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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Molecular mechanisms of redoxin-mediated signalling in plant immunity

Kneeshaw, Sophie January 2016 (has links)
Posttranslational modification (PTM) of proteins is essential to creating a diverse proteome with the complex functions necessary to regulate key cellular processes. Redox-based PTMs exhibit many desirable characteristics to finely modulate transcriptional regulators; they occur rapidly and can alter protein conformation, localisation and activity. The plant immune system offers an excellent model in which to study redox-based modifications due to the rapid accumulation of oxidising agents that occurs during immune invasion. This so-called “oxidative burst” causes spontaneous oxidation of cysteine residues that are present in many regulatory proteins. These modifications fine-tune the activities of proteins that harbour them, enabling them to act in a concerted effort to reprogram the transcriptome, prioritising the expression of immune-related genes over housekeeping genes. Disulphide bonds (S-S) and S-nitrosothiols (SNO, i.e. the addition of an NO group to a cysteine moiety) have been shown to play particularly important roles in plant immunity. However, what still remains unclear is how these redox-based PTMs are rendered reversible, enabling them to act as molecular signalling switches. The work presented in this thesis explores a class of enzymes that are responsible for controlling the cellular levels of protein oxidation: the Thioredoxins. In addition to their well-established role in reducing disulphide bonds, I demonstrate in Chapter 3 that Thioredoxins are able to reverse protein S-nitrosylation during plant immune signalling. Immune-inducible Thioredoxin-h5 (TRXh5) was shown to be unable to restore immunity in gsnor1 mutants that display excessive accumulation of the NO donor S-nitrosoglutathione, but rescued impaired immunity and defence gene expression in nox1-mutants that exhibit elevated levels of free NO. This data indicates that TRXh5 discriminates between protein-SNO substrates to provide previously unrecognized specificity and reversibility to protein-SNO signalling in plant immunity. Furthermore, data is presented to show that TRXh5 reversed the effects of S.nitrosylation on many immune-related transcriptional regulators in vitro, forming the initial stages of an investigation into which proteins and pathways might be controlled by reversible S-nitrosylation in plant immunity (Chapters 3 & 4). Although the majority of transcriptional regulators are likely modified at their site of action, the nucleus, very little is currently known about nuclear redox signalling in plants. Therefore, in Chapter 5 a subclass of theThioredoxin superfamily was studied, the Nucleoredoxins, which have previously been shown to display disulphide reduction activity and localise in part to the nucleus. Here it is revealed that the activity and nuclear accumulation of Nucleoredoxin 1 (NRX1) is induced by the plant leaf pathogen Pseudomonas syringae, suggesting a key role for this protein in immune signalling. Target-capture experiments and subsequent mass spectrometry analysis identified the first in vitro targets of NRX1 and revealed many proteins with roles in oxidative stress, including the hydrogen peroxide scavenger Catalase 2 (CAT2). Moreover, overexpression of NRX1 was shown to be able to rescue the enhanced cell death phenotype of cat2 knockout mutants in response to the oxidative stressor, methyl viologen. Accordingly, nrx1 knockout mutants also exhibited an enhanced cell death phenotype in response to methyl viologen treatment. Together, these data indicate that NRX1 plays a key role in the control of oxidative stress-mediated cell death, potentially through direct regulation of Catalase proteins. Taken together, the work in this thesis implicates members of the Thioredoxin family as key regulators of transcriptional reprogramming during plant immunity and uncovers a novel role for Thioredoxin superfamily member, NRX1, in the control of oxidative stress.
2

Algorithmic developments for sequence analysis, structure modeling, and functional prediction of proteins

Qi, Yuan January 2006 (has links)
Dissertation (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2006. / Vita. Bibliography: p.156-163
3

Estudos estruturais das proteinas Q4DV70 de Trypanosoma cruzi e mesotelina de Homo sapiens / Structural studies of the proteins Q4DV70 from Trypanosoma cruzi and mesothelin from Homo sapiens

