Global ETD Search

141	Structural Studies on Heat Shock Protein 90 from Dictyostelium Discoideum and Oryza Sativa Raman, Swetha January 2014 (has links) (PDF) Molecular chaperones are proteins that interact with and aid in stabilization and activation of other proteins. Chaperones help proteins attain their three dimensional conformation, without forming a part of the final structure. Many of the chaperones are stress proteins known as Heat shock proteins (Hsps). Their expression is upregulated in response to various kinds of stress such as heat stress, oxidative stress etc., which threaten the protein homeostasis, by structurally destabilizing cellular proteins, and increasing the concentration of aggregation-prone folding intermediates. The Hsps are classified according to their molecular weight into Hsp40, Hsp60, Hsp70, Hsp90, Hsp100, and the small Hsp families. Some of them are constitutively expressed and play a fundamental role in de novo protein folding. They further aid in proteome maintenance by assisting in oligomeric assembly, protein trafficking, refolding of stress denatured protein, preventing protein aggregation and protein degradation. Heat shock protein 90 (Hsp90) are one of the important representatives of this class of proteins. Hsp90 are highly conserved class of molecular chaperones. They are found in bacteria, eukaryotes, but not in archaea. In contrast to the eukaryotes which require a functional cytoplasmic Hsp90 for viability, the bacterial counterpart (HtpG) is typically nonessential. Hsp90 is an ATP dependent chaperone. Hsp90 form dimers, with each protomer consisting of three functional domains: N- terminal, ATP binding domain, Middle domain and C-terminal domain. Hsp90 is a dynamic protein, and undergoes an elaborate conformational cycle during its ATPase cycle, which is essential for its chaperoning activity. The Hsp90 chaperone cycle is regulated by interaction with diverse cochaperones. Hsp90 interacts with specific set of substrate proteins. Many of these substrate proteins function at the heart of several cellular processes like signalling, cell cycle, apoptosis. Studies from protozoans like Leishmania, Plasmodium, Trypanosoma etc. have also implicated the role of Hsp90 in their growth and stage transitions. Thus, selective inhibition of Hsp90 has been explored as an intervention strategy against important human diseases such as cancer, malaria and other protozoan diseases. The ATP binding N-terminal domain (NTD), has been explored as the target domain for inhibition of Hsp90 using competitive inhibitors of ATP. Several chemical classes of Hsp90 inhibitors are known, including ansamycins, macrolides, purines, pyrazoles, and coumarin antibiotics. However, many inhibitors are observed to be toxic, less soluble and unstable. Hence, there is a requirement for new approach to design inhibitors which are more soluble and less toxic and serve as effective therapeutic drugs.inhibitors are observed to be toxic, less soluble and unstable. Hence, there is a requirement for new approach to design inhibitors which are more soluble and less toxic and serve as effective therapeutic drugs. The work presented in this thesis mainly concerns with the structural studies and biochemical and biophysical characterization of Hsp90 from two different sources viz. Dictyostelium discoideum, a cellular slime mould and a plant source Oryza sativa (rice). The structural analyses of these two proteins have been carried out by X-ray crystallography. Though yeast has been explored extensively as a model system to understand the different roles of Hsp90, it lacks the various signalling pathways essential for growth and development present in case of higher eukaryotes. D. discoideum has been employed as a model system to understand multicellular development, which occurs in response to starvation induced stress. D. discoideum has the advantages due to its ease of manipulation. The organism's genome also shows many signalling pathway for growth and differentiation that are conserved between D. discoideum and mammals. With this motivation, we have studied several structural aspects of the cytosolic isoform of Hsp90 from D. discoideum called HspD. HspD was also observed to play a role in the multicellular development of D. discoideum. It has been demonstrated that the treatment of D. discoideum with inhibitors like Geldanamycin or Radicicol causes an arrest in the multicellular development at the mound stage, and the few which escaped this arrest gave rise to abnormal fruiting bodies. A subset of the proteins involved in this mound arrest phenotype, were observed to have homologs in humans, which are clients of Hsp90. Therefore, a structural perspective of HspD can aid in better understanding of the role of this protein in the organism, as well as, elucidate any structural differences observed as compared to other species, which may have an impact on its activity. Studies on the physiological role of Hsp90 in plants began much later as compared to fungi and humans. In plants Hsp90 are involved in various abiotic stress responses. In addition, their roles have also been implicated in plant growth and development, innate immune response