Global ETD Search

121	Regulation von Adipocyte fatty acid binding protein in Abhängigkeit der Nierenfunktion Hopf, Lisa-Marie 17 December 2015 (has links) Adipositas und die damit verbundenen Folgeerkrankungen sind eine der zentralen Gesund-heitsherausforderungen unserer Zeit. Dauerhafte Adipositas führt zu einer Dysregulation fettgewebseigener Peptidhormone. Diese sogenannten Adipokine stellen ein Verbindungsglied zwischen Fettgewebsakkumulation und den vielfältigen Adipositaskomplikationen des gesamten Organismus dar. Adipocyte fatty acid binding protein (AFABP) wurde in den letzten Jahren als zirkulierendes Adipokin mit diabetogenen, proinflammatorischen und proateriosklerotischen Effekten etabliert. Zu Beginn der Dissertation lagen unzureichende Erkenntnisse über die Elimination von AFABP sowie die Regulation des Adipokins bei eingeschränkter Nierenfunktion vor. Aus diesem Grund untersucht die vorliegende Arbeit die AFABP-Regulation in Abhängigkeit von der Nierenfunktion in 532 Patienten mit chronischer Niereninsuffizienz (Studienpopulation 1) und 32 Patienten mit akuter Nierenfunktionsverminderung nach Nephrektomie (Studienpopulation 2). In beiden Kohorten stiegen die medianen AFABP-Serumkonzentrationen mit abfallender Nierenfunktion an. Zudem waren Marker der Nierenfunktion in beiden Studienpopulationen die stärksten unabhängigen Prädiktoren für zirkulierendes AFABP. Untersuchungen aus der Arbeitsgruppe zur AFABP-Regulation in einem Rattenmodell der akuten Niereninsuffizienz unterstützen die klinischen Studienergebnisse. Zusammenfassend zeigen diese Ergebnisse zum ersten Mal signifikant steigende AFABP-Serumspiegel bei chronischer und akuter Nierenfunktionsstörung, sowie bei akutem Abfall der Nierenfunktion. Diese Befunde stützen die Hypothese, dass AFABP renal eliminiert wird. Inwiefern AFABP darüber hinaus in die Pathogenese der chronischen Niereninsuffizienz eingreift, muss in weiterführenden Studien beleuchtet werden. info:eu-repo/classification/ddc/610 ddc:610 Adipocste fatty acid binding protein
122	Identificação e caracterização de novos moduladores da divisão em Bacillus subtilis / Identification and characterization of new modulators of division in B. subtilis Tavares, José Roberto 31 July 2009 (has links) Em procariotos, a principal forma de reprodução é a divisão binária, que permite à célula-mãe dar origem a duas outras células-filhas, com conteúdo genético idêntico ao da progenitora. Em Bacillus subtilis este processo acontece graças ao divisomo, um complexo formado por aproximadamente dezesseis proteínas, que leva à constrição da membrana e da parede, formando o septo de divisão. A montagem do divisomo é coordenada por FtsZ, um homólogo de tubulina, que polimeriza na região central da bactéria e serve de arcabouço para a montagem do divisomo. Partindo de um levantamento detalhado da distribuição dos genes envolvidos em divisão em genomas completos de procariotos detectamos que divIVA, um gene de divisão já bem caracterizado, apresentava um gene parálogo em B. subtilis, conhecido como ypsB. Para determinarmos se YpsB seria um novo componente do divisomo foi realizada uma caracterização citológica e funcional desta proteína. Utilizamos microscopia de fluorescência e fusões de YpsB a GFP para determinar a localização subcelular de YpsB. Estes experimentos revelaram que YpsB está presente no divisomo, apresentando um padrão de localização semelhante mas não idêntico ao de DivIVA. Medindo-se a taxa de co-localização entre o anel Z e YpsB ficou demonstrado que estas proteínas co-localizam em aproximadamente 50%, sugerindo que YpsB é recrutada depois que o anel Z é montado. Para determinar quando YpsB chega ao divisomo, usamos mutantes termo-sensíveis das proteínas de divisão que revelaram a dependência de YpsB pelo sub complexo DivIB-DivIC-FtsL-FtsW-PBP2B. Já na ausência de DivIVA, YpsB continua associado ao divisomo, indicando que não depende do seu parálogo para localizar. Além disso, análises de deleções de YpsB mostraram que a porção N-terminal da proteína é a mais importante para o seu recrutamento ao divisomo. Para determinarmos o papel de YpsB durante a divisão foi construído um mutante com deleção completa do gene. DivIVA é uma proteína responsável por localizar o sistema Min nos pólos da bactéria e assim contribui para a precisão espacial da divisão. Apesar de serem parálogos, a função de YpsB, no entanto, parece ser diferente da de DivIVA. Análise do mutante ypsB- mostrou que na sua ausência, o divisomo é montado e o seu posicionamento tanto em fase vegetativa como em esporulação não são afetados. Como a ausência de YpsB não afeta perceptivelmente a divisão, combinamos a mutação em ypsB com mutações em outros genes envolvidos em divisão. A análise destes duplos mutantes revelou que a ausência simultânea de YpsB e FtsA produz exacerbada lise celular e letalidade. Com base neste fenótipo e em evidências evolutivas, sugerimos que YpsB esteja envolvida na regulação da síntese de peptideoglicano do septo. Mais especificamente, YpsB seria responsável por modular a atividade de PBP1, uma enzima necessária para a