Santos, Camila Ramos dos 14 August 2018 (has links)
Orientador: João Alexandre Ribeiro Gonçalves Barbosa / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-14T15:40:05Z (GMT). No. of bitstreams: 1 Santos_CamilaRamosdos_D.pdf: 7751754 bytes, checksum: 779a2794a6dc213431c4264c43cc0af6 (MD5) Previous issue date: 2009 / Resumo: Neste trabalho realizamos estudos estruturais com duas proteínas, a Q4DV70 de Trypanosoma cruzi e a mesotelina de Homo sapiens. O objetivo foi contribuir para a compreensão da função dessas proteínas, as quais possivelmente são importantes para a doença de Chagas e o câncer, respectivamente. A proteína Q4DV70 estava anotada no genoma de T. cruzi como hipotética conservada. Em nosso estudo, a proteína foi pela primeira vez detectada em amostras do parasita. Essa expressão ocorre na fase epimastigota, mas não na fase tripomastigota metacíclica, indicando que a proteína pode ter uma função importante no ciclo de vida do T. cruzi. A estrutura cristalográfica da Q4DV70 foi resolvida por substituição molecular e refinada com dados até 1,5 Å de resolução. Ela apresenta enovelamento tiorredoxina, formado por uma folha ß de 5 fitas cercada por duas hélices a de cada lado. As proteínas que apresentam maior identidade seqüencial e superposição estrutural com Q4DV70 são as tiorredoxinas e PDIs, oxidorredutases de pontes dissulfeto. Porém, as duas cisteínas do sítio ativo dessas proteínas estão substituídas por serinas em Q4DV70, o que impossibilita a função de formação, redução ou isomerização de pontes dissulfeto. Diversas tiorredoxina-like apresentam atividade chaperona independente da função oxidorredutase. Essa função está relacionada a regiões hidrofóbicas na superfície e/ou depende da presença de outro domínio. Q4DV70 é monomérica, composta apenas pelo domínio tiorredoxinalike, e não apresenta regiões hidrofóbicas em sua superfície. Além disso, não demonstrou capacidade de aumentar o enovelamento da GAPDH de T. cruzi. Esses resultados indicam que Q4DV70 não apresenta atividade chaperona. Mesotelina é uma proteína expressa em mesotélio normal e em diversos tipos de câncer, como mesotelioma, câncer de ovário e de pâncreas e leucemia mielóide aguda. Ela é considerada um marcador diagnóstico para esses cânceres e tem sido alvo para o desenvolvimento de drogas anti-tumor. Além disso, ela interage com MUC16, uma proteína presente na superfície de células de câncer de ovário. Apesar da reconhecida importância e uso da mesotelina, pouco se sabe sobre sua estrutura e função. A proteína foi purificada em condições desnaturantes e submetida ao re-enovelamento por diálise. Experimentos de dicroísmo circular, fluorescência e proteólise limitada comprovaram que a mesotelina foi corretamente re-enovelada. Essa amostra foi submetida a ensaios de cristalização, os quais resultaram em cristais que difrataram a baixa resolução. A estrutura de baixa resolução da mesotelina foi calculada a partir de dados de espalhamento de raios X a baixo ângulo e mostra que sua forma é alongada e curvada. O espectro de dicroísmo circular da mesotelina é típico de proteínas ricas em hélices a. Recentemente foi proposto que a estrutura da mesotelina é formada por uma estrutura em super-hélice, composta por repetições do tipo ARM, as quais apresentam 3 hélices a cada uma. Nossos resultados experimentais indicam que esse modelo teórico está correto. Proteólise limitada com quimotripsina resultou em um domínio estável de 20 kDa na região N-terminal da proteína. Esse domínio contém os 64 resíduos descritos como possível sítio de ligação a MUC16 e deve ser formado pelas 4 primeiras repetições do tipo ARM, de acordo com o modelo publicado. / Abstract: In this work we carried out studies with two proteins, Q4DV70 from Trypanosoma cruzi and mesothelin from Homo sapiens. The aim was to help the understanding of the function of these proteins which possibly are important to Chagas disease and cancer, respectively. Q4DV70 protein was annotated in T. cruzi genome as a conserved hypothetical protein. In our studies, the protein was detected for the first time in parasite samples. Its expression occurs in the epimastigote form but not in the metacyclic trypomastigote form indicating that Q4DV70 is important for the pathogen life cycle. Q4DV70 crystal structure was solved by molecular replacement and refined with data to 1.5 Å maximum resolution. It shows a thioredoxin fold, formed by a five stranded ß-sheet flanked by two a-helixes in each side. The proteins more sequentially identical and better structurally superposed to Q4DV70 are thioredoxins and protein disulfide isomerases, which are disulfide oxidoreductases. However, the cysteine residues from CXXC motif of the active site are replaced by serines in Q4DV70, what prevents the function of formation, reduction and isomerization of disulfide bonds. Different thioredoxin-like proteins show chaperone activity independent of oxidoreductase function. This function is related to hydrophobic regions on the surface and/or is dependent of another domain. Q4DV70 is monomeric, composed only by thioredoxin-like domain and does not show hydrophobic regions on its surface. Moreover the protein does not increase the refolding of GAPDH from T. cruzi. These results indicate that Q4DV70 does not present chaperone activity. Mesothelin is a protein expressed in normal mesothelium and in different types of cancer, such as mesothelioma, ovarian cancer, acute myeloid leukemia and cancer of pancreas. It is considered a diagnostic marker for these cancers and it has been used in the development of antitumor drugs. Besides that, it binds to MUC16, a protein present on the surface of ovarian cancer cells. In spite of its recognized significance and use in cancer, little is known about its structure and function. The protein was purified under denaturing conditions and submitted to refolding by dialysis. Circular dichroism, fluorescence and limited proteolysis experiments confirmed that mesothelin was correctly refolded. This sample was submitted to crystallization trials that resulted in crystals which diffracted at low resolution. The low resolution structure of mesothelin was calculated from small angle X-ray scattering data and it shows an elongated and curved shape. The circular dichroism spectrum for mesothelin is typical of proteins that are rich in a-helixes. Recently it was proposed that mesothelin has a superhelix structure made by ARM repeats which are composed by 3 a-helixes each one. Our experimental results indicate that this theoretical model is correct. Limited proteolysis with chymotrypsin resulted in a stable domain of 20 kDa in the Nterminal region of the protein. This domain has the 64 residues described as the possible binding site for MUC16 and should be composed by the first four ARM repeats according to the model. / Doutorado / Bioquimica / Doutor em Biologia Funcional e Molecular
4

Caractérisation biochimique et fonctionnelle d’une nouvelle thiorédoxine plastidiale (TRX z) chez Arabidopsis Thaliana / Biochemical and functional characterisation of a new plastidial thioredoxin (TRX z) in Arabidopsis Thaliana