and buffering genetic variations. However, the molecular mechanisms of these various actions are not clearly understood. Also, the structural aspects of plant Hsp90 are yet to be explored. The structure of the NTD of Hsp90 from barley is the only one available from a plant source till now. We have initiated the studies on rice Hsp90 with the objective to understand the mechanism of Hsp90 in plants, which may aid in improving stress tolerance in plants. The thesis has been divided into five chapters. The first chapter introduces the various aspects of Hsp90 protein. The chapter starts with a general overview of concept of molecular chaperones and describes briefly the different classes of molecular chaperones. This is followed by a detailed description of different aspects of Hsp90 with main emphasis on the structure and its conformational flexibility. The chapter describes the association of Hsp90 with other accessory proteins like cochaperones and its interaction with its substrate proteins and explains the functional significance of Hsp90 as a drug target and the need for the development of new class of inhibitors, followed by the significance of the study of Hsp90 in the two model systems (D. discoideum and rice) chosen to be studied. The second chapter gives a brief overview of the principles behind the different experimental methods employed during the course of this research, which includes the tools of X-ray crystallography and other biochemical and biophysical techniques employed for the characterization of the protein. Chapter 3 describes the crystal structure of NTD of Hsp90 from D. discoideum. The structure of NTD was solved in two different native (ligand-free) forms viz. monoclinic and hexagonal. The two forms differed in local structural rearrangement of a segment of NTD known as the lid region. The lid region in the hexagonal form showed a shift in its position as compared to the other solved structures of NTD. The structure of NTD was also solved in complex with various ligands which include ADP, substrate analogs and an inhibitor molecule. A comparison of all the structures showed that the overall structure is well-conserved. One of the crystal structures of NTD showed a heptapeptide (part of the vector) bound at the active site. The peptide was observed to make several complementary interactions with the residues of the ATP binding pocket and retain several interactions which the nucleotide makes with the NTD. The NTD showed subtle conformational differences when compared with the NTD of Hsp90 from yeast. Chapter 4 details the structural and functional characteristics of full length Hsp90 protein from D. discoideum. Due to the large size and flexibility, the full length protein did not crystallize in spite of several attempts. Hence, HspD was studied using different solution studies like Small Angle X-ray Scattering (SAXS) and Dynamic Light Scattering (DLS). Both the studies showed the presence of higher oligomers. The SAXS data showed the presence of tetramers and hexamers while, the addition of the ligand shifts the protein from a dimer to a higher oligomer as observed from DLS studies. The chapter also describes the study of interaction of HspD with a cochaperone protein p23. The interactions were studied using ITC, which showed a strong binding. The ATPase activity was also evaluated in the presence of increasing concentrations of p23, which was observed to decline with increasing concentrations of p23. In chapter 5, we describe the biochemical characterization of Hsp90 from Oryza sativa (rice) and the crystallographic analysis of its NTD. Binding of the rice Hsp90 to ATP and an inhibitor were studied by fluorescence. The ATPase activity of rice Hsp90 was checked by radioactive assay and the protein was observed to be active. The NTD of rice Hsp90 crystallized as a monomer in complex with a substrate analog AMPPCP and the structure was determined. Oryza Sativa (Rice) Heat Shock Proteins Molecular Chaperones Heat Shock Proteins Heat Shock Protein 90 (Hsp90) Chaperone Proteins Heat Shock Protein D. Discoideum (HspD) Microbial Heat Shock Proteins Plant Heat Shock Proteins Dictyostelium discoideum Hsp90 Oryza sativa Hsp90 Molecular Biophysics
142	In Situ Hybridization of 70 kD Heat Shock Protein mRNA in a Rat Model of Ethanol Self-Administration Ott-Reeves, Ellen (Ellen Theresa) 12 1900 (has links) Sucrose fading was used to initiate self-administration of ethanol on an FR4 schedule in male Fischer 344 rats. Rats showed low response rates for ethanol alone. After administration of liquid diet containing ethanol, ethanol intake increased over levels prior to administration of the liquid diet. In situ hybridization compared mRNA for the inducible or constitutive 70 kD heat shock proteins in ethanol and nonethanol rats. Both inducible and constitutive mRNAs were found in nonethanol and ethanol tissues. In peripheral organs, radiolableling was higher in ethanol tissue. In brain regions, nonethanol tissues showed higher radiolabeling. molecular biology physiological effect ethanol heat shock proteins messenger RNA Alcohol -- Physiological effect. Heat shock proteins. Messenger RNA. Mice -- Effect of chemicals on.
