Global ETD Search

51	Enzymatic and structural studies of glutathione S-transferases of white-rot fungus Ceriporiopsis subvermispora which is a selective degrader of lignin in woody biomass / 木質バイオマス中のリグニンを選択的に分解する白色腐朽菌Ceriporiopsis subvermisporaのグルタチオンS-トランスフェラーゼに関する酵素学的および構造学的研究 WAN, HASNIDAH BINTI WAN OSMAN 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第21885号 / エネ博第386号 / 新制\|\|エネ\|\|75(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授片平正人, 教授森井孝, 教授木下正弘 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM Ceriporiopsis subvermispora glutathione S-transferases woody biomass enzyme kinetics crystal structure 501
52	Tuning the Substrate Specificity of the Glutathione Transferase GstB from <i>Escherichia coli</i> via Site-directed Mutagenesis Moore, Jennifer Marie 17 August 2017 (has links) No description available. Biochemistry Chemistry Microbiology Glutathione glutathione transferases site-directed mutagenesis bioremediation bromoacetate
53	Crystallographic characterization of the ribosomal binding site and molecular mechanism of action of Hygromycin A. Kaminishi, Tatsuya, Schedlbauer, Andreas, Fabbretti, Attilio, Brandi, Letizia, Ochoa Lizarralde, Borja, He, Cheng-Guang, Milon, Pohl, Connell, Sean R, Gualerzi, Claudio O, Fucini, Paola 16 November 2015 (has links) Hygromycin A (HygA) binds to the large ribosomal subunit and inhibits its peptidyl transferase (PT) activity. The presented structural and biochemical data indicate that HygA does not interfere with the initial binding of aminoacyl-tRNA to the A site, but prevents its subsequent adjustment such that it fails to act as a substrate in the PT reaction. Structurally we demonstrate that HygA binds within the peptidyl transferase center (PTC) and induces a unique conformation. Specifically in its ribosomal binding site HygA would overlap and clash with aminoacyl-A76 ribose moiety and, therefore, its primary mode of action involves sterically restricting access of the incoming aminoacyl-tRNA to the PTC. / Bizkaia:Talent and the European Union's Seventh Framework Program (Marie Curie Actions; COFUND; to S.C., A.S., T.K.); Marie Curie Actions Career Integration Grant (PCIG14-GA-2013-632072 to P.F.); Ministerio de Economía Y Competitividad (CTQ2014-55907-R to P.F., S.C.); FIRB Futuro in Ricerca from the Italian Ministero dell'Istruzione, dell'Universitá e della Ricerca (RBFR130VS5_001 to A.F.); Peruvian Programa Nacional de Innovación para la Competitividad y Productividad (382-PNICP-PIBA-2014 (to P.M. and A.F.)). Funding for open access charge: Institutional funding. / Revisión por pares Binding Sites Cinnamates X-Ray Crystallography Hygromycin B Models Molecular Peptidyl Transferases Ribosome Subunits RNA Binding Sites Cinnamates Crystallography, X-Ray Hygromycin B Models, Molecular Peptidyl Transferases Protein Synthesis Inhibitors RNA, Transfer, Amino Acyl Ribosome Subunits, Large, Bacterial
54	Diversité écologique et fonctionnelle des champignons décomposeurs du bois : l'influence du substrat de la communauté à l'enzyme / Ecological and functional diversity of wood decomposing fungi : substrate influence from community to enzyme Mathieu, Yann 11 December 2012 (has links) Les champignons saprophytes sont les acteurs principaux du recyclage de la matière organique morte au sein des écosystèmes forestiers. Ces microorganismes possèdent la capacité unique de dégrader la totalité des polymères constitutifs du bois. L'analyse de la structuration des communautés durant les stades initiaux de la colonisation du bois par séquençage à haut débit a révélé que celui-ci influence la distribution et la dynamique des communautés qui lui sont associées. A l'échelle de l'organisme, les différents groupes écologiques de champignons décomposeurs du bois possèdent des systèmes de dégradation extracellulaires reflétant cette complexité chimique. Le séquençage du génome d'un grand nombre de ces organismes a permis l'identification de superfamilles d'enzymes impliquées dans les mécanismes de résistance et de détoxication des composés toxiques exogènes. Parmi elles, la superfamille des glutathion transférases présente une extension de classes spécifiques au sein des champignons décomposeurs du bois. La détermination des propriétés biochimiques et structurales d'une