Bohrer, Anne-Sophie 20 December 2012 (has links)
Un des principaux acteurs impliqués dans la régulation du statut redox intracellulaire, permettant aux plantes de s’adapter aux contraintes environnementales, est une famille multigénique de petites (12-14 kDa) oxydoréductases ubiquistes appelées thiorédoxines (TRX). Le génome d’Arabidopsis code une vingtaine de TRX canoniques dont neuf sont plastidiales (TRX f, m, x et y). Très étudiées dans notre laboratoire par des approches biochimiques, les TRX de types f et m apparaissent réguler majoritairement l’activité d’enzymes impliquées dans le métabolisme primaire tandis que les types x et y servir principalement de substrats réducteurs d’enzymes antioxydantes. Plus récemment, une dixième TRX, proposée plastidiale et nommée TRX z, a été identifiée. Au cours de ma thèse, j’ai caractérisé cette nouvelle TRX chloroplastique montrant des propriétés physico-chimiques inhabituelles, la rendant unique. En effet, la TRX z semble interagir, via des interactions électrostatiques, avec des protéines pour former des complexes de masses moléculaires élevées, potentiellement liés aux acides nucléiques. De plus, la TRX z, dont l’expression est induite à la lumière, principalement dans les tissus photosynthétiques, est la première TRX chloroplastique qui n’est pas réduite par le système FTR à la lumière mais qui peut être réduite par les autres TRX plastidiales, suggérant une interconnexion entre ces différentes TRX. D’autre part, une recherche exhaustive de cibles de la TRX z, par deux approches spécifiques et complémentaires (protéomique et double hybride), ont révélé 90 cibles putatives de la TRX z. La plupart de ces cibles, jamais identifiées comme cibles des TRX, sont impliquées dans la réponse de défense des plantes mise en place lors de stress biotiques. Ces résultats suggèrent que la TRX z pourrait être un élément clé dans la mise en place de ces réponses. L’analyse fonctionnelle préliminaire de la TRX z au cours de la réponse immune innée conforte cette hypothèse. L’ensemble de ces résultats indique que la TRX z pourrait jouer le rôle d’une protéine senseur de l’état d’oxydoréduction de la cellule. / One of the main actors involved in regulation of the cellular redox state, which allow plant adaptation to stress environmental conditions, is a multigenic family of small (12-14 kDa) ubiquitous oxidoreductases named thioredoxins (TRX). Arabidopsis encodes around twenty canonical TRX, including nine plastidial isoforms (TRX f, m, x and y). Extensively studied in our laboratory by biochemical approaches, TRX f and m was found to mainly redox regulate the activity of enzymes involved in the primary metabolism whereas TRX x and y serve as reducing substrates for antioxidant enzymes. More recently, a tenth TRX, predicted plastidial and named TRX z, was identified. During my PhD, I have characterized this new plastidial TRX showing unusual physicochemical properties, making it unique. Indeed, TRX z seems to interact, via electrostatic bonds, with proteins to form high molecular weight complexes, potentially linked to nucleic acids. Moreover, TRX z, which is expressed in green tissues in the light, is the first plastidial TRX which is not reduced by the FTR system but which can be reduced by other plastidial TRX, suggesting an interconnection between these TRX. Furthermore, a large scale inventory of TRX z targets, by two specific and complementary approaches (proteomic and yeast two hybrid), revealed 90 putative TRX z targets. Most of these, which have never been identified as TRX targets before, are implicated in plant defense response to biotic stresses. These results suggest that TRX z might be a key player in these responses. Preliminary functional analysis of TRX z during immune innate response reinforces this hypothesis. Altogether, these results indicate that TRX z appears as an important sensor of the redox status of the cell.
5

Rôle des rédoxines chez Sinorhizobium meliloti à l’état libre et lors de son interaction symbiotique avec Medicago truncatula. / Role of Sinorhizobium meliloti redoxins in free living conditions and during symbiosis with Medicago truncatula

Benyamina, Sofiane 29 March 2012 (has links)
Sinorhizobium meliloti est une bactérie du sol Gram- capable d'induire la formation denodosités fixatrices d'azote lors d'une interaction symbiotique avec les plantes de la familledes légumineuses. L'importance de la balance redox au cours de cette interaction a été miseen évidence. Ainsi, des mutants bactériens déficients dans la production du glutathion (GSH),présentent un phénotype altéré d'infection et de fixation de l'azote atmosphérique.Le premier objectif a donc été de déterminer si les phénotypes observés chez les mutants de lavoie de biosynthèse du GSH étaient liés à l'activité des glutarédoxines (GRX). Une analysebioinformatique a révélé la présence de trois gènes codant des GRX chez S. meliloti. Lesmutants, Smgrx1, Smgrx2 et Smgrx3, déficients pour chacune des GRX, ne produisent pasdes phénotypes similaires à ceux observés avec les mutants GSH. Si Smgrx2 présente unphénotype moins marqué, Smgrx1 est plus sévèrement affecté puisqu'il n'est plus capable dese différencier en bactéroïde. L'implication de SmGrx2 dans la régulation du métabolisme dufer et la mise en place des centres Fe-S a, par ailleurs, été mise en évidence.Le second objectif a été de définir s'il existait, chez S. meliloti, une redondance fonctionnelleentre les GRX et les thiorédoxines (TRX). Ainsi, le mutant SmtrxB, dépourvu de thiorédoxineréductase, présente la particularité d'induire la formation d'un plus grand nombre de nodulesque la souche sauvage. Le système TRX de S. meliloti apparaît donc comme un régulateurnégatif de la nodulation. D'autre part, les nodosités formées par ce mutant SmtrxB, ont uneactivité fixatrice d'azote significativement diminuée. Les rôles des TRX et des GRXapparaissent donc, au moins partiellement, distincts.Les résultats obtenus ici apportent des éléments nouveaux sur l'implication du GSH, des GRXet des TRX dans la mise en place d'une nodosité fonctionnelle, et ouvrent de nouvellesperspectives d'études sur les rôles de ces molécules dans le processus de fixation d'azote. / Sinorhizobium meliloti is a soil bacterium Gram- able to induce the formation of nitrogenfixingnodules during a symbiotic interaction with plants of the legume family. Theimportance of redox balance during this interaction has been demonstrated. In this way,bacterial mutants deficient in the production of glutathione (GSH), exhibit an alteredphenotype of infection and fixation of atmospheric nitrogen.The first objective was therefore to determine whether the phenotypes observed in mutants ofthe GSH biosynthesis pathway were related to the activity of glutaredoxins (GRX). Abioinformatic analysis revealed the presence of three genes encoding GRX in S. meliloti. Themutants, Smgrx1, Smgrx2 and Smgrx3, deficient for each of the GRX, do not producephenotypes similar to those observed with the GSH mutants. If Smgrx2 presents a less severephenotype, Smgrx1 is more severely affected since it is incapable of differentiating intobacteroïd. The involvement of SmGrx2 in the regulation of iron metabolism and theestablishment of Fe-S cluster has also been demonstrated.The second objective was to determine if there was, in S. meliloti, a functional redundancybetween GRX and thioredoxin (TRX). Thus, the SmtrxB mutant, devoid of thioredoxinreductase, has the distinctive feature of inducing the formation of more nodules than the wildtype strain. The TRX system of S. meliloti appears to be a negative regulator of nodulation.On the other hand, the nodules formed by this SmtrxB mutant have a significantly decreasednitrogen-fixing activity. Hence, the roles of TRX and GRX appear to be at least partiallydistinct.The results obtained here provide new evidence on the involvement of GSH, the GRX andTRX in the establishment of a functional nodule, and open new perspectives for studying onthe roles of these molecules in the process of nitrogen fixation.
6

