes tecidos (semente seca e embebida, flores, vagens, cotilÃdones, folhas unifolioladas e trifolioladas, raÃzes, hipocÃtilos e epicÃtilos) durante o desenvolvimento da soja. Para os ensaios em condiÃÃes de estresse foram utilizadas folhas e raÃzes de soja com treze dias apÃs a semeadura (DAS) que foram submetidas a estresse osmÃtico promovido pela aplicaÃÃo de polietileno glicol (PEG) e estresse biÃtico atravÃs de Ãcido salicÃlico (AS). O RNA total de cada amostra foi extraÃdo para a realizaÃÃo de RT-qPCR. Os valores de ct foram obtidos pelo programa realplex e analisados pelo programa GeNorm. O perfil de expressÃo gÃnica mostrou que todos os genes GmUCP foram expressos em todos os tecidos/ÃrgÃos analisados durante o desenvolvimento da soja, com exceÃÃo de alguns genes em semente seca e epicÃtilo. Os diferentes perfis de expressÃo de cada gene durante o desenvolvimento de cada tecido/ÃrgÃo sugerem que ocorra uma regulaÃÃo gÃnica espacial/temporal entre os membros da GmUCP. Os perfis de expressÃo dos genes GmUCP em soja durante as condiÃÃes de estresses foi diversificado, visto que 2 genes apresentaram expressÃo estÃvel em ambos tecidos/estresse, 7 genes apresentaram queda do perfil de expressÃo, enquanto apenas 4 genes apresentaram aumento dos nÃveis de transcritos. / Several studies have evidenced that the main function of the mitochondrial uncoupling protein in plants (pUCP) is related to reactive oxygen species (ROS) regulation. In silico analysis suggests the existence of multigenic families to pUCPs codification, however further studies are yet needed to establish the pUCPs genetic expression profile, just like the gene amount in each species and their phylogenetic relations. The current work had as objective to characterize, analyze phylogeneticly and evaluate the expression profile of the pUCP multigenic family in different tissues during the soybean development [Glycine max (L.) MERR.] and in stress conditions. It has been performed an in silico analysis on the soybean genome and on other legumes available in the database WGS, revealing a codifier multigenic family for pUCP, UCP1 and 2 with 9 exons, UCP3 with 2 exons, and UCP4 and 5 with only 1 exon. Amongst the legumes analyzed, the soybean stood out with the greater number of genes, 10 genes in total, giving four GmUCP1 genes, one GmUCP2, one GmUCP3, two GmUCP4 and two GmUCP5, along with the presence of an alternative splicing on GmUCP1b1 gene. Specific primers have been designed for each GmUCP member in order to analize the expression profiles in different tissues (dry and doused seed, flowers, pods, cotyledons, unifoliate and trifoliate leaves, roots, hypocotyl and epicotyl) during the soybean development. For the assays in stress conditions have been used soybean leaves and roots with thirteen days after sowing (DAS) which have been subjected to osmotic stress caused by the application of polyethylene glycol (PEG) and biotic stress caused by salicylic acid (SA). The total RNA from each sample has been extracted in order to perform the RT-qPCR. The ct values have been obtained through the realplex program and analyzed through the GeNorm program. The genetic expression profile has shown that all genes were expressed in every tissue/organ analyzed during the soybean development, with the exception on some genes in dry seeds and epicotyl. The different expression profiles of each gene during the development of each tissue/organ suggest that occurs a spatial/temporal gene regulation among the GmUCP members. The expression profiles of the GmUCP genes in soybean during the stress conditions have varied, once 2 genes have shown steady expression in both tissues/ stress, 7 genes have shown a drop in the expression profile, while only 4 genes have shown an increase of the transcript levels. ProteÃna desacopladora mitocondrial ExpressÃo gÃnica AnÃlise in silico Uncoupling protein Gene expression In silico analysis BIOQUIMICA