isoforme, issue d'une de ces classes spécifique (les Etherase-like), présente chez Phanerochaete chrysosporium a révélé des caractéristiques particulières. Cette enzyme possède un mode de dimérisation atypique ainsi que la capacité à séquestrer des composés phénoliques toxiques via une propriété ligandine unique. La comparaison des propriétés de plusieurs isoformes de cette classe d'enzymes appartenant aux champignons C. cinereus et P. chrysosporium a démontré que celle-ci exhibe une grande versatilité intra- et interspécifique, de leurs activités enzymatiques et de leur propriété ligandine / Saprophytic fungi are key players of dead organic matter recycling in forest ecosystems. These microorganisms possess the unique ability to degrade the integrality of wood constitutive polymers by secretion of complex oxydative and hydrolytic enzymatic systems. Communities structuration analysis during the initial stages of wood colonisation by high throughput sequencing revealed that the latter beyond being a source of nutrients, influences the distribution and dynamic of communities by its broad chemical variability. At the organism level, the different ecological groups of wood decomposing fungi possess extracellular degradation systems reflecting this chemical complexity. Genome sequencing of these organisms allowed the identification of enzymes superfamilies involved in resistance and detoxification mechanisms towards exogenous toxic compounds. Among them, the glutathione transferases superfamily exhibit extension of specific classes in wood decaying basidiomycetes. Biochemical and structural properties determination of one isoform belonging to one of these specific classes (the Etherase-like), found in Phanerochaete chrysosporium revealed unusual characteristics. This enzyme possesses an atypical dimerization mode as well as the ability to sequestrate toxic phenolic compounds resulting from wood degradation through a unique ligandin property. Properties comparison of several isoforms from this class belonging to C. cinereus and P.chrysosporium demonstrated a huge intra- and interspecific versatility of their enzymatics activities and ligandin property in response to environmental constraints arising from the great chemical heterogeneity of wood composition Champignons saprophytes Glutathion transférases Xénobiotiques Enzymes extracellulaires Communautés Saprophytic fungi Glutathione transferases Xenobiotics Extracellular enzymes Communities 579.6
55	Diversité fonctionelle des Glutation Transférases fongiques : caractérisation des classes Ure2p et GTT2 de Phanerochaete chrysosporium / Functional diversification of fungal Glutathione Transferases : characterization of Ure2p and GTT2 classes from Phanerochaete chrysosporium Thuillier, Anne 31 October 2013 (has links) Phanerochaete chrysosporium est un champignon forestier faisant partie des organismes saprophytes capables de recycler la matière organique morte. Grâce à l'excrétion de nombreuses enzymes de dégradation, en particulier des lignine peroxydases, il est capable de décomposer la matière végétale dont la lignine, un polymère complexe de composés phénoliques très résistant. L'élimination de la lignine permet la libération des autres composants du bois tels que la cellulose et l'hémicellulose qui peuvent être utilisés dans l'industrie papetière ou pour la production de bioéthanol de deuxième génération. La structure des intermédiaires et produits de dégradation de la lignine est souvent proche de celle denombreux polluants, d'où l'intérêt biotechnologique de P. chrysosporium dans les processus de bioremédiation. Cependant, les systèmes de dégradation engendrent des composés plus ou moins toxiques pour le champignon et contre lesquels il doit faire face. C'est pourquoi il possède un système de détoxication impliquant des enzymes telles que les cytochrome P450 monooxygénases ou encore les glutathion transférases (GST). Les Ure2p forment une classe de GST étendue chez Phanerochaete et d'autres basidiomycètes saprophytes. Leur étude par des approches phylogénétiques, biochimiques, structurales et transcriptomiques a permis de mieux comprendre les mécanismes d'évolution que peut subir une classe d'enzymes potentiellement soumises à une forte pression de sélection / Phanerochaete