A expressão dos genes codificantes da proteína de interação com tiorredoxina, da beta 2 microglobulina e do transportador de tiamina 1, correlaciona-se com marcadores clínicos da doença renal em pacientes com diabetes tipo 1 / The expression of the genes encoding thioredoxin interacting protein, beta 2 microglobulin and thiamine transporter 1, correlates with clinical markers of renal disease in type 1 diabetes patients

Caillaud, Maria Beatriz Camargo Monteiro 20 January 2016 (has links)
A nefropatia diabética (ND) é uma das principais causas de doença renal terminal. Além da lesão glomerular, o compartimento tubulointersticial é afetado no desenvolvimento da ND, não somente pela proteinúria como pelos efeitos pró-inflamatórios, profibróticos, pró-oxidantes e angiogênicos da hiperglicemia e dos produtos finais de glicação avançada (AGEs). Sabese que as concentrações de marcadores do estresse oxidativo estão aumentadas em pacientes com diabetes mellitus (DM). O sistema tiorredoxina (TXN) é um dos principais sistemas antioxidantes endógenos. A TXN é capaz de interagir com um grande número de fatores de transcrição e proteínas, tal como a Thioredoxin interacting protein (TXNIP) que tem sido reconhecida na patogênese do DM e de suas complicações. Além da TXNIP, a deficiência de tiamina, ou vitamina B1, já foi relatada em modelos experimentais de DM, concomitantemente a um aumento de seu clearance renal. Os transportadores de tiamina 1 (THTR1) e 2 (THTR2) (codificados pelos genes SLC19A2 e SLC19A3, respectivamente) são os responsáveis pela reabsorção de tiamina no túbulo proximal após sua filtração pelo glomérulo. Estudos já demonstraram que a excreção aumentada de tiamina pode ser um fator de risco para o declínio precoce da função renal em pacientes DM. Uma outra proteína de interesse é a beta 2 microglobulina (B2M), expressa em situações que cursam com inflamação, um fenômeno bem caracterizado na tubulopatia diabética. O estudo da ativação intrarenal de vias potencialmente associadas à evolução da ND em humanos é dificultada pela necessidade de biópsia renal. Recentemente o sedimento urinário tem sido utilizado na avaliação das doenças renais, tanto na tentativa de identificar biomarcadores que possam predizer o declínio da função renal, como para o melhor entendimento da patogênese dessa complicação. O objetivo deste trabalho foi estudar a participação dos genesalvo TXNIP, TXN, SLC19A2, SLC19A3 e B2M na patogênese da ND em portadores de DM1. Estudamos o RNA mensageiro (mRNA) do sedimento urinário de pacientes DM1 (n=55), portadores de glomeruloesclerose segmentar e focal (GESF, um modelo de nefropatia não diabética, n=12) e de indivíduos controles (n=11) para avaliação da expressão dos genes-alvo, e sua associação com as manifestações da ND. Também foi extraído mRNA de células linfomononucleares de pacientes DM1 (n=162) e indivíduos controles (n=26) para comparação com os resultados obtidos no sedimento urinário e foram dosadas as concentrações plasmáticas de tiamina em um subgrupos de pacientes DM1 e de indivíduos controles. Além disso, uma linhagem de células renais humanas foi tratada com altas concentrações de glicose e albumina glicada ou não glicada in vitro para avaliar se os AGEs estão implicados na alteração de expressão dos genes-alvos. Como resultado observamos (1) um aumento na expressão de TXNIP e TXN no sedimento urinário de pacientes DM1 com doença renal e associação da expressão de TXNIP com a magnitude do declínio da taxa de filtração glomerular; (2) um aumento na expressão de TXNIP e TXN nas células linfomononucleares dos pacientes DM1; (3) um aumento na expressão de SLC19A2 no sedimento urinário de pacientes DM1 com doença renal; (4) uma diminuição nas concentrações plasmáticas de tiamina nos pacientes DM1 em comparação aos controles; (5) um aumento na expressão de B2M no sedimento urinário de pacientes DM1 com doença renal e (6) um aumento na expressão de TXNIP e B2M nas células renais humanas tratadas concomitantemente com altas concentrações de glicose e albumina glicada. Os resultados do presente estudo sugerem fortemente a participação do sistema TXN e da B2M na etiopatogênese da ND / Diabetic nephropathy (DN) is a major cause of end stage renal disease. Glomerular and tubulointerstitial compartments are affected not only by proteinuria but also by the pro-inflammatory, profibrotic, pro-oxidants and pro-angiogenic effects exerted by hyperglycemia and advanced glycation end products (AGEs) in the development of DN. It is well known that concentrations of oxidative stress markers are increased in patients with diabetes mellitus (DM). The thioredoxin system (TXN) is one of the majors endogenous antioxidant systems; TXN molecule is able to interact with a large number of transcription factors and proteins such as Thioredoxin interacting protein (TXNIP), which has been recognized in the pathogenesis of DM and its complications. Deficiency of thiamine, or B1 vitamin, has been reported in experimental models of DM concomitantly with an increase in its renal clearance. Thiamine transporter 1 (THTR1), encoded by the SLC19A2 gene and Thiamine transporter 2 (THTR2), encoded by the SLC19A3 gene are responsible for thiamine reabsorption in the proximal tubule after glomerular filtration. Studies have shown that increased urinary excretion of thiamine may be a risk predictor for an early decline in kidney function in diabetic patients. Another protein of interest is beta-2-microglobulin (B2M), expressed in situations of inflammation, a well-characterized phenomenon in diabetic tubulopathy. The study of activation or inactivation of intrarenal pathways potentially associated with progression of DN in humans is complicated by the need for renal biopsy. Recently urinary