síntese de peptideoglicano septal. / In prokaryotes, the main form of reproduction is binary fission, which allows the mother-cell to give origin the two daughter-cells, with identical genetic material. In Bacillus subtilis, this process is performed by the divisome, a complex formed for approximately sixteen proteins that leads to the constriction of the membrane and the wall, creating the division septum. The assembly of the divisome is coordinated by FtsZ, a homolog of tubulin, that polymerizes in the central region of the bacteria and serves as the base for the assembly of the divisome. From a detailed survey of the distribution of the genes involved in division in complete genomes of prokaryotes, we detected that divIVA, a well characterized division gene, showed a paralog in B. subtilis, known as YpsB. To determine if YpsB would be a new component of the divisome, a cytological and functional characterization of this protein was carried out. We used fluorescence microscopy and fusion of YpsB to GFP to determine the subcellular localization of YpsB. These experiments displayed that YpsB is present in the divisome, with similar but not identical localization as DivIVA. Measuring co-localization between the Z ring and YpsB demonstrated that this happened in approximately 50% of the cells, suggesting that YpsB go to the divisome after the Z ring is formed. To determine when YpsB goes to the divisome, we used temperature-sensitive mutants of the division proteins. This showed that YpsB depends on the DivIB-DivIC-FtsL-FtsW-PBP2B sub-complex to associate with the divisome. In the absence of DivIVA, YpsB is still present in the divisome, indicating that it does not depend on its paralog to localize. Moreover, deletion analyses of YpsB showed that the N-terminal portion of the protein is the most important for its recruitment to the divisome. To determine the role of YpsB during division, we constructed a ypsB- mutant. DivIVA is the protein responsible for localization of the Min system in polar regions of B. subtilis and, thus, contributes for the spatial precision of division. Our results showed that the function of YpsB must be different from that of DivIVA, since analysis of the ypsB- mutant showed that in the absence this protein the divisome is assembled and septum position in vegetatively growing or sporulating cells is not affected. Since the absence of YpsB does not affect division, we combined the ypsB- mutant with mutants involved in division. Analysis of these double mutants showed that the simultaneous absence of YpsB and FtsA caused cellular lysis and lethality. Based on this phenotype and evolutionary evidences, we suggest that YpsB is involved in the regulation of peptidoglycan synthesis in the septum. More specifically, YpsB would be responsible for modulating the activity of PBP1, a necessary enzyme for septum peptidoglycan synthesis. Bacillus Bacillus Penicillin binding protein Biochemistry Bioquímica Cell division Divisão celular Divisome Divisomo DivIVA DivIVA FtsZ FtsZ Penicillin binding protein Peptideoglicano Peptidoglycan YpsB YpsB
123	Modelagem comparativa e triagem virtual hier?rquica para identifica??o de moduladores das OBPs de Lutzomyia Longipalpis Santana, Isis Bugia 11 March 2016 (has links) Submitted by Ricardo Cedraz Duque Moliterno (ricardo.moliterno@uefs.br) on 2017-02-14T00:41:33Z No. of bitstreams: 1 PPGBiotec - Disserta??o corrigida - Isis Bugia.pdf: 6811384 bytes, checksum: 2380cbb790d35324858de90e106415fc (MD5) / Made available in DSpace on 2017-02-14T00:41:33Z (GMT). No. of bitstreams: 1 PPGBiotec - Disserta??o corrigida - Isis Bugia.pdf: 6811384 bytes, checksum: 2380cbb790d35324858de90e106415fc (MD5) Previous issue date: 2016-03-11 / The Visceral Leishmaniasis (VL) is the second most important vector-borne disease in the world, transmitted in the Americas by Lutzomyia longipalpis, vector control is essential for the prevention of the disease. But since it is not possible to identify the oviposition sites, the fight is directed to adult insects, using traps impregnated with chemical attractants. Whereas the Odorant Binding Proteins (OBPs) act in the first level of odor selection, this work used in silico methodology to identify putative vector olfactory chemical modulators based on the structure of OBPs and known ligands. For this, tridimensional (3D) structure of L. longipalpis OBPs were predicted by three comparative modeling methods. The best model, predicted by I-Tasser, was refined by Molecular Dynamics on Gromacs. Then, in a hierarchical virtual screening approach, natural compounds of ZINC12 closer to the typical OBP ligands in global chemical space, provided by ChemGPS-NP, were evaluated and staggered concerning affinity with the orthosteric site from the OBP, by molecular docking on DOCK6. The compounds were scored by GRIDSCORE, then the 100 best classified were submitted to AMBERSCORE, which took into account the flexibility from both OBP and the docked ligands. The lowest energy conformations interacted with a hydrophobic pocket through residues Met6, Gly10, Glu11, Ala9 