chrysosporium is a forest fungus being part of saprophytic organisms able to recycle dead organic matter. Thanks to the excretion of numerous wood decaying enzymes, and especially lignin peroxidases, this fungus is able to break down plant material including lignin, a complex polymer of phenolic compounds. Lignin removal allows the release of other wood components such as cellulose and hemicellulose, which can be further used in paper industry or to produce second generation bioethanol. The structure of intermediates and products from lignin decomposition is close to that of numerous pollutants making P. chrysosporium biotechnologically interesting for bioremediation purposes. Moreover, the fungus has to deal with more or less toxic compounds created by degradation mechanisms. It thus presents a detoxification pathway involving enzymes including cytochrome P450 monooxygenases and glutathione transferases (GST). Ure2p enzymes belong to an extended GST class in Phanerochaete genus as well as in other saprophytic basidiomycetes. Their study based on phylogenetic, biochemical, structural and transcriptomic approaches provides a better understanding of evolution mechanisms of a class of enzymes potentially subject to strong selection selection pressure Champignons saprophytes Dégradation du bois Glutathion transférases Xénobiotiques Détoxication Évolution Saprophytic fungi Wood degradation Glutathione transferases Xenobiotics Detoxification Evolution 579.5 572.792
56	Melatonina, isoenzimas de glutationa S-transferases e estresse oxidante em pacu Piaractus mesopotamicus (Holmberg, 1887) / Melatonin, Glutathione S-transferases isoenzymes, and oxidative stress in pacu, Piaractus mesopotamicus (Holmberg, 1887). Frederico Freire Bastos 08 March 2010 (has links) Conselho Nacional de Desenvolvimento Científico e Tecnológico / O oxigênio é fundamental para os vertebrados. No entanto, variações dos níveis de oxigênio na água podem provocar estresse oxidante em peixes porque privação de oxigênio seguida de reoxigenação forma espécies reativas de oxigênio (ERO) em células. Níveis intracelulares de ERO aumentados favorecem que moléculas de proteínas, fosfolipídios e ácidos nucleicos sofram alterações, vindo a prejudicar muitas funções celulares. No Pantanal, habitat do pacu, o nível de oxigênio varia circadianamente na água das lagoas rasas que acabam isoladas dos rios na seca. O pacu evoluiu sob a pressão contínua da exposição aos efeitos prejudiciais das ERO causados pelos pulsos de inundação. A melatonina, uma indolamina produzida na glândula pineal, influencia os níveis de atividade de enzimas antioxidantes que reduzem ERO, além de ser capaz de doar elétrons ou captar radicais livres de forma não enzimática. Os níveis de melatonina no pacu são mais altos no verão e menores no inverno. Isoenzimas de glutationa S-transferases que conjugam o tripetídeo glutationa com o 4-hidroxinonenal, aldeído derivado da peroxidação de ácidos graxos por ERO, são importantes para evitar alteração funcional de proteínas por ligação do 4-hidroxinonenal à sua estrutura. Neste trabalho procuramos relação entre estresse oxidante, níveis de atividades de glutationa S-transferase e melatonina, para estabelecer se a melatonina ajudaria pacus a superar os efeitos deletérios das espécies reativas de oxigênio. Ensaiamos atividades de isoenzimas de glutationa S-transferases no citosol de fígado de pacus mantidos em normoxia, hipoxia, reoxigenação e hiperoxia no inverno e no verão. Medimos o efeito da melatonina in vitro e in vivo sobre as atividades de isoenzimas de glutationa S-transferase. Medimos os efeitos do estresse oxidante sobre a ligação do 4-hidroxinonenal com proteínas nos fígados de pacus tratados com melatonina. Somente as isoenzimas que conjugam 4-hidroxinonenal com glutationa mostraram menor atividade no inverno em relação ao verão; outras isoenzimas de glutationa S-transferases não alteram suas atividades sazonalmente. In vitro a melatonina não alterou a atividade de isoenzimas de glutationa S-transferase que conjugam o 4-hidroxinonenal, mas inibiu outras isoenzimas de glutationa S-transferase. In vivo a melatonina aumentou a atividade encontrada no inverno das isoenzimas que conjugam o 4-hidroxinonenal para os níveis do verão. A ligação de 