sediment has been used in the evaluation of kidney diseases in an attempt to identify biomarkers that can predict kidney function decline and as a tool for a better understanding of the pathogenesis of this complication. The objective of this work was to study the participation of the target genes TXNIP, TXN, SLC19A2, SLC19A3 and B2M in the pathogenesis of DN in type 1 DM (T1D) patients. We studied the urinary sediment messenger RNA (mRNA) from patients with T1D (n=55); with focal and segmental glomerulosclerosis (FSGS, a non diabetic nephropathy model, n=12) and from control subjects (n=11) to assess the expression of the target genes and their association with the severity of DN. We also studied the mRNA expression of peripheral lymphomononuclear (PLMN) cells from T1D patients (n=162) and control subjects (n=26) in order to compare with the results obtained in the urinary sediment. Plasmatic concentrations of thiamine were also measured in a subgroup of T1D patients and control subjects. In addition, a lineage of human kidney cells was exposed to high glucose concentrations and to glycated and non-glycated albumin to evaluate if AGEs are implicated in the modulation of expression of the target genes. As a result we found that (1) TXNIP and TXN are upregulated in the urinary sediment of T1D patients with kidney disease and TXNIP is associated with the magnitude of glomerular filtration rate decline; (2) TXNIP and TXN are upregulated in PLMN cells from T1D patients; (3) SLC19A2 is upregulated in the urinary sediment of T1D patients with kidney disease; (4) T1D patients present decreased plasmatic thiamine concentrations compared to control subjects; (5) B2M is upregulated in the urinary sediment of T1D patients with kidney disease and (6) TXNIP and B2M are upregulated in human kidney cells exposed concomitantly to high glucose concentrations and glycated albumin. The results of the present study strongly suggest the participation of the TXN system and of B2M in the pathogenesis of DN. Descriptors: diabetes mellitus, diabetic nephropathies, urine, glycosylation end products, advanced, thiamine, thioredoxins, beta 2-microglobulin Diabetic nephropathy (DN) is a major cause of end stage renal disease. Glomerular and tubulointerstitial compartments are affected not only by proteinuria but also by the pro-inflammatory, profibrotic, pro-oxidants and pro-angiogenic effects exerted by hyperglycemia and advanced glycation end products (AGEs) in the development of DN. It is well known that concentrations of oxidative stress markers are increased in patients with diabetes mellitus (DM). The thioredoxin system (TXN) is one of the majors endogenous antioxidant systems; TXN molecule is able to interact with a large number of transcription factors and proteins such as Thioredoxin interacting protein (TXNIP), which has been recognized in the pathogenesis of DM and its complications. Deficiency of thiamine, or B1 vitamin, has been reported in experimental models of DM concomitantly with an increase in its renal clearance. Thiamine transporter 1 (THTR1), encoded by the SLC19A2 gene and Thiamine transporter 2 (THTR2), encoded by the SLC19A3 gene are responsible for thiamine reabsorption in the proximal tubule after glomerular filtration. Studies have shown that increased urinary excretion of thiamine may be a risk predictor for an early decline in kidney function in diabetic patients. Another protein of interest is beta-2-microglobulin (B2M), expressed in situations of inflammation, a well-characterized phenomenon in diabetic tubulopathy. The study of activation or inactivation of intrarenal pathways potentially associated with progression of DN in humans is complicated by the need for renal biopsy. Recently urinary sediment has been used in the evaluation of kidney diseases in an attempt to identify biomarkers that can predict kidney function decline and as a tool for a better understanding of the pathogenesis of this complication. The objective of this work was to study the participation of the target genes TXNIP, TXN, SLC19A2, SLC19A3 and B2M in the pathogenesis of DN in type 1 DM (T1D) patients. We studied the urinary sediment messenger RNA (mRNA) from patients with T1D (n=55); with focal and segmental glomerulosclerosis (FSGS, a non diabetic nephropathy model, n=12) and from control subjects (n=11) to assess the expression of the target genes and their association with the severity of DN. We also studied the mRNA expression of peripheral lymphomononuclear (PLMN) cells from T1D patients (n=162) and control subjects (n=26) in order to compare with the results obtained in the urinary sediment. Plasmatic concentrations of thiamine were also measured in a subgroup of T1D patients and control subjects. In addition, a lineage of human kidney cells was exposed to high glucose concentrations and to glycated and non-glycated albumin to evaluate if AGEs are implicated in the modulation of expression of the target genes. As a result we found that (1) TXNIP and TXN are upregulated in the urinary sediment of T1D patients with kidney disease and TXNIP is associated with the magnitude of glomerular filtration rate decline; (2) TXNIP and TXN are upregulated in PLMN cells from T1D patients; (3) SLC19A2 is upregulated in the urinary sediment of T1D patients with kidney disease; (4) T1D patients present decreased plasmatic thiamine concentrations compared to control subjects; (5) B2M is upregulated in the urinary sediment of T1D patients with kidney disease and (6) TXNIP and B2M are upregulated in human kidney cells exposed concomitantly to high glucose concentrations and glycated albumin. The results of the present study strongly suggest the participation of the TXN system and of B2M in the pathogenesis of DN
7