Arg14, Leu74, Met53, Phe118, Phe119, Pro120, amino groups and formed ionic interaction with carboxyl of Glu11, Furthermore, Phe119, Asn29 and Gln69 formed hydrogen bonds, this last formed donor and acceptor H-bonds. / A Leishmaniose Visceral (LV) ? a segunda doen?a vetorial mais importante do mundo, transmitida nas Am?ricas por Lutzomyia longipalpis, o controle do vetor ? indispens?vel ? preven??o da doen?a. Mas como n?o ? poss?vel identificar onde ocorre a oviposi??o, o combate ? direcionado aos insetos adultos, utilizando armadilhas impregnadas com atrativos qu?micos. Considerando que as Prote?nas Ligadoras de Odor (OBPs) atuam no primeiro n?vel de sele??o dos odores, este trabalho utilizou uma metodologia in silico para identificar potenciais moduladores qu?micos olfativos do vetor baseando-se na estrutura das OBPs e de ligantes conhecidos. Para isso, foram preditas as estruturas tridimensionais (3D) de OBPs de L. longipalpis por tr?s m?todos de modelagem comparativa. O melhor modelo, predito pelo I-Tasser, foi refinado por Din?mica Molecular no Gromacs. Ent?o, numa abordagem hier?rquica da triagem virtual, os compostos naturais do ZINC12 mais pr?ximos dos t?picos ligantes de OBPs no espa?o qu?mico global, fornecido pelo ChemGPS-NP, foram avaliados e escalonados quanto ? afinidade com o s?tio ortost?rico da OBP, pelo acoplamento molecular no DOCK6. Os compostos foram pontuados pelo Gridscore, em seguida, os cem melhores classificados foram submetidos ? pontua??o pelo Amberscore, que levou em conta a flexibilidade tanto da OBP como dos ligantes acoplados. As conforma??es de menor energia interagiram com um bols?o hidrof?bico atrav?s dos res?duos Met6, Ala9, Gly10, Glu11, Arg14, Met53, Leu74, Phe118, Phe119, Pro120; grupamentos amino formaram pontes salinas com a carboxila do Glu11. Al?m disso, os res?duos Phe119, Asn29 e Gln69 formaram liga??es hidrog?nio, sendo que, este ?ltimo res?duo formou liga??es-H aceptoras e doadoras. Leishmaniose Lutzomyia Longipalpis Ecologia qu?mica Odorant-binding protein Modelagem comparativa Triagem virtual Leishmaniasis Chemical ecology Odorant-binding protein Comparative modeling Virtual screening CIENCIAS BIOLOGICAS::BIOLOGIA GERAL
124	Screening mutacional do gene HINT1 em uma amostra da população brasileira com quadro clínico de CMT recessivo / Mutational screening of the HINT1 gene in a sample of the Brazilian population with clinical picture of recessive CMT Rocha, Aline Marubayashi 27 June 2016 (has links) O grande grupo heterogêneo de neuropatias periféricas hereditárias estão entre os casos mais comuns de perda sensitiva e fraqueza muscular em crianças e adolescentes. Pelo menos 84 genes estão envolvidos com neuropatias sensitivo-motoras hereditárias (NSMH), sendo suas formas de herança mais comuns as autossômico-dominantes desmielinizante e axonal e as neuropatias ligadas ao cromossomo X, e as mais raras as autossômicorecessivas desmielinizante e axonal e as formas ainda não classificadas. O gene HINT1, possuinte de 3 exons e localizado no cromossomo 5, codifica a proteína Histidine triad nucleotide binding protein 1, uma variante transcricional (mRNA) regulatória que hidroliza substratos. Recentemente mutações em HINT1 foram também relacionadas à neuropatias axonais com neuromiotonia (ARCMT2-NM), e portanto à CMT. O objetivo deste trabalho foi realizar o screening mutacional do gene HINT1 em uma amostra da população brasileira com quadro clínico de CMT recessivo (CMT2-AR), e foram encontradas 1 mutação silenciosa já previamente descrita, 1 polimorfismo exônico e 1 polimorfismo intrônico, também já conhecidos. Concluiu-se que mutações no gene HINT1 não são portanto responsáveis pela CMT-AR nesta amostra da população brasileira. / The large heterogeneous group of inherited peripheral neuropathies are among the most common causes of sensory loss and muscle weakness in children and adolescents. At least 84 genes are involved in inherited sensorymotor neuropathies (NSMH), being the demyelinating and axonal autosomaldominant and the X-linked neuropathies their most common forms of inheritance, and the demyelinating and axonal autosomal-recessive and not yet classified forms the most rare ones. The HINT1 gene, with 3 exons and located on chromosome 5, encodes the protein Histidine triad nucleotide binding protein 1, a regulatory transcriptional variant (mRNA) that hydrolyzes substrates. Recently, mutations in HINT1 were also related to axonal neuropathy with neuromyotonia (ARCMT2-NM), and therefore to CMT. The objective of this study was the mutational screening of the HINT1 gene in a sample of the Brazilian population with clinical recessive CMT (CMT2-AR), and 1 silent mutation previously described, 1 intronic polymorphism and 1 exonic polymorphism, both also known, were founded. It was then concluded that mutations in the HINT1 gene are not responsible for CMT2-AR in this particular sample of the Brazilian population. ARCMT2-NM ARCMT2-NM HINT1 HINT1 mutação silenciosa silent mutation SNP sinônimo synonymous SNP