4-hidroxinonenal com proteínas foi menor em pacus inoculados com melatonina. Nossos resultados mostram que a melatonina pode influenciar os efeitos de ERO em fígado de pacus. Ficou claro que a melatonina do plasma mantém os níveis de atividade conjugadora de 4-hidroxinonenal do fígado em pacus e que a baixa produção de melatonina no inverno não é adequada para a conjugação do 4-hidroxinonenal em fígado de pacus. / Oxygen is vital for vertebrates. However, changes in the levels of dissolved oxygen in water might cause oxidative stress in fishes because the shortage of oxygen followed by reoxygenation originates reactive oxygen species (ROS) inside cells. Higher intracellular levels of ROS favor alterations of proteins, phospholipids and nucleic acid molecules, which result in impairment of many cell functions. In Pantanal, the pacus habitat, circadian variation of the oxygen levels occurs in water of the shallow lagoons that ended up isolated from the rivers along the dry season. Pacu has evolved under the pressure of continuous exposition to harmful effects of ROS caused by the annual inundation pulses. Melatonin, an indolamine produced by the pineal gland, influences the levels of activity of antioxidant enzymes that reduce ROS, and is capable of donating electrons or scavenge free radicals nonenzymatically. Pacus melatonin levels are higher during summer than in winter. Glutathione S-transferases isoenzymes that catalyze the conjugation of the tripeptide glutathione with 4-hydroxynonenal, an aldehyde derived from peroxidation of fat acids by ROS, are important to avoid functional alterations of proteins consequential to the binding of 4-hydroxynonenal to their structures. In this work, we searched for facts that linked oxidative stress, levels of activity of glutathione S-transferase and melatonin, in order to establish whether melatonin could help pacus to overcome the pernicious effects of reactive oxygen species. We carried out assays of glutathione S-transferases in liver cytosol of pacus kept under normoxia, hypoxia, reoxygenation and hyperoxia, in the summer and in the winter. We measured the effect of melatonin in vitro and in vivo on isoenzymes of glutathione S-transferases. We measured the effects of oxidative stress on the binding of 4-hydroxynonenal to proteins in liver of pacu treated with melatonin. Only isoenzymes that conjugate 4-hydroxynonenal with glutathione showed less activity during the winter in comparison to the summer; other isoenzymes did not have their activities changed seasonally. In vitro, melatonin did not change the activity of glutathione S-transferases isoenzymes that conjugate 4-hydroxynonenal, but inhibited other isoenzymes of glutathione S-transferase. In vivo, melatonin enhanced the liver activity of the glutathione S-transferase that conjugate 4-hydroxynonenal found in winter up to the levels found in summer. The binding of 4-hydroxynonenal to proteins was lower in liver cytosol from pacus injected with melatonin. Our findings show that melatonin can influence the effects of ROS in liver of pacu. It became evident that plasma melatonin maintains the liver levels of the conjugating activity of 4-hydroxynonenal and that the lower production of melatonin during winter is not adequate to the conjugation of 4-hydroxynonenal. Pacu Estresse oxidante Melatonina Glutationa S-transferase Piaractus mesopotamicus Piaractus mesopotamicus Melatonin Glutathione S-transferases Oxidative stress Pacu ENZIMOLOGIA
57	Análise de polimorfismos dos genes de enzimas de metabolização de detoxificação em doenças inflamatórias crônicas Rech, Tássia Flores January 2013 (has links) A doença inflamatória intestinal (DII) e a esclerose sistêmica (ES) são doenças inflamatórias crônicas de difícil diagnóstico e tratamento. A etiologia da DII e da ES ainda não é completamente compreendida, mas sabe-se que fatores genéticos, imunológicos e ambientais estão envolvidos na sua patogênese. A DII possui dois principais subtipos clínicos: a doença de Crohn (DC) e a retocolite ulcerativa (RCU), caracterizados pela inflamação do intestino delgado e/ou cólon. Evidências sugerem que o aumento do estresse oxidativo desempenha um papel importante na fisiopatologia da DII. A ES é uma doença inflamatória autoimune rara, caracterizada