143	Involvement of poly(A)-binding and heat shock 70 kDa proteins in Turnip mosaic virus infection Dufresne, Philippe J. January 1900 (has links) Thesis (Ph.D.). / Written for the Dept. of Plant Science. Title from title page of PDF (viewed 2008/01/12). Includes bibliographical references.
144	Caracterização estrutural e funcional das chaperonas Hsp100 e Hsp90 de Saccharum spp. (cana-de-açúcar) / Structural and functional characterization of the Hsp90 and Hsp100 chaperones from Saccharum spp. (sugarcane) Silva, Viviane Cristina Heinzen da, 1984- 22 August 2018 (has links) Orientador: Carlos Henrique Inácio Ramos / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-22T11:29:26Z (GMT). No. of bitstreams: 1 Silva_VivianeCristinaHeinzenda_D.pdf: 5558657 bytes, checksum: 719a2c54c3d42be8642a0beb9014221c (MD5) Previous issue date: 2013 / Resumo: As chaperonas moleculares estão envolvidas na manutenção da homeostase celular, auxiliando no correto enovelamento de proteínas, e consequentemente em sua funcionalidade. Duas famílias de chaperonas moleculares participam de pontos-chave neste sistema. Uma delas é a Hsp100 que tem papel importante na desagregação de proteínas; a outra é a Hsp90 que tem o papel de auxiliar no enovelamento, ativação, e na translocação de proteínas regulatórias e sinalizadoras. Neste trabalho foram caracterizadas as chaperonas Hsp100 e Hsp90 de cana-de-açúcar, denominadas SHsp101 e SsHsp90, respectivamente, cuja expressão em níveis basais foi detectada em tecido foliar. As proteínas recombinantes foram produzidas em Escherichia coli, de maneira solúvel, e após purificação apresentaram-se enoveladas. A SHsp101 foi obtida como um hexâmero em solução, apresentando capacidade de ligar nucleotídeos ATP e ADP, e de hidrolisar o ATP de maneira alostérica com cooperatividade positiva; mas não foi capaz de hidrolisar o ADP, que por sua vez mostrou-se inibidor da atividade ATPásica. A SHsp101 exibiu atividades de proteção do substrato luciferase contra agregação induzida por alta temperatura e de desagregação e reenovelamento da proteína-modelo GFPuv, na presença de ATP e ATP?S. Análises de complementação in vivo revelaram que a superexpressão heteróloga de SHsp101 em cepas de levedura mutantes nulo de hsp104, aumentou a termotolerância a 53°C, proporcionando um aumento de 80 vezes na sobrevivência das leveduras. A SsHsp90 apresentou-se dimérica em solução, com características estruturais e conformacionais (modelo tridimensional gerado por modelagem comparativa e validado por meio de análises de ligação cruzada acoplada à espectometria de massas) semelhantes às homólogas de outros organismos. A SsHsp90 apresentou atividade chaperona de proteção contra agregação da proteína-modelo citrato sintase desnaturada por choque térmico. As informações acerca da expressão, estrutura, e função de SHsp101 e SsHsp90 obtidas neste trabalho, contribuem para um melhor entendimento destas famílias de chaperonas moleculares, particularmente em plantas, que por serem organismos sésseis, estão mais expostos às condições adversas do ambiente / Abstract: Molecular chaperones are involved in the maintenance of cellular homeostasis by promoting the correct folding of proteins, and consequently, ensuring their functionality. Two families of molecular chaperones participate at key points in this system. The first is Hsp90, which assists in protein refolding, activation, and the trafficking of regulatory and signaling proteins, while the second is Hsp100, which has an important role in protein disaggregation. In this study, the Hsp90 and Hsp100 proteins from sugarcane were characterized, denoted as SsHsp90 and SHsp101, respectively, and their basal level of expression was detected in leaf tissue. In addition, both were produced by Escherichia coli as soluble form and then they were purified in a folded state. The SHsp101 was obtained folded as hexamer in solution and showed capacity of bind both ATP and