A expressão dos genes codificantes da proteína de interação com tiorredoxina, da beta 2 microglobulina e do transportador de tiamina 1, correlaciona-se com marcadores clínicos da doença renal em pacientes com diabetes tipo 1 / The expression of the genes encoding thioredoxin interacting protein, beta 2 microglobulin and thiamine transporter 1, correlates with clinical markers of renal disease in type 1 diabetes patients

Maria Beatriz Camargo Monteiro Caillaud 20 January 2016 (has links)
A nefropatia diabética (ND) é uma das principais causas de doença renal terminal. Além da lesão glomerular, o compartimento tubulointersticial é afetado no desenvolvimento da ND, não somente pela proteinúria como pelos efeitos pró-inflamatórios, profibróticos, pró-oxidantes e angiogênicos da hiperglicemia e dos produtos finais de glicação avançada (AGEs). Sabese que as concentrações de marcadores do estresse oxidativo estão aumentadas em pacientes com diabetes mellitus (DM). O sistema tiorredoxina (TXN) é um dos principais sistemas antioxidantes endógenos. A TXN é capaz de interagir com um grande número de fatores de transcrição e proteínas, tal como a Thioredoxin interacting protein (TXNIP) que tem sido reconhecida na patogênese do DM e de suas complicações. Além da TXNIP, a deficiência de tiamina, ou vitamina B1, já foi relatada em modelos experimentais de DM, concomitantemente a um aumento de seu clearance renal. Os transportadores de tiamina 1 (THTR1) e 2 (THTR2) (codificados pelos genes SLC19A2 e SLC19A3, respectivamente) são os responsáveis pela reabsorção de tiamina no túbulo proximal após sua filtração pelo glomérulo. Estudos já demonstraram que a excreção aumentada de tiamina pode ser um fator de risco para o declínio precoce da função renal em pacientes DM. Uma outra proteína de interesse é a beta 2 microglobulina (B2M), expressa em situações que cursam com inflamação, um fenômeno bem caracterizado na tubulopatia diabética. O estudo da ativação intrarenal de vias potencialmente associadas à evolução da ND em humanos é dificultada pela necessidade de biópsia renal. Recentemente o sedimento urinário tem sido utilizado na avaliação das doenças renais, tanto na tentativa de identificar biomarcadores que possam predizer o declínio da função renal, como para o melhor entendimento da patogênese dessa complicação. O objetivo deste trabalho foi estudar a participação dos genesalvo TXNIP, TXN, SLC19A2, SLC19A3 e B2M na patogênese da ND em portadores de DM1. Estudamos o RNA mensageiro (mRNA) do sedimento urinário de pacientes DM1 (n=55), portadores de glomeruloesclerose segmentar e focal (GESF, um modelo de nefropatia não diabética, n=12) e de indivíduos controles (n=11) para avaliação da expressão dos genes-alvo, e sua associação com as manifestações da ND. Também foi extraído mRNA de células linfomononucleares de pacientes DM1 (n=162) e indivíduos controles (n=26) para comparação com os resultados obtidos no sedimento urinário e foram dosadas as concentrações plasmáticas de tiamina em um subgrupos de pacientes DM1 e de indivíduos controles. Além disso, uma linhagem de células renais humanas foi tratada com altas concentrações de glicose e albumina glicada ou não glicada in vitro para avaliar se os AGEs estão implicados na alteração de expressão dos genes-alvos. Como resultado observamos (1) um aumento na expressão de TXNIP e TXN no sedimento urinário de pacientes DM1 com doença renal e associação da expressão de TXNIP com a magnitude do declínio da taxa de filtração glomerular; (2) um aumento na expressão de TXNIP e TXN nas células linfomononucleares dos pacientes DM1; (3) um aumento na expressão de SLC19A2 no sedimento urinário de pacientes DM1 com doença renal; (4) uma diminuição nas concentrações plasmáticas de tiamina nos pacientes DM1 em comparação aos controles; (5) um aumento na expressão de B2M no sedimento urinário de pacientes DM1 com doença renal e (6) um aumento na expressão de TXNIP e B2M nas células renais humanas tratadas concomitantemente com altas concentrações de glicose e albumina glicada. Os resultados do presente estudo sugerem fortemente a participação do sistema TXN e da B2M na etiopatogênese da ND / Diabetic nephropathy (DN) is a major cause of end stage renal disease. Glomerular and tubulointerstitial compartments are affected not only by proteinuria but also by the pro-inflammatory, profibrotic, pro-oxidants and pro-angiogenic effects exerted by hyperglycemia and advanced glycation end products (AGEs) in the development of DN. It is well known that concentrations of oxidative stress markers are increased in patients with diabetes mellitus (DM). The thioredoxin system (TXN) is one of the majors endogenous antioxidant systems; TXN molecule is able to interact with a large number of transcription factors and proteins such as Thioredoxin interacting protein (TXNIP), which has been recognized in the pathogenesis of DM and its complications. Deficiency of thiamine, or B1 vitamin, has been reported in experimental models of DM concomitantly with an increase in its renal clearance. Thiamine transporter 1 (THTR1), encoded by the SLC19A2 gene and Thiamine transporter 2 (THTR2), encoded by the SLC19A3 gene are responsible for thiamine reabsorption in the proximal tubule after glomerular filtration. Studies have shown that increased urinary excretion of thiamine may be a risk predictor for an early decline in kidney function in diabetic patients. Another protein of interest is beta-2-microglobulin (B2M), expressed in situations of inflammation, a well-characterized phenomenon in diabetic tubulopathy. The study of activation or inactivation of intrarenal pathways potentially associated with progression of DN in humans is complicated by the need for renal biopsy. Recently urinary