pela fibrose progressiva da pele e de órgãos internos. A hipótese de que o aumento do dano oxidativo pode iniciar o dano vascular e desencadear os eventos patológicos observados na ES vem sendo investigada. Genes e enzimas envolvidos na metabolização (Fase I) e detoxificação (Fase II) de xenobióticos são utilizados como marcadores de susceptibilidade para o desenvolvimento de doenças que possuem fatores ambientais como fatores de risco. Em uma reação de Fase I, as enzimas do Citocromo P450 (CYP) inserem um átomo de oxigênio em um substrato deixando-o eletrofílico e reativo, criando um sítio para posterior conjugação pelas enzimas de Fase II. As enzimas Glutationa S-tranferases (GST) de Fase II catalisam a conjugação da glutationa com uma grande variedade de compostos eletrofílicos, detoxificando substâncias endógenas e exógenas. A atividade catalítica aumentada das enzimas CYP, bem como a falha na detoxificação de metabólitos pelas GST pode contribuir para o aumento do estresse oxidativo. O objetivo deste estudo foi investigar o papel de polimorfismos nos genes que codificam enzimas de metabolização (CYP1A2C e CYP2E15B) e detoxificação (GSTT1 nulo, GSTM1 nulo e GSTP1 Ile105Val) na susceptibilidade a estas doenças. O grupo de pacientes com DII era constituído por 235 indivíduos e o grupo controle por 241 indivíduos, todos eurodescendentes. Na ES, 122 pacientes (99 eurodescendentes e 23 afrodescendentes) e 329 controles (241 eurodescendentes e 87 afrodescendentes) foram analisados. Os polimorfismos CYP foram genotipados por PCR-RFLP, enquanto que os polimorfismos em GSTT1 e GSTM1 foram genotipados por PCR multiplex e PCR-RFLP para GSTP1. As frequências alélicas e genotípicas foram comparadas entre pacientes e controles usando o teste de Qui-Quadrado. A respeito dos resultados das análises em DII, as frequências alélicas e genotípicas dos polimorfismos CYP1A12C, CYP2E15B e GSTP1 Ile105Val, bem como as frequências genotípicas do polimorfismo de presença/ausência de GSTM1, foram similares nos três grupos de pacientes (DII, DC e RCU) quando comparados ao grupo controle (P>0,05). Observouse uma frequência significativamente aumentada do genótipo nulo de GSTT1 no grupo de pacientes com DII quando comparado ao grupo controle [0,28 vs 0,18; χ² com Yates P=0,02; OR=1,71 (IC 95% 1,09 –2,71)]. Quando separamos o grupo de pacientes em DC ou RCU, esta frequência permaneceu significativamente aumentada somente no grupo de pacientes com RCU comparado ao grupo controle [0,29 vs 0,18; χ² com Yates P=0,035; OR=1,84 (IC 95% 1,03 –3,24)]. Com relação aos resultados das análises na ES, uma frequência significativamente aumentada do genótipo 1A/1A (P=0,03; 0,74 vs. 0,61) e do alelo 1A (P=0,013; 0,86 vs 0,78; OR=0,57, IC 95% 0,36–0,90) do polimorfismo CYP1A12C foi observada entre os indivíduos controles eurodescendentes. Em contrapartida, a frequência do alelo 2C estava significativamente aumentada entre os pacientes de mesma etnia (P=0,013; 0,22 vs 0,14; OR=1,75, IC 95% 1,11–2,74). Com relação às frequências alélicas e genotípicas dos polimorfismos CYP2E15B e GSTP1 Ile105Val, e as frequências genotípicas do polimorfismo de presença/ausência de GSTM1, nenhuma diferença significativa foi observada quando os grupos de pacientes de ambas as etnias foram comparados aos grupos controle (P>0,05). Uma frequência significativamente aumentada do genótipo nulo de GSTT1 [0,29 vs 0,18; χ² com Yates P=0,035; OR=1,85 (IC 95% 1,03–3,29)], bem como uma alta frequência da dupla deleção de GSTT1/GSTM1 [0,19 vs 0,08; χ² com Yates P=0,007; OR=2,62 (IC 95% 1,25 –5,46)], foi observada no grupo de pacientes comparado aos controles (eurodescendentes). Estas associações não se repetiram entre indivíduos afrodescendentes. Concluindo, nossos resultados sugerem que o genótipo nulo de GSTT1 está associado à susceptibilidade a DII e pode influenciar na definição do curso da doença para a RCU. Além disso, o genótipo nulo de GSTT1 sozinho ou em combinação com o genótipo nulo de GSTM1 é um fator genético de susceptibilidade para a ES, enquanto que o genótipo 1A/1A ou a presença do alelo 1A do polimorfismo CYP1A12C pode exercer um papel protetor contra o desenvolvimento da ES em indivíduos eurodescendentes. / Inflammatory bowel disease (IBD) and systemic sclerosis (SSc) are chronic inflammatory diseases of difficult diagnosis and treatment. The etiology of IBD and SSc is not completely understood but it is known that genetic, immunologic and environmental factors are involved in its pathogenesis. Crohn’s disease (CD) and ulcerative colitis (UC) are the two major subtypes of IBD, characterized by inflammation of the small intestine and/or colon. Evidences suggest that the increase of oxidative stress plays an important role in the pathophysiology of IBD. SSc is a rare autoimmune inflammatory disease of the connective tissue characterized by progressive fibrosis of the skin and internal organs. The hypothesis that the increase of oxidative stress can initiate vascular damage and triggers the pathological events in SSc has been investigated. Genes and enzymes involved in metabolism (Phase I) and detoxification (Phase II) of xenobiotics are used as markers of susceptibility to the development of diseases that have environmental factors as risk factors. In a Phase I reactions, the Cytochrome P450 (CYP) enzymes insert an oxygen atom in a substrate that making it more electrophilic and reactive, and creating a site for subsequent conjugation by Phase II enzymes. Phase II Glutathione S-transferases (GSTs) enzymes catalyze the conjugation of glutathione with a variety of electrophilic compounds, detoxifying endogenous and exogenous substances. A higher catalytic activity of CYP enzymes, as well as the failure in detoxifying of metabolites by GST enzymes may to contribute for the increase of oxidative stress. The aim of this study was investigated the role of polymorphisms in genes coding Phase I enzymes (CYP1A2C and CYP2E15B) and Phase II (GSTT1 null, GSTM1 null and GSTP1 Ile105Val) in susceptibility to these diseases. IBD group was constituted by 235 patients and the control group by 241 individuals, all European-derived. In SSc group, 122 patients (99 European-derived and 23 African-derived) and 329 controls (241 European-derived and 87 African-derived) were analyzed. The CYP polymorphisms were genotyped by PCR-RFLP, whereas polymorphisms in GSTM1 and GSTT1 were genotyped by multiplex PCR and PCRRFLP for GSTP1. Allelic and genotypic frequencies were compared between patients and controls using the Chi-square test. Concerning IBD, allelic and genotypic frequencies of CYP1A12C, CYP2E15B and GSTP1 Ile105Val polymorphisms, as well as genotypic frequencies of GSTM1 presence/absence polymorphism were similar in all groups patients (IBD, CD, and UC) and controls (P>0.05). We observed a significantly increased frequency of GSTT1 null genotype in IBD group as compared to controls [0.28 vs. 0.18, χ ² with Yates P=0.02, OR=1.71 (95% CI 1.09 – 2.71)]. When patients were classified in CD or UC group, this frequency remained significantly increased only among UC patients [0.29 vs. 0.18, χ ² with Yates P=0,035, OR=1.84 (95% CI 1.03 – 3.24)] as compared to controls. Regarding results in SSc, a frequency significantly increased of 1A/1A genotype (P=0.03; 0.74 vs. 0.61) and 1A allele (P=0.013; 0.86 vs 0.78; OR=0.57, 95% CI 0.36–0.90) from CYP1A12C polymorphism was observed among European-derived controls. On the other hand, the frequency of 2C allele was significantly increased among patients of same ethnic group (P=0.013; 0.22 vs 0.14; OR=1.75, 95% CI 1.11–2.74). The allelic and genotypic frequencies of CYP2E15B and GSTP1 Ile105Val polymorphisms, as well as genotypic frequencies of GSTM1 presence/absence polymorphism were similar between SSc patients and controls of both ethnic groups (P>0.05). We observed a significantly increased frequency of GSTT1 null genotype [0.29 vs. 0.18, χ ² with Yates P=0.035, OR=1.85 (95% CI 1.03–3.29)], as well as an increased frequency of GSTT1/GSTM1 double-null in SSc patients as compared to controls [0.19 vs. 0.08; χ ² with Yates P=0.007, OR=2.62 (95% CI 1.25 – 5.46)]. These associations were exclusive to European-derived individuals. In conclusion, our results suggest that the GSTT1 null genotype is associated with susceptibility to IBD and may influence in defining the course of the disease for RCU. Furthermore, the GSTT1 null genotype alone or combined with GSTM1 null genotype is a susceptibility genetic factor to SSc, while the 1A/1A genotype or the presence of 1A allele from CYP1A12C polymorphism may plays a protector role in SSc development in Brazilian Europeanderived individuals. Polimorfismo Detoxificação Esclerose sistêmica Doença inflamatória intestinal Glutationa Inflammatory bowel disease Systemic sclerosis Cytochrome P450 Glutathione S-transferases Polymorphisms