125	Identificação e caracterização de novos moduladores da divisão em Bacillus subtilis / Identification and characterization of new modulators of division in B. subtilis José Roberto Tavares 31 July 2009 (has links) Em procariotos, a principal forma de reprodução é a divisão binária, que permite à célula-mãe dar origem a duas outras células-filhas, com conteúdo genético idêntico ao da progenitora. Em Bacillus subtilis este processo acontece graças ao divisomo, um complexo formado por aproximadamente dezesseis proteínas, que leva à constrição da membrana e da parede, formando o septo de divisão. A montagem do divisomo é coordenada por FtsZ, um homólogo de tubulina, que polimeriza na região central da bactéria e serve de arcabouço para a montagem do divisomo. Partindo de um levantamento detalhado da distribuição dos genes envolvidos em divisão em genomas completos de procariotos detectamos que divIVA, um gene de divisão já bem caracterizado, apresentava um gene parálogo em B. subtilis, conhecido como ypsB. Para determinarmos se YpsB seria um novo componente do divisomo foi realizada uma caracterização citológica e funcional desta proteína. Utilizamos microscopia de fluorescência e fusões de YpsB a GFP para determinar a localização subcelular de YpsB. Estes experimentos revelaram que YpsB está presente no divisomo, apresentando um padrão de localização semelhante mas não idêntico ao de DivIVA. Medindo-se a taxa de co-localização entre o anel Z e YpsB ficou demonstrado que estas proteínas co-localizam em aproximadamente 50%, sugerindo que YpsB é recrutada depois que o anel Z é montado. Para determinar quando YpsB chega ao divisomo, usamos mutantes termo-sensíveis das proteínas de divisão que revelaram a dependência de YpsB pelo sub complexo DivIB-DivIC-FtsL-FtsW-PBP2B. Já na ausência de DivIVA, YpsB continua associado ao divisomo, indicando que não depende do seu parálogo para localizar. Além disso, análises de deleções de YpsB mostraram que a porção N-terminal da proteína é a mais importante para o seu recrutamento ao divisomo. Para determinarmos o papel de YpsB durante a divisão foi construído um mutante com deleção completa do gene. DivIVA é uma proteína responsável por localizar o sistema Min nos pólos da bactéria e assim contribui para a precisão espacial da divisão. Apesar de serem parálogos, a função de YpsB, no entanto, parece ser diferente da de DivIVA. Análise do mutante ypsB- mostrou que na sua ausência, o divisomo é montado e o seu posicionamento tanto em fase vegetativa como em esporulação não são afetados. Como a ausência de YpsB não afeta perceptivelmente a divisão, combinamos a mutação em ypsB com mutações em outros genes envolvidos em divisão. A análise destes duplos mutantes revelou que a ausência simultânea de YpsB e FtsA produz exacerbada lise celular e letalidade. Com base neste fenótipo e em evidências evolutivas, sugerimos que YpsB esteja envolvida na regulação da síntese de peptideoglicano do septo. Mais especificamente, YpsB seria responsável por modular a atividade de PBP1, uma enzima necessária para a síntese de peptideoglicano septal. / In prokaryotes, the main form of reproduction is binary fission, which allows the mother-cell to give origin the two daughter-cells, with identical genetic material. In Bacillus subtilis, this process is performed by the divisome, a complex formed for approximately sixteen proteins that leads to the constriction of the membrane and the wall, creating the division septum. The assembly of the divisome is coordinated by FtsZ, a homolog of tubulin, that polymerizes in the central region of the bacteria and serves as the base for the assembly of the divisome. From a detailed survey of the distribution of the genes involved in division in complete genomes of prokaryotes, we detected that divIVA, a well characterized division gene, showed a paralog in B. subtilis, known as YpsB. To determine if YpsB would be a new component of the divisome, a cytological and functional characterization of this protein was carried out. We used fluorescence microscopy and fusion of YpsB to GFP to determine the subcellular localization of YpsB. These experiments displayed that YpsB is present in the divisome, with similar but not identical localization as DivIVA. Measuring co-localization between the Z ring and YpsB demonstrated that this happened in approximately 50% of the cells, suggesting that YpsB go to the divisome after the Z ring is formed. To determine when YpsB goes to the divisome, we used temperature-sensitive mutants of the division proteins. This showed that YpsB depends on the DivIB-DivIC-FtsL-FtsW-PBP2B sub-complex to associate with the divisome. In the absence of DivIVA, YpsB is still present in the divisome, indicating that it does not depend on its paralog to localize. Moreover, deletion analyses of YpsB showed that the N-terminal portion of the protein is the most important for its recruitment to the divisome. To determine the role of YpsB during division, we constructed a ypsB- mutant. DivIVA is the protein responsible for localization of the Min system in polar regions of B. subtilis and, thus, contributes for the spatial precision of division. Our results showed that the function of