ADP, but could only hydrolyze ATP in an allosteric manner with positive cooperativity. In fact, the presence of ADP had an inhibitory effect on the ATPase activity. SHsp101 exhibited protection against aggregation of luciferase, and showed a disaggregation and refolding activity of GFPuv in the presence ATP and ATP?S. In vivo complementation analysis revealed that heterologous overexpression of SHsp101 in a null hsp104 yeast strain correlated with an 80 fold increase in yeast survival at 53°C. The dimer obtained for SsHsp90 had similar structural and conformational characteristics compared to other Hsp90 homologues, and was compatible with a three-dimensional model generated by comparative modeling, which was validated by cross-linking coupled to mass spectrometry. The SsHsp90 protected against thermal aggregation of citrate synthase. Taken together, the information about the expression, structure, and function of SHsp101 and SsHsp90 obtained in this study contribute to a better understanding of these molecular chaperone protein families, particularly in plants, which are sessile organisms and more exposed to adverse environmental conditions / Doutorado / Bioquimica / Doutora em Biologia Funcional e Molecular Chaperonas moleculares Proteínas de choque térmico HSP90 Proteínas de choque térmico HSP100 Cana-de-açúcar Molecular chaperones HSP90 Heat-shock proteins HSP100 Heat-shock proteins Sugarcane
145	Lactate Impairs Vascular Permeability by Inhibiting HSPA12B Expression via GPR81-Dependent Signaling in Sepsis Fan, Min, Yang, Kun, Wang, Xiaohui, Zhang, Xia, Xu, Jingjing, Tu, Fei, Gill, P Spencer, Ha, Tuanzhu, Williams, David L., Li, Chuanfu 01 October 2022 (has links) Introduction: Sepsis impaired vascular integrity results in multiple organ failure. Circulating lactate level is positively correlated with sepsis-induced mortality. We investigated whether lactate plays a role in causing endothelial barrier dysfunction in sepsis. Methods: Polymicrobial sepsis was induced in mice by cecal ligation and puncture (CLP). Lactic acid was injected i.p. (pH 6.8, 0.5 g/kg body weight) 6 h after CLP or sham surgery. To elucidate the role of heat shock protein A12B (HSPA12B), wild-type, HSPA12B-transgenic, and endothelial HSPA12B-deficient mice were subjected to CLP or sham surgery. To suppress lactate signaling, 3OBA (120 μM) was injected i.p. 3 h before surgery. Vascular permeability was evaluated with the Evans blue dye penetration assay. Results: We found that administration of lactate elevated CLP-induced vascular permeability. Vascular endothelial cadherin (VE-cadherin), claudin 5, and zonula occluden 1 (ZO-1) play a crucial role in the maintenance of endothelial cell junction and vascular integrity. Lactate administration significantly decreased VE-cadherin, claudin 5, and ZO-1 expression in the heart of septic mice. Our in vitro data showed that lactate (10 mM) treatment disrupted VE-cadherin, claudin 5, and ZO-1 in endothelial cells. Mechanistically, we observed that lactate promoted VE-cadherin endocytosis by reducing the expression of HSPA12B. Overexpression of HSPA12B prevented lactate-induced VE-cadherin disorganization. G protein-coupled receptor 81 (GPR81) is a specific receptor for lactate. Inhibition of GPR81 with its antagonist 3OBA attenuated vascular permeability and reversed HSPA12B expression in septic mice. Conclusions: The present study demonstrated a novel role of lactate in promoting vascular permeability by decreasing VE-cadherin junctions and tight junctions in endothelial cells. The deleterious effects of lactate in vascular hyperpermeability are mediated via HSPA12B- and GPR81-dependent signaling. animals cadherins metabolism capillary permeability claudin-5 endothelial cells HSP70 heat-shock proteins heat-shock proteins lactic acid mice receptors G-protein-coupled genetics sepsis Surgery Surgery