35	Limiting factors in ATP synthesis Kramarova, Tatiana January 2006 (has links) <p>The aim of the present study was to investigate the biosynthesis of the ATP synthase in various tissues, and to test hypotheses about possible models of activation of several mitochondrial proteins, the ATP/ADP translocase and UCPs, that could utilize the proton gradient, thus bypassing the ATP synthase. </p><p>We have examined the role of the expression of the P1 isoform of the c-F<sub>o</sub> subunit in the biogenesis of ATP synthase in brown adipose tissue. Our findings point to a role for the c-F<sub>o</sub> subunit in defining the final content of the ATP synthase in brown adipose tissue.</p><p>We have analyzed sequences in the 3’UTR of the β subunit F<sub>1</sub>-ATPase mRNA that are important for formation of RNA-protein complexes. We could detect protein complexes that bind to two different sequence regions of the 3’UTR, one being the poly(A) tail and an adjacent region), and the other being a sequence stretch at the 3’ end of the 3’UTR able to form a stem-loop structure, which is evolutionarily conserved throughout mammalian species. </p><p>We investigated a role of the ATP/ADP carrier (ANT) in fatty acid-induced uncoupling in brown-fat mitochondria. We conclude that the ANT cannot substitute for UCP1 in fatty acid uncoupling in brown-fat mitochondria from mice lacking UCP1. We propose that the two ANT isoforms mediate proton translocation under different conditions.</p><p>We have investigated a role of UCP1 in defence against oxidative stress. We found that products of oxidative stress (4-HNE) could neither reactivate purine nucleotide-inhibited UCP1, nor induce additional activation of innately active UCP1 in brown-fat mitochondria from UCP1(+/+) and UCP1(-/-) mice. We conclude that UCP1 is not involved in defence against oxidative stress. </p><p>We evaluated possible uncoupling activity of UCP3 in skeletal muscle from warm- and cold-acclimated UCP1(+/+) and UCP1(-/-) mice. We conclude that no evidence exists for a higher UCP3-mediated uncoupling activity; a high UCP3 content in cold-acclimated UCP1(-/-) mice could possibly be linked to improved fatty acid oxidative capacity.</p> ATP synthase biosynthesis assembly uncoupling proteins ATP/ADP carrier Physiology Fysiologi
36	Limiting factors in ATP synthesis Kramarova, Tatiana January 2006 (has links) The aim of the present study was to investigate the biosynthesis of the ATP synthase in various tissues, and to test hypotheses about possible models of activation of several mitochondrial proteins, the ATP/ADP translocase and UCPs, that could utilize the proton gradient, thus bypassing the ATP synthase. We have examined the role of the expression of the P1 isoform of the c-Fo subunit in the biogenesis of ATP synthase in brown adipose tissue. Our findings point to a role for the c-Fo subunit in defining the final content of the ATP synthase in brown adipose tissue. We have analyzed sequences in the 3’UTR of the β subunit F1-ATPase mRNA that are important for formation of RNA-protein complexes. We could detect protein complexes that bind to two different sequence regions of the 3’UTR, one being the poly(A) tail and an adjacent region), and the other being a sequence stretch at the 3’ end of the 3’UTR able to form a stem-loop structure, which is evolutionarily conserved throughout mammalian species. We investigated a role of the ATP/ADP carrier (ANT) in fatty acid-induced uncoupling in brown-fat mitochondria. We conclude that the ANT cannot substitute for UCP1 in fatty acid uncoupling in brown-fat mitochondria from mice lacking UCP1. We propose that the two ANT isoforms mediate proton translocation under different conditions. We have investigated a role of UCP1 in defence against oxidative stress. We found that products of oxidative stress (4-HNE) could neither reactivate purine nucleotide-inhibited UCP1, nor induce additional activation of innately active UCP1 in brown-fat mitochondria from UCP1(+/+) and UCP1(-/-) mice. We conclude that UCP1 is not involved in defence against oxidative stress. We evaluated possible uncoupling activity of UCP3 in skeletal muscle from warm- and cold-acclimated UCP1(+/+) and UCP1(-/-) mice. We conclude that no evidence exists for a higher UCP3-mediated uncoupling activity; a high UCP3 content in cold-acclimated UCP1(-/-) mice could possibly be linked to improved fatty acid oxidative capacity. ATP synthase biosynthesis assembly uncoupling proteins ATP/ADP carrier Physiology Fysiologi