YpsB must be different from that of DivIVA, since analysis of the ypsB- mutant showed that in the absence this protein the divisome is assembled and septum position in vegetatively growing or sporulating cells is not affected. Since the absence of YpsB does not affect division, we combined the ypsB- mutant with mutants involved in division. Analysis of these double mutants showed that the simultaneous absence of YpsB and FtsA caused cellular lysis and lethality. Based on this phenotype and evolutionary evidences, we suggest that YpsB is involved in the regulation of peptidoglycan synthesis in the septum. More specifically, YpsB would be responsible for modulating the activity of PBP1, a necessary enzyme for septum peptidoglycan synthesis. Bacillus Penicillin binding protein Bioquímica Divisão celular Divisomo DivIVA FtsZ Peptideoglicano YpsB Bacillus Biochemistry Cell division Divisome DivIVA FtsZ Penicillin binding protein Peptidoglycan YpsB
126	Isolation and Identification of O-linked-β-N-acetylglucosamine Modified Proteins (O-GlcNAc) in the Developing Xenopus laevis Oocyte Paspuleti, Sreelatha 08 November 2004 (has links) Oocyte development in Xenopus laevis spans six morphologically distinct stages (stage I-VI), and is associated with a decrease in protein O-GlcNAc levels. As a first step in elucidating the role of O-GlcNAc in developing oocytes, initial efforts were focused on isolation and identification of fifteen modified proteins that decrease during oocyte development. Stage I oocytes due to their high amounts of these proteins, were used as starting material for purification. Multiple affinity and specific antibody based purification technique were initially used in an attempt to enrich the O-GlcNAc proteins. Due to the unique properties of the proteins ultimately identified, these techniques were unable to provide sufficient material for sequencing. However, differential centrifugation coupled with 2D-gel electrophoresis was highly successful. The majority of isolated proteins were strongly basic in nature with pIs 8-10. Coomassie stained bands from 2D-analysis were trypsin digested, and peptides were sequenced by mass spectroscopy (Finnigan LCQ). Mass data were interpreted by Bioworks software, and protein sequences were compared to multiple protein databases. Initially, six proteins were identified as Thesaurin a (42Sp50), cytoplasmic mRNA binding protein p54, y-box homolog, Xp 54 (ATP dependent RNA helicase p54), Vg1 RNA binding protein variant A, Zygote arrest 1(Zar1) and Poly (A) binding protein (PABP). Thesaurin a, the main component of 42S particle of previtellogenic oocytes (stages I-III) is involved in tRNA storage and possess low tRNA transfer activity; y-box factor homolog and Xp54 are present in oocyte mRNA storage ribonucleoprotein particles; Vg1 RBP variant A associates mVg1 RNA to microtubules in order to translocate to the vegetal cortex; Zar1 is involved in oocyte-to-embryo transition; and PABP initiates mRNA translation. This study is the first to characterize these oocyte specific proteins as O-GlcNAc modified proteins. Overall, the presence of several O-GlcNAc proteins in oocytes, the reduction in their levels/ O-GlcNAc levels, and the variation in maturation time in the presence of HBP-flux modulators in developing oocyte indicates O-GlcNAc may play important roles in metabolism, cell growth and cell division of X. laevis oocytes. Therefore, identifying the remainder of these proteins and elucidating the O-GlcNAc role in their function is a worthwhile pursuit. Thesaurin a Cytoplasmic mRNA binding protein p54 Vg1 RNA binding protein variant A Zygote arrest 1 Two-dimensional gel electrophoresis American Studies Arts and Humanities
127	Insights Into Oxidative Folding Of Retinol Binding Protein In The Endoplasmic Reticulum : A Study In Isolated Microsomes Rajan, Sundar S 02 1900 (has links) The central role played by the Endoplasmic Reticulum (ER) in the correct folding and assembly of secretary and membrane proteins cannot be overstated. As the first compartment in the secretary pathway, it is responsible for the synthesis, modification and targeting of proteins to their proper destinations within the secretary pathway and the extracellular space. Protein folding in this specialized compartment is dynamic and involves a host of molecular chaperones and folding catalysts. Once inside the ER lumen, proteins fold into their native conformation and undergo a multitude of post-translational modifications, including N-linked glycosylation and disulfide oxidation. The proper conformational maturation of nascent proteins that traverse the secretary pathway is both aided and monitored by a complex process termed ER quality control. A variety of quality control mechanisms that rely on the chaperone systems operate in the ER. These act in close concert with the molecular machinery involved in degradation of non-native proteins to maintain homeostasis. The common goal of these mechanisms is to prevent expression and secretion of misfolded proteins. As a general rule, only those proteins that have successfully completed