146	Non-neuronal expression of transient receptor potential type A1 (TRPA1) in human skin Atoyan, R., Shander, D., Botchkareva, Natalia V. January 2009 (has links) No Calcium Channels Fluorescent antibody technique Gene expression profiling HSP27 heat-shock proteins HSP90 heat-shock proteins Humans Nerve tissue proteins Pyrimidinones Skin Transient receptor potential channels
147	Remifentanil induces delayed cardioprotection in the rat against ischaemic and reperfusion injury via Kappa, delta, mu opioid receptorsand inducible heat shock protein 70 Yu, Che-kwan., 俞治均. January 2007 (has links) published_or_final_version / abstract / Anaesthesiology / Master / Master of Philosophy Opioids. Opioids - Receptors. Heat shock proteins. Myocardial infarction - Animals models. Ischemia. Reperfusion injury.
148	Glucose-regulated protein 78 as a novel target of BRCA1 for inhibitingstress-induced apoptosis Kwan, Wai-yin., 關偉然. January 2009 (has links) published_or_final_version / Biological Sciences / Master / Master of Philosophy Tumor suppressor proteins. Heat shock proteins. Small interfering RNA. Gene expression. Apoptosis.
149	Characterization of HSP47 Expression in <i>Xenopus Laevis</i> Cell Culture and Embryos Hamilton, Amanda January 2005 (has links) The heat shock or stress response is a transient response to stressful stimuli that protects vital cellular proteins from damage and irreversible aggregation. Heat shock proteins (Hsps) are molecular chaperones that bind to unfolded protein and inhibit their aggregation, thereby maintaining their solubility until they can be refolded to their native conformation. Hsp47 is an endoplasmic reticulum (ER)-resident protein that serves as a molecular chaperone during collagen production. Collagen is the major class of insoluble fibrous protein found in the extracellular matrix and in connective tissues. It is the single most abundant protein of the animal kingdom; at least 14 different forms exist, each with distinct structures and binding properties. The various types of collagen all possess protein regions with the distinct triple helical conformation. This complex physical structure requires very organized assembly and HSP47 has been established as an integral component of this process for collagen types I-V. Most of the previous studies examining the expression and function of hsp47 have been conducted with mammalian cultured cells. The present study represented the first investigation of the expression of hsp47 in the poikilothermic vertebrate, <i>Xenopus laevis</i>. Full-length <i>Xenopus</i> hsp47 nucleotide and amino acid sequences were obtained from Genbank and compared with hsp47 from chicken, mouse, rat, human and zebrafish. <i>Xenopus</i> HSP47 protein had an identity of approximately 77% with chicken, 73% with mouse, 72% with rat and human, and 70% with zebrafish. Most of the sequence identity between HSP47 from all investigated organisms occurred centrally in the amino acid sequence and in several carboxyl terminal regions. Three key features were conserved between HSP47 proteins from most species investigated: a hydrophobic leader sequence, two potential glycosylation sites and the ER-retention signal, RDEL. A partial cDNA clone encoding <i>Xenopus</i> hsp47 was obtained from the American Type Culture Collection (ATCC) and used to generate hsp47 antisense riboprobe for the purpose of investigating hsp47 mRNA accumulation in <i>Xenopus</i> A6 kidney epithelial cells and embryos. Northern blot analysis detected hsp47 mRNA constitutively in A6 cells. The expression pattern for hsp47 mRNA was compared with two other <i>Xenopus</i> heat shock proteins that have been previously characterized in our laboratory: hsp70, a cystolic/nuclear hsp and BiP, an ER-resident hsp. The results of hsp47 mRNA accumulation in A6 cells suggested that the expression pattern for <i>Xenopus</i> hsp47 was unique but, with respect to some stressors, resembled that of a cytosolic hsp rather than an ER-resident hsp. HSP47 protein levels were