58	Os Genes Codificadores de Glutationa S-transferases na Abelha Apis mellifera: Expressão, Regulação e Função Durante e Após a Metamorfose. / The genes Encoding Glutathione S-transferases in the Honeybee (Apis mellifera): expression, regulation and function during and After Metamorphosis. Loterio, Guaracini Aparecida 27 October 2011 (has links) Em insetos, as enzimas glutationa S-transferases (GSTs) são conhecidas pela capacidade de degradar inseticidas, pesticidas e outros compostos químicos, naturais ou não naturais, estranhos ao organismo, podendo também promover o transporte intracelular de hormônios, metabólitos, e atuar na proteção celular contra o estresse oxidativo. Além disto, a função de uma GST tem sido associada ao processo de sequestro, pelo corpo gorduroso, de um tipo de proteína (hexamerinas) estocada na hemolinfa larval para ser utilizada como fonte de aminoácidos durante a metamorfose. Os objetivos deste trabalho consistiram em caracterizar a estrutura, a expressão e aspectos da função dos genes codificadores de GSTs em abelhas operárias Apis mellifera, além de investigar a possível função de um destes genes, hp191(GSTS1), na dinâmica de sequestro de hexamerinas durante a metamorfose. A metodologia utilizada abrangeu técnicas de biologia molecular, como RT-PCR semiquantitativa e em tempo real, sequenciamento de nucleotídeos, western blot, silenciamento gênico. Resumidamente os resultados mostraram (1) diferenças estruturais (número e organização de íntrons e éxons) entre os dez genes GSTs de A. mellifera, (2) aumento da atividade destes genes relacionado ao envelhecimento e intensa atividade de forrageamento, (3) níveis de expressão dependente do tipo de dieta alimentar, (4) perfil de expressão de hp191(GSTS1), assim como sua resposta aos hormônios morfogenéticos (hormônio juvenil e 20-hidroxiecdisona), consistentes com função na metamorfose, (4) diminuição dos níveis de hexamerina HEX 70a na hemolinfa em consequência do silenciamento de hp191(GSTS1) mediado por RNAi. Em conjunto, estes dados informam sobre estrutura, expressão e função dos genes GSTs de A. mellifera com particular foco na potencial participação de hp191(GSTS1) na metamorfose. / In insects, the enzymes glutathione S-transferases (GSTs) are known for their ability to degrade insecticides, pesticides and other chemical compounds, natural or not, which are not normally produced or expected to be present in the organism. GSTs can also promote the intracellular transportation of hormones and metabolites as well as act in the cellular protection against oxidative stress. In addition, the GST function has been associated with the process of sequestration, by the fat body, of one type of protein (hexamerin) which is stored in the larval hemolymph to be used as a source of amino acids during metamorphosis. The aims of this study were (1) to characterize structure and expression, and explore the roles of the GST encoding genes in Apis mellifera worker bees and, (2) to investigate the potential role of one of these genes, hp191(GSTS1), in the dynamics of hexamerin sequestration during metamorphosis. The methodology included molecular biology techniques, such as semiquantitative and real time RT-PCR, gene sequencing and silencing, and western blot. Briefly, the results revealed structural differences (number and organization of introns and exons) among the ten GSTs genes of A. mellifera, increased activity of these genes associated to bee aging and the intense foraging activity, and modulation of the expression levels of GST genes by the type of diet. The results also revealed that the expression profile of hp191(GSTS1), as well as its response to the morphogenetic hormones (juvenile hormone and 20-hydroxyecdysone), are consistent with a function in metamorphosis. Furthermore, hp191(GSTS1) silencing mediated by RNAi resulted in decreased hemolymph levels of a hexamerin (HEX 70a) with an essential function in metamorphosis. Altogether, these data provide novel findings concerning the structure, expression and function of the GSTs genes of A. mellifera with a special focus on the potential participation of hp191(GSTS1) in metamorphosis. Apis mellifera Apis mellifera Gene hp19 Glutathione S-transferase Glutationa S-transferases Hexamerinas Hexamerins hp19 gene Metamorfose Metamorphosis