37	Uncoupling Protein-2 Modulation of Reactive Oxygen Species and Cell Viability in the Pancreatic Beta Cell Lee, Simon 30 July 2008 (has links) Uncoupling protein-2 (UCP2) may be linked to the attenuation of reactive oxygen species (ROS), but it is unclear whether this phenomenon pertains to the pancreatic beta cell. In this study, a UCP2-deficient mouse model was used to assess the importance of UCP2 to beta cell viability. We investigated the effect of UCP2 absence in response to a beta cell cytotoxic model of diabetes induction. In vivo treatment by the cytotoxic agent streptozotocin led to overall beta cell loss, but severity was not exacerbated by UCP2 deficiency. We also examined ROS production and cell viability in islet cells exposed to various stressors associated with oxidative stress. In vitro measurements of ROS and cell death in islet cells demonstrated that the response was not influenced by UCP2 expression. In contrast with UCP2 overexpression studies showing cytoprotection, this study reveals that beta cell survival is not compromised by the absence of UCP2. uncoupling protein-2 diabetes beta cell reactive oxygen species oxidative stress cell viability 0719
38	Uncoupling Protein-2 Modulation of Reactive Oxygen Species and Cell Viability in the Pancreatic Beta Cell Lee, Simon 30 July 2008 (has links) Uncoupling protein-2 (UCP2) may be linked to the attenuation of reactive oxygen species (ROS), but it is unclear whether this phenomenon pertains to the pancreatic beta cell. In this study, a UCP2-deficient mouse model was used to assess the importance of UCP2 to beta cell viability. We investigated the effect of UCP2 absence in response to a beta cell cytotoxic model of diabetes induction. In vivo treatment by the cytotoxic agent streptozotocin led to overall beta cell loss, but severity was not exacerbated by UCP2 deficiency. We also examined ROS production and cell viability in islet cells exposed to various stressors associated with oxidative stress. In vitro measurements of ROS and cell death in islet cells demonstrated that the response was not influenced by UCP2 expression. In contrast with UCP2 overexpression studies showing cytoprotection, this study reveals that beta cell survival is not compromised by the absence of UCP2. uncoupling protein-2 diabetes beta cell reactive oxygen species oxidative stress cell viability 0719
39	Mitochondrial uncoupling protein 3 blocks skin carcinogenesis and drives bulge stem cell differentiation and epidermal turnover Lago, Cory Ungles 09 August 2012 (has links) Malignant cells increase glycolysis and down regulate mitochondrial respiration for ATP production. Mechanisms for respiratory impairment in cancerous cells and their importance for carcinogenesis are not well defined. We found that expression of the respiration-inducing uncoupling protein 3 (UCP3) was normally expressed in murine skin and was greatly decreased in cutaneous malignancies. To better understand the significance of UCP3 in epidermal biology and to test the importance of respiratory changes in cancer development, we generated hemizygous mice expressing a keratin-5 promoter-UCP3 transgene (K5-UCP3). Compared to wild type, K5-UCP3 mice exhibited increased cutaneous mitochondrial respiration, had decreased mitochondrial membrane potential in isolated keratinocytes, and were completely resistant to chemically-induced skin carcinogenesis. We showed that the mechanism of UCP3-dependent cancer protection is most likely not due to increased intracellular heat production or ATP depletion in pre-cancerous cells. Therefore, because hair follicle "bulge" stem cells (bSC) are K5⁺ and progenitors of cutaneous carcinomas, we hypothesized that K5-UCP3 animals were protected from skin carcinogenesis due to alterations in their bSC population. Unlike WT, most (85%) hair follicle bulge regions in K5-UCP3 mice lost biochemical markers of quiescent bSC, but bSC functions were fully intact. Supporting our hypothesis that increased skin turnover protected K5-UCP3 mice from skin cancer; we showed that basal keratinocyte cell cycling was increased 3% in K5-UCP3 skin compared to WT. Moreover, the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) induced similar proliferative responses in both WT and K5-UCP3 skin, but the magnitude of TPA-induced skin thickening was greatly decreased in K5-UCP3 versus WT mice. Together with microarray, histochemical and in vitro morphologic analyses showing that keratinocyte differentiation was sharply increased in K5-UCP3 skin, this implies that UCP3 may increase keratinocyte transit from stem to differentiated daughter cells. Thus, the cancer resistance mechanism in K5-UCP3 mice likely stems from UCP3-induced mitochondrial respiration, which promotes the differentiation and abrogates the tumorigenicity of progenitor keratinocytes. This is the first demonstration in any context that UCP3 blocks carcinogenesis and promotes cellular differentiation. These observations support Warburg's contention that respiratory dysfunction promotes cancer development, and suggest that mitochondrial uncoupling may be a novel target for cancer prevention and treatment. / text Uncoupling protein 3 UCP3 Skin carcinogenesis Mitochondrial Skin cancer Epidermal turnover