also examined in A6 cells. Heat shock, sodium arsenite and b-aminopropionitrile fumerate treatments enhanced hsp47 accumulation. In some experiments, western blot analysis revealed the presence of two closely sized protein bands. It is possible that minor differences in HSP47 protein size may be due to post-translational modification, namely phosphorylation or glycosylation. The present study also examined the accumulation and spatial pattern of hsp47 mRNA accumulation during <i>Xenopus laevis</i> early development. Hsp47 was constitutively expressed throughout <i>Xenopus</i> early development. Constitutive levels of hsp47 mRNA in unfertilized eggs, fertilized eggs and cleavage stage embryos indicated that these transcripts were maternally inherited. Constitutive hsp47 mRNA accumulation was enhanced in neurula and tailbud embryos compared to earlier stages. This finding may be explained by the shift towards organogenesis during these stages. Whole mount <i>in situ</i> hybridization revealed hsp47 message along the dorsal region of the embryo, in the notochord and somites, as well as in the head region including the eye vesicle. Hsp47 mRNA induction in <i>Xenopus</i> embryos was also examined in response to heat shock. Hsp47 mRNA accumulated in response to heat shock immediately following the midblastula transition (MBT). In tailbud stages, hsp47 mRNA accumulated in the notochord, somites and head region. Northern blot analysis and whole mount <i>in situ</i> hybridization results revealed an expression pattern that coincided well with the development of collagen-rich tissues thereby substantiating the proposed role of HSP47 as a procollagen molecular chaperone. Molecular Biology Biology hsp47 heat shock proteins endoplasmic reticulum Xenopus laevis
150	Loss of chaperone protein in human cancer Adighibe, Omanma January 2012 (has links) TRAP1 is a Heat Shock Protein (HSP) chaperone to retinoblastoma but also associated to the tumor necrosis factor receptor. HSPs are primarily up regulated in cancer. Work in our lab noted a down regulation of TRAP1 in some non-small cell lung cancers compared to normal lung. The first aim of this project was to evaluate the effect of the loss of TRAP1 on cell proliferation using a spheroid model. The presence of TRAP1 in spheroids promoted cell proliferation and a faster onset of hypoxia. This suggests an oncogenic role for TRAP1 since rapid hypoxia development equates to poor prognosis. Micro array analysis showed that TRAP1’s loss was associated with increased transcrpition of the Junctional Mediating and Regulatory protein (JMY). JMY possesses an oncogenic property due to its ability to facilitate cell motility. Additionally it has tumor suppressor activity in promoting p53 activation. The second aim of this project was to produce an anti-JMY antibody and use it to characterize JMY and additionally verify the association between TRAP1 and JMY. JMY was found to be widely expressed in normal tissues and in many types of tumors. In neoplastic tissues, comparing primary versus metastatic tumors, JMY was found to have significantly higher expression in the metastatic compared with the primary tumors. A pilot study showed that nuclear co-expression of JMY and P53 was associated with shorter overall survival suggesting that a possible tumorigenesis mechanism could be via a deregulation/mutation of JMY/p53 or both. Finally, using 3 dimensional constructions, I demonstrated the distinct morphological difference between an angiogenic tumor and a non-angiogenic tumor. Additionally, I showed a characteristic cytoplasmic p53 sequestration in the non-angiogenic phenotype that is absent in the angiogenic phenotype. This could be the mechanism that the non-angiogenic tumor uses to adapt to hypoxia. This would imply that there is a potential for cancers to escape therapy by switching between these 2 phenotypes. 616.994

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