their folding and passed a stringent selection process are allowed to exit the ER on their way to their final destinations. The importance of the normal functioning of the ER is underlined by the fact that disruption in protein folding, resulting in ER stress, has now been identified as the biochemical basis of many ER storage diseases including Diabetes mellitus, Endocrinopathies and Hemophilia A. Processing events occurring inside the ER lumen are known to influence the efficiency of protein secretion. Vastly different rates of exocytose observed among secretary proteins have been found to correlate with the rate of exit from the ER. One such example is the interesting secretion property exhibited by Retinol Binding Protein (RBP) The principal carrier of retinol (Vitamin A) in plasma. RBP is a single domain protein consisting of three intramolecular disulfide bonds and helps transport retinol from the liver stores to the various target tissues in the body. Availability of its ligand, retinol, while not affecting its synthesis, is known to be the major factor in regulating RBP secretion from the liver. In the absence of retinol, apo-RBP has been shown to be retained in the ER by a hitherto unclear mechanism. Like most other secretary proteins, RBP is co-translationally targeted to the ER lumen, where it undergoes disulfide oxidation as the only modification. It has been shown to form a complex with another secretary protein, Transthyretin (TTR) in the ER and this complex formation is thought to prevent premature glomerular filtration of the otherwise small RBP with its bound retinol. Despite attaining a mature conformation, apo-RBP is not secreted and awaits conversion to its ligand-bound, holo form in order to exit the ER. It is widely believed that ligand binding may relieve this retention of RBP from the ER quality control machinery. However the precise mechanisms that mediate and regulate RBP folding, ligand binding, TTR assembly and secretion are not clearly understood. Though the folding and secretion properties of RBP have been described in HepG2 cells, its interactions with the ER resident chaperones have not been addressed. Apart from being an important cell biological question, the study of RBP assumes a lot of significance with its recent emergence as a key player in the pathogenesis of type 2 diabetes mellitus. It has been proposed that lowering of serum RBP levels could be a new strategy for treating type 2 diabetes mellitus. The present study was undertaken with the intention of analyzing the oxidative folding of RBP in the ER more closely. A systematic approach aimed at understanding the early events associated with folding and maturation of RBP, with particular emphasis on the role of ER-resident chaperones and the quality control machinery, is likely to provide interesting insights into the mechanisms involved in its ligand dependent secretion. Reconstitution of RBP biogenesis in a cell free system. The folding of RBP in cells is extremely quick with rapid oxidation kinetics. This makes it difficult to systematically analyze the early folding events in cultured cells. It was necessary to make use of a simplified system that would faithfully recapitulate the folding process in the ER. Therefore, a cell free translation system consisting of rabbit reticulocyte lysate and canine pancreatic microcosms as a source of ER-derived membranes was developed. This system affords the advantage of easy manipulation while still preserving the overall environment that prevails in the ER of intact cells. Extensive biochemical and functional characterization of the isolated microcosms was carried out and in vitro translation and microsomal translocation of RBP was established. Though initially confined to studies on membrane insertion and core glycosylate, the cell free system supplemented with microcosms has subsequently been used to analyze folding and assembly of a number of secretary and membrane proteins. A similar strategy has been adopted in the present study of RBP folding and maturation. Oxidative folding of RBP in isolated microcosms: Delineation of its disulfide oxidation pathway Using glutathione (GSSG) as the oxidant, co- and posttranslational disulfide oxidation of RBP was carried out in isolated microcosms. The ability to manipulate the redox status of this cell free system has helped to considerably slow down the oxidative folding of RBP so that a more careful analysis of the folding process could be performed. RBP was found to undergo oxidative folding with a t1/2 of 30 minutes and folding proceeded through at least one disulfide-bonded intermediate. Non-reducing SDS PAGE was used to resolve the folding intermediates. The pattern of oxidation was in good agreement with that reported earlier in HepG2 cells. No significant effect of retinol was observed on either the folding kinetics or the pattern of disulfide oxidation of RBP in isolated microsomes.A DTT sensitivity assay, used to probe the conformational maturity of folding RBP, revealed that RBP was capable of maturing into a DTT-resistant conformation in isolated