sediment has been used in the evaluation of kidney diseases in an attempt to identify biomarkers that can predict kidney function decline and as a tool for a better understanding of the pathogenesis of this complication. The objective of this work was to study the participation of the target genes TXNIP, TXN, SLC19A2, SLC19A3 and B2M in the pathogenesis of DN in type 1 DM (T1D) patients. We studied the urinary sediment messenger RNA (mRNA) from patients with T1D (n=55); with focal and segmental glomerulosclerosis (FSGS, a non diabetic nephropathy model, n=12) and from control subjects (n=11) to assess the expression of the target genes and their association with the severity of DN. We also studied the mRNA expression of peripheral lymphomononuclear (PLMN) cells from T1D patients (n=162) and control subjects (n=26) in order to compare with the results obtained in the urinary sediment. Plasmatic concentrations of thiamine were also measured in a subgroup of T1D patients and control subjects. In addition, a lineage of human kidney cells was exposed to high glucose concentrations and to glycated and non-glycated albumin to evaluate if AGEs are implicated in the modulation of expression of the target genes. As a result we found that (1) TXNIP and TXN are upregulated in the urinary sediment of T1D patients with kidney disease and TXNIP is associated with the magnitude of glomerular filtration rate decline; (2) TXNIP and TXN are upregulated in PLMN cells from T1D patients; (3) SLC19A2 is upregulated in the urinary sediment of T1D patients with kidney disease; (4) T1D patients present decreased plasmatic thiamine concentrations compared to control subjects; (5) B2M is upregulated in the urinary sediment of T1D patients with kidney disease and (6) TXNIP and B2M are upregulated in human kidney cells exposed concomitantly to high glucose concentrations and glycated albumin. The results of the present study strongly suggest the participation of the TXN system and of B2M in the pathogenesis of DN. Descriptors: diabetes mellitus, diabetic nephropathies, urine, glycosylation end products, advanced, thiamine, thioredoxins, beta 2-microglobulin Diabetic nephropathy (DN) is a major cause of end stage renal disease. Glomerular and tubulointerstitial compartments are affected not only by proteinuria but also by the pro-inflammatory, profibrotic, pro-oxidants and pro-angiogenic effects exerted by hyperglycemia and advanced glycation end products (AGEs) in the development of DN. It is well known that concentrations of oxidative stress markers are increased in patients with diabetes mellitus (DM). The thioredoxin system (TXN) is one of the majors endogenous antioxidant systems; TXN molecule is able to interact with a large number of transcription factors and proteins such as Thioredoxin interacting protein (TXNIP), which has been recognized in the pathogenesis of DM and its complications. Deficiency of thiamine, or B1 vitamin, has been reported in experimental models of DM concomitantly with an increase in its renal clearance. Thiamine transporter 1 (THTR1), encoded by the SLC19A2 gene and Thiamine transporter 2 (THTR2), encoded by the SLC19A3 gene are responsible for thiamine reabsorption in the proximal tubule after glomerular filtration. Studies have shown that increased urinary excretion of thiamine may be a risk predictor for an early decline in kidney function in diabetic patients. Another protein of interest is beta-2-microglobulin (B2M), expressed in situations of inflammation, a well-characterized phenomenon in diabetic tubulopathy. The study of activation or inactivation of intrarenal pathways potentially associated with progression of DN in humans is complicated by the need for renal biopsy. Recently urinary sediment has been used in the evaluation of kidney diseases in an attempt to identify biomarkers that can predict kidney function decline and as a tool for a better understanding of the pathogenesis of this complication. The objective of this work was to study the participation of the target genes TXNIP, TXN, SLC19A2, SLC19A3 and B2M in the pathogenesis of DN in type 1 DM (T1D) patients. We studied the urinary sediment messenger RNA (mRNA) from patients with T1D (n=55); with focal and segmental glomerulosclerosis (FSGS, a non diabetic nephropathy model, n=12) and from control subjects (n=11) to assess the expression of the target genes and their association with the severity of DN. We also studied the mRNA expression of peripheral lymphomononuclear (PLMN) cells from T1D patients (n=162) and control subjects (n=26) in order to compare with the results obtained in the urinary sediment. Plasmatic concentrations of thiamine were also measured in a subgroup of T1D patients and control subjects. In addition, a lineage of human kidney cells was exposed to high glucose concentrations and to glycated and non-glycated albumin to evaluate if AGEs are implicated in the modulation of expression of the target genes. As a result we found that (1) TXNIP and TXN are upregulated in the urinary sediment of T1D patients with kidney disease and TXNIP is associated with the magnitude of glomerular filtration rate decline; (2) TXNIP and TXN are upregulated in PLMN cells from T1D patients; (3) SLC19A2 is upregulated in the urinary sediment of T1D patients with kidney disease; (4) T1D patients present decreased plasmatic thiamine concentrations compared to control subjects; (5) B2M is upregulated in the urinary sediment of T1D patients with kidney disease and (6) TXNIP and B2M are upregulated in human kidney cells exposed concomitantly to high glucose concentrations and glycated albumin. The results of the present study strongly suggest the participation of the TXN system and of B2M in the pathogenesis of DN
8