40	Mechanisms of Methylglyoxal-elicited Leukocyte Recruitment 2014 June 1900 (has links) Methylglyoxal (MG) is a reactive dicarbonyl metabolite formed during glucose, protein and fatty acid metabolism. In hyperglycemic conditions, an increased MG level has been linked to the development of diabetes and the accompanying vascular inflammation encountered at both macro- and microvascular levels. The present study explores the mechanisms of MG-induced leukocyte recruitment in mouse cremasteric microvasculature. Biochemical and intravital microscopy studies performed suggest that administration of MG (25 and 50 mg/kg) to mouse cremaster muscle tissue induces dose-dependent leukocyte recruitment in cremasteric vasculature with 84-92% recruited cells being neutrophils. MG treatment up-regulated the expression of endothelial cell (EC) adhesion molecules P-selectin, E-selectin and intercellular adhesion molecule-1 (ICAM-1) via the activation of nuclear factor-κB (NF-κB) signalling pathway and contributed to the increased leukocyte rolling flux, reduced leukocyte rolling velocity, and increased leukocyte adhesion, respectively. The inhibition of NF-κB blunted MG-induced endothelial adhesion molecule expression and thus attenuated leukocyte recruitment. Further study of signalling pathways revealed that MG induced Akt-regulated transient glycogen synthase kinase 3 (GSK3) activation in ECs, which was responsible for NF-κB activation at early time-points (< 1 h). After MG activation for 1 h, the endothelial GSK3 activity was decreased due to the up-regulation of serum- and glucocorticoid-regulated kinase 1 (SGK1), which was responsible for maintaining NF-κB activity at later time-points. Silencing GSK3 or SGK1 attenuated P-selectin, E-selectin and ICAM-1 expression in ECs, and abated MG-induced leukocyte recruitment. SGK1 also promoted cyclic adenosine monophosphate (cAMP) response element-binding protein (CREB) activity which was partially involved in ICAM-1 expression. Silencing CREB blunted ICAM-1 expression while P-selectin and E-selectin levels remained unaffected. MG also induced GSK3 activation in isolated neutrophils after 30 min treatment, an effect that was not responsible for MG-elicited Mac-1 expression. These data suggest the sequential activation of GSK3 and SGK1 in ECs as the pivotal signalling mechanism in MG-elicited leukocyte recruitment. Additionally, MG-treatment led to uncoupling of endothelial nitric oxide synthase (eNOS) following MG-induced superoxide generation in ECs. MG triggered eNOS uncoupling and hypophosphorylation associated with superoxide generation and biopterin depletion in EA.hy926 ECs. In cremaster muscle, as well as in cultured murine and human primary ECs, MG increased eNOS monomerization and decreased 5,6,7,8-tetrahydroboipterin (BH4)/total biopterin ratio, effects that were significantly mitigated by supplementation of BH4 or its precursor sepiapterin but not by NG-nitro-L-arginine methyl ester (L-NAME) or 5,6,7,8-tetrahydroneopterin (NH4). These observations confirm that MG administration triggers eNOS uncoupling. In murine cremaster muscle, MG triggered the reduction of leukocyte rolling velocity and the increases in rolling flux, adhesion, emigration and microvascular permeability. MG-induced leukocyte recruitment was significantly attenuated by supplementation of BH4 or sepiapterin or suppression of superoxide by L-NAME confirming the role of eNOS uncoupling in MG-elicited leukocyte recruitment. MG treatment further decreased the expression of guanosine triphosphate cyclohydrolase I in murine primary ECs, suggesting the impaired BH4 biosynthesis caused by MG. Taken together, these data suggest that vascular inflammation and endothelial dysfunction occurring in diabetes may be linked to GSK3/SGK1 regulated adhesion molecule expression, as well as the uncoupling of eNOS evoked by elevated levels of MG. These findings not only provide a better understanding of the role of MG in the development of diabetic vascular inflammation, but also suggest the potential therapeutic targets for MG-sensitive endothelial dysfunction in diabetes. Methylglyoxal Leukocyte recruitment Endothelial cell GSK3 SGK1 eNOS uncoupling NF-kB

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