microsomes. With the aid of disulfide mutants, the probable disulfide oxidation pathway of RBP in the ER has been determined. Single and double disulfide mutants of RBP were generated by site-directed mutagenesis and their posttranslational oxidation patterns were analyzed and compared with that of the wild type protein. Based on the results obtained, it was clear that the folding intermediate was made up of one of the two big disulfide loops and that the presence of both these loops was essential for RBP to fold into a fully oxidized, compact form. It has not been possible to determine the contribution of the third, smallest disulfide loop to the oxidative folding of RBP. Molecular events associated with the early oxidative folding of RBP To gain insights into the possible role of ER chaperones in the oxidative folding of RBP, the oligomeric state of folding RBP was analyzed by velocity sedimentation and chemical crosslinking assays. Velocity sedimentation analysis revealed that the reduced form of RBP was present in a large complex of size >100 S20,W. Upon disulfide oxidation, it readily dissociated from the complex and assumed a monomeric state. This was evident even during co-translational oxidation which suggested that RBP transiently associated with the large complex during its oxidative folding. Dynamic nature of this complex indicated that this could be a folding complex containing the chaperone machinery of the ER. These results were also supported by crosslinking analysis performed in unbroken microsomes using the homo-bifunctional crosslinker, DSP. The early folding forms of RBP could be crosslinked to a large complex while upon disulfide oxidation, RBP matured to its monomeric form and was no longer crosslinkable. Sedimentation and crosslinking analyses of the RBP disulfide mutants revealed that while the double disulfide mutant remained irreversibly associated with the large complex, the single mutants were released upon acquiring one of the two big disulfide loops. This suggested that despite the lack of one of the two major disulfides, these mutants were considered ‘folded’ by the quality control machinery in the ER while the double mutant probably resembled a molten globule state and was therefore considered ‘unfolded’ and irreversibly retained. Results from crosslinking analysis in microsomes not engaged in active translation suggested that chaperones of the ER were organized in a complex constitutively thereby lending support to the concept of ER-matrix, a large network of luminal proteins consisting of ER chaperones and accessory factors. Given this scenario, it is not unlikely that newly synthesized protein substrates transiently associate with this large pre-existing complex of chaperones and dissociate during late stages of their maturation. Conclusion In all, this study provides significant insights into some of the early events associated with the oxidative folding of RBP in the ER. The delineation of the disulfide oxidation pathway of RBP has been possible. The results obtained from this study suggest that RBP probably dissociates from the quality control quite early during its folding process and this step in its maturation might not be influenced by retinol. The stimulus for its ligant dependent secretion is likely to operate at a later stage of its sojourn in the ER, possibly consequent to positive cues from accessory binding factors such as TTR. Lastly, Perservation of the ER microenvironment in isolated microsomes, as evidenced from this study, augurs well for the use of this system to analyze mechanisms underlying folding, maturation, secretion and/or retention of secretory proteins. Endoplasmic Reticulum (ER) Retinol Binding Protein (RBP) Oxidative Folding Endoplasmic Reticulum Chaperones Secretory Proteins Microsomes Biochemistry
128	Studies On Polypyrimidine Tract Binding Protein : Identification Of Interacting Partners Ramesh, V 01 1900 (has links) PTB (HnRNP I) is a multifunctional RNA binding protein which participates in a variety of RNA metabolic processes put together called as post transcriptional gene regulation. It interacts with shuttling hnRNPs L, K and E2 of the spliceosomal machinery and also with other RNA binding proteins like PSF, Raver1 and Raver2, which assists PTB in splicing. Based on the complexity of these processes and multifunctional nature of PTB, we hypothesized that; it might interact with various additional proteins not identified till date. Keeping this objective in mind, we set out to screen the custom made 18 day old mouse testes cDNA library in pGAD10 vector available in the laboratory, to hunt for novel interacting partners of PTB using the Clontech’s Matchmaker Gal4 yeast two hybrid system III. PTB1, the prototype of PTB was chosen and the above mentioned cDNA library was screened for novel PTB interacting partners. Twenty five large scale library transformations (spanning 8*106 independent clones) were performed and 99 putatives were obtained. By re-transformation of these library plasmids with bait construct to check for the interaction phenotype and eliminating