59	The Effect Of Salvia Absconditiflora Extract On The Gene Expressions Of Gsto1 And Gstz1 In Mcf-7 And Mda-mb-231 Cells Hisarli, Nazli Deniz 01 January 2013 (has links) (PDF) S.absconditiflora is one of the endemic Salvia species grown in Turkey, which is consumed as a herbal tea. Because of the presence of high amounts of vesicles on their leaves, S.absconditiflora is very rich in active compounds. S.absconditiflora water extract was investigated for its antioxidant capacity by 2,2-Diphenyl-1-picrylhydrazyl (DPPH) free radical scavenging assay. Total phenolic and total flavonoid contents were quantified by spectrophotometric methods. LC-MS/MS analyses revealed the presence and quantities of caffeic acid, luteolin rutin and coumaric acid. Cytotoxic effects of water extract of S.absconditiflora on breast cancer cell lines (MCF-7 and MDA-MB-231) were examined via XTT colorimetric assay and Trypan Dye Exclusion cell viability assay. IC50 values for each cell line at 24 and 48 hours were determined. The results indicated that water extract of leaves of S.absconditiflora could inhibit cell proliferation in MCF-7 and MDA-231 cells in dose dependent but not in time dependent manner. Effects of S.absconditiflora water extract on the expression of glutathione-S-transferases (GSTs) in MCF-7 and MDA-MB-231 cells were investigated with qRT-PCR technique. IC50 values calculated in XTT experiment for 24h incubation was used as cytotoxic extract concentration. It was found that treatment of MCF-7 cells with 1,558 mg/ml of extract enhanced an increase in expression as 2 and 2,8 fold in GSTO1 and GSTZ1 genes, respectively. Treatment of MDA-MB-231 cells with 1,131 mg/ml of extract resulted in 1,57 fold increase for GSTO1 and 1,56 fold increase for GSTZ1.
60	Purification Of Glutathione S-transferases And Genetic Characterization Of Zeta Isozyme From Pinus Brutia, Ten Oztetik, Elif 01 February 2005 (has links) (PDF) Glutathione S-transferases (GST, EC2.5.1.18) are a family of multifunctional, dimeric enzymes that catalyse the nucleophilic attack of the tripeptide glutathione (&amp / #947 / -L-glutamyl-L-cysteinyl-L-glycine) on lipophilic compounds with electrophilic centres. The primary function of GSTs is generally considered to be the detoxification of both endogenous and xenobiotic compounds. Cytosolic GSTs have been grouped into eleven distinct classes as: (A) / Alpha, (M) / Mu, (P) / Pi, (S) / Sigma, (T) / Theta, (Z) / Zeta, (F) / Phi, (U) / Tau, (B) / Beta, (O) / Omega and (L) / Lambda. iv In this study, the total RNAs from Pinus brutia needles were isolated, GST Zeta cDNA was prepared by RT-PCR, the length of the insert was elongated by applying 5&#039 / RACE (Rapid Amplification for cDNA ends) method and the identity of the insert was checked by sequencing. The amino acid sequence of GST-Zeta was deduced as composed of 226 amino acids. The genomic DNA was also isolated from Pinus brutia needles, amplified by PCR and sequenced, and compared to the sequence of cDNA. The expression level of GST-Zeta in individual trees of Pinus brutia were examined by Northern blot analysis, and compared to their thiol contents. The mRNA levels varied up to three-fold, whereas GSH amounts varied approximately 1.8 fold, and there were no correlation between the GST-Zeta expression and GSH concentration. GST enzyme with activity towards CDNB was isolated and purified from Pinus brutia needles in 1.95 % yield with a purification factor of 15.45-fold. The purification protocol included a sequential chromatography on Sephadex G-25 column, DEAE cellulose anion exchanger liquid chromatography column, and S-hexylglutathione agarose affinity columns. The purified GST showed specific activity towards CDNB as 2022 nmole/min/mg. The GST purified from needles had a molecular weight (Mr) value of about 24.000 which was confirmed by SDS-PAGE. QD Biochemistry 415-436

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