Redox-Regulation der Enzyme Glutamyl-tRNA-Reduktase (GluTR) und 5-Aminolävulinsäure-Dehydratase (ALAD) in Arabidopsis thaliana

Wittmann, Daniel Thomas 22 March 2022 (has links)
Die für Pflanzen lebenswichtige Synthese von Tetrapyrrolen bedarf einer fein justierten Anpassung an die Umweltbedingungen und erfolgt auf transkriptioneller und post-translationaler Ebene. In den Chloroplasten hat sich die Regulation von Enzymen über ihren Redox-Status als probates Mittel zur Koordination der photosynthetischen Energiegewinnung und des Metabolismus erwiesen. Die bei der Photosynthese generierten Reduktionsäquivalente werden zum Teil über die Ferredoxin-Thioredoxin-Reduktase auf eine Vielzahl plastidärer Thioredoxine (TRX) übertragen, welche Disulfidbrücken ihrer Zielproteine reduzieren können. Unter den Enzymen der Tetrapyrrolbiosynthese (TBS) wurden bisher mehrere TRX-Interaktionspartner identifiziert, darunter die Glutamyl-tRNA-Reduktase (GluTR) und die 5-Aminolävulinsäure-Dehydratase (ALAD). In Arabidopsis Mutanten, in denen die NADPH-abhängige Thioredoxin-Reduktase (NTRC) oder f- und m-Typ-TRX fehlen, konnten verringerte Chlorophyll- und Hämgehalte beobachtet werden. Diese ließen sich auf die verringerte Stabilität verschiedener TBS-Enzyme in den Mutanten zurückführen, darunter auch die GluTR und ALAD. Die Relevanz der Cysteine (Cys, C) für die Regulation der GluTR1-Stabilität wurde in vivo über transgene Arabidopsis Cys➔Serin (Ser, S)-Substitutionslinien untersucht. Dabei erwies sich GluTR1(C464S) stärker vor dem Abbau über die kaseinolytische Protease (Clp) geschützt als das WT-Protein. Eine intermolekulare Disulfidbrücke zwischen den beiden Cys464-Resten des GluTR1-Homodimers wird daher als Abbausignal postuliert. Mit Hilfe der rekombinanten ALAD1(Cys➔Ser)-Substitutionsmutanten konnte gezeigt werden, dass nicht nur die Stabilität, sondern auch die Aktivität der ALAD1 in vitro vom Redox-Status des Enzyms abhängig ist. Die ALAD1(Cys➔Ser)-Substitutionsmutanten konnten über Enzymaktivitäts- und gel shift-Assays unter oxidierenden und reduzierenden Bedingungen zur Identifizierung der redox-sensitiven Cys beitragen. / The synthesis of tetrapyrroles, such as chlorophyll, is vital for plants and requires a finetuned regulation. The control mechanisms involved in tetrapyrrole biosynthesis (TBS) take place both on transcriptional and post-translational levels. A broadly spread post-translational regulatory mechanism in the chloroplast involves the reduction of inter- or intramolecular disulfide bonds of redox-sensitive target enzymes by thioredoxins (TRX). Thereby the coupling of photosynthetic energy production with several energy-consuming metabolic processes can be accomplished. The reduction of disulfide bonds in redox-sensitive enzymes was previously shown to lead usually to their activation. Regarding the TBS, several TRX interacting proteins have been identified, including glutamyl-tRNA-reductase (GluTR) as well as the 5-aminolevulinic acid dehydratase (ALAD). Through the detailed and combined analysis of mutants with deficient NADPH-dependent thioredoxin reductase C (NTRC), TRX-f and TRX-m, a correlation became evident between decreased chlorophyll and heme levels of the mutants and lower amounts of several TBS enzymes, including GluTR and ALAD. For GluTR1, transgenic Arabidopsis cysteine (Cys, C) ➔ serine (Ser, S) substitution lines were generated and analyzed to identify the redox-sensitive Cys residues in vivo. In these studies, GluTR1(C464S) was shown to be better protected from degradation by the caseinolytic protease (Clp) than the GluTR1 WT protein. Thus, an intermolecular disulfide bond between the Cys464 residues in the dimerization domain of the GluTR1 homodimer is postulated to serve as a degradation signal under oxidizing conditions. However, it was shown by activity- and gel shift-assays with recombinant ALAD1(Cys➔Ser) substitution mutants that not only the stability, but also the in vitro activity of ALAD1 depends on the enzyme's redox state. Redox-sensitive inter- and intramolecular disulfide bridges of ALAD1 were identified among Cys71, Cys152 and Cys251.

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