bait independent activation of reporter genes and elimination of known false positives, only 5 clones were consistent with the interaction phenotype. All these library plasmids were sequenced with vector specific primers, ORF was identified and BLAST analysis for the identification of insert was done. Two of these clones encoded the partial CDS of mouse Protein Inhibitor of Activated STAT3-PIAS3. One of these encoded the partial CDS of mouse TOLL Interacting Protein-TOLLIP. The other two encoded the partial CDS of mouse importin-α and mouse hnRNP K, both of which were already known interacting partners of PTB. GST pull down assay and mammalian matchmaker co-immunoprecipitation was used for confirming the in vitro one to one physical interaction between PTB and these newly identified protein partners. Indirect Immunofloresence was used for demonstrating the co-localization of PTB and PIAS3 in Gc1Spg mouse spermatogonial cell line. The fact that PIAS3 an E3 SUMO ligase was picked up as an interacting partner of PTB was interesting and we hypothesized that PTB might be a sumoylation substrate. Towards this, we first resorted to the prediction of sumoylation consensus motif by using SUMOPLOT. PTB indeed was found to have sumoylation consensus sites. Subsequently, in vivo sumoylation of PTB was demonstrated, where in over expression of donor protein [SUMO-1] and acceptor protein [PTB] in RAG-1 mouse kidney cell line had resulted in the identification of an approximately 67 kDa slow moving SUMO modified myc tagged PTB band apart from the bulk of unmodified 57 kDa myc-PTB. This confirmed the fact that PTB is SUMO modified only at a single consensus target site in vivo and attempts are made to map this site of modification. SUMOylation regulates diverse biological processes in vivo ranging from nucleo- cytoplasmic shuttling, alteration of protein-protein interaction, DNA protein interaction etc. PTB shuttles rapidly between the nucleus and cytoplasm in a transcription sensitive manner and the translocation of PTB to the cytoplasm, happens under the conditions of cell stress, viral infections, apoptosis and exposure of cells to genotoxic agents like doxorubicin. Phosphorylation of PTB at Ser-16 residue has been shown to modulate the nucleo-cytoplasmic shuttling of PTB, albeit shuttling can also occur irrespective of this modification. Interaction of PTB with an E3 SUMO ligase-PIAS3 and the fact that it is SUMOylated in vivo, we hypothesize that K-47 residue present in the NLS/NES might be the most probable site of this SUMO modification and SUMOylation of PTB by PIAS3 might regulate the nucleo-cytoplasmic shuttling of PTB. Proteins RNA Binding Protein Plasmid DNA Gene Regulation Messenger Ribo Nucleic Acid (mRNA) Biochemistry
129	The characterization of the cytoskeleton and associated proteins in the formation of wound-induced contractile arrays / Stromme, Adrianna. January 2008 (has links) The cytoskeleton is an intrinsic aspect of all cells, and is essential for many cellular events including cell motility, endocytosis, cell division and wound healing. Remodeling of the cytoskeleton in response to these cellular activities leads to significant alterations in the morphology of the cell. One such alteration is the formation of an actomyosin contractile array required for cytokinesis, wound healing and embryonic development. / Cellular structure and shape depends upon tensional prestress brought about by the organization of cytoskeletal components. Using the Xenopus laevis oocyte wound healing model, it is first described how diminished cellular tension affects the balance of the Rho family of GTPases, and subsequently prevents the formation of actomyosin contractile arrays. This suggests that cellular tension in the cell is not created at the level of the cytoskeletal elements but rather via the upstream signaling molecules: RhoA and Cdc42. / The role of N-WASP (Neural-Wiscott Aldrich Syndrome Protein), a mediator of Arp2/3 based actin polymerization, is next examined for its putative role in cellular wound healing. Xenopus laevis oocytes injected with mutant N-WASP constructs reveals in vivo evidence that functional N-WASP is required for appropriate contractile array formation and wound closure. / Lastly, it is revealed that the cellular structures involved with single cell wound healing in other model systems are also important for the initial repair of severed muscle cells. Actin, non-muscle myosin-II, microtubules, sarcomeric myosin and Cdc42 are all recruited and reorganized at the edge of damaged C2C12 myotubes. This data promotes the possibility that an actomyosin array may be established in injured muscle cells as well. Actomyosin -- physiology. Contractile Proteins -- physiology. Wound Healing -- physiology. cdc42 GTP-Binding Protein -- metabolism. rhoA GTP-Binding Protein -- metabolism. Oocytes -- physiology. Xenopus laevis.
130	Studies on the regulatory roles of cholesterol and bile acids / Murphy, Charlotte, January 2007 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.

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