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The Role Of Small Heat Shock Proteins Of The Thermoacidophilic Archaeon Thermoplasma Volcanium In The Stress ResponseAygar, Sema 01 June 2011 (has links) (PDF)
In this study, possible involvement of the small heat shock proteins (sHsps) from a thermoacidophilic archaeon, Thermoplasma (Tp) volcanium in the stress response was investigated. Our results showed that heterologous, high level
expression of TVN0775/sHsp gene in E.coli increased its thermotolerance at 53° / C for two hours. But, the second sHsp of the Tp. volcanium, TVN0984/sHsp was not effective in improvement of the thermal resistance of the mesophilic bacterium (i. e., E.coli). The expression of the TVN0775/sHsp and TVN0984/sHsp genes increased about 3 fold after heat-shock at 65° / C, as revealed by Real-Time PCR analysis.
Although expression of the both genes was induced at 70° / C, TVN0984/sHsp gene expression was increased higher (about 5 fold) than that of the TVN0775/sHsp gene expression (about 1.5 fold). Tp. volcanium cells were exposed to high pH (pH: 3.5, pH: 4.0, pH: 4.5, pH: 5.0), and the change in the sHsp genes&rsquo / expression profile were analyzed. The results
showed that TVN0775/sHsp gene expression was more sensitive to increased pH than TVN0984/sHsp gene expression. The TVN0775/sHsp gene transcription
induced at most 2.5 fold at pH 4.0 and the gene expression either reduced or did not change at higher pH values (i.e., pH 4.5 and 5.0). On the other hand, TVN0984/sHsp gene expression did not change at pH 4.0 but significantly
reduced at higher pH values. The effect of oxidative stress on the expression of TVN0775 and TVN0984 genes
was investigated by treatment of Tp. volcanium cells with 0.01 mM, 0.02 mM, 0,03 mM and 0.05 mM H2O2. For both sHsp genes, transcription was induced at lower concentrations of H2O2 (0.01 mM and 0.02 mM). At higher concentrations of H2O2 expression of both genes&rsquo / transcription either did not changed or down
regulated. Lastly, in this study we have purified the recombinant TVN0775/sHsp, as an Nterminal
6x his-tag fusion to homogeneity on Ni-NTA affinity column. Purified protein samples were used in the chaperone activity assays using bovine glutamate dehydrogenase enzyme (boGDH) as substrate. We have found that the recovery of glutamate dehydrogenase activity at 45° / C, 50° / C and 53° / C in the presence of the Tp. volcanium sHsps was higher than that of spontaneous refolding. Also, TVN0775/sHsp increased the recovery of the boGDH enzyme that was denatured at 2.5 M GdnHCl concentrations for 30 min.
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Small Heat Shock Proteins from Oryza Sativa and Salmonella EntericaMani, Nandini January 2014 (has links) (PDF)
Small heat shock proteins (sHSPs) are a ubiquitous family of molecular chaperones that play a vital role in maintaining protein homeostasis in cells. They are the first line of defence against the detrimental effects of cellular stress conditions like fluctuations in temperature, pH, oxidative and osmotic potentials, heavy metal toxicity, drought and anoxia. Many sHSPs are also constitutively expressed during developmental stages of different plant tissues.
Members of this family are ATP-independent chaperones, with monomeric masses varying from 12-40 kDa. A characteristic feature of sHSPs is their ability to assemble into large oligomers, ranging from dimers to 48-mers. Under stress conditions, these oligomers dissociate and/or undergo drastic conformational changes to facilitate their binding to misfolded substrate proteins in the cell. This interaction prevents the substrate from aggregating during stress. When physiological conditions are restored, the substrates are transferred to other ATP-dependent heat shock proteins for refolding. Thus sHSPs do not refold their substrates, but instead prevent them from aggregating and maintain them in a „folding-competent‟ state. The clientele of sHSPs includes proteins with a wide range of molecular masses, secondary structures and pIs. This promiscuity has led to sHSPs occupying key positions in the protein quality control network. As molecular chaperones that protect proteins, sHSPs prevent disease. Concomitantly, mutations in sHSPs have also been linked to various human diseases.
Till date, high resolution crystal structures are available only for 3 sHSP oligomers. This insufficiency of structural information has hindered our understanding of the mechanism of chaperone function, the link between the oligomeric status and chaperone activity, identification of substrate binding sites and the role of the flexible terminal segments in mediating both the oligomerization and chaperone function. We undertook structural and functional characterization of plant and bacterial sHSPs in order to address some of these questions.
Chapter 1 of this thesis gives an overview of the sHSP family, with special emphasis on the oligomeric assemblies of sHSPs of known structures. We highlight what we know about this family through mutational studies, what is as yet unknown, and why it is important to study this family.
Chapter 2 describes our efforts at structural and functional characterization of 5 sHSPS in rice, each targeted to a different organelle. We probed the role played by the N-terminal region in mediating oligomer assembly and in the chaperone activity of the protein. Rice sHSPs displayed a wide range of hydrodynamic radii, from 4 nm to 14 nm, suggesting that their oligomeric assemblies are likely to be diverse.
In chapter 3, we discuss our attempts at the structural characterization of a bacterial sHSP, Aggregation suppressing protein A, or AgsA from Salmonella enterica. We obtained a high resolution crystal structure of the dimer of the core sHSP domain. We compared this dimer with other known sHSP dimers, reported the deviations that we observed and analysed the structure to account for these differences. We used this dimer structure to successfully obtain solutions for low resolution X-ray diffraction data for oligomers of different truncated constructs of AgsA. We observed that a C-terminal truncated construct formed an octahedral 24¬mer (4.5 Å resolution), whereas a construct truncated at both termini formed a triangular bipyramidal 18-mer (7.7 Å resolution), an assembly hitherto unobserved for any sHSP. A similar 18-mer was obtained when the C-terminal truncated construct was incubated with a dipeptide prior to crystallisation (6.7 Å resolution). The cryo-EM map of the wild type protein (12 Å resolution) could be fitted with a different 18-mer. The low resolution of the data pre-empted an atomic-level description of the interfaces of the assemblies. However, our work highlights the structural plasticity of this protein and probes the sensitivity of the oligomeric assembly to minor differences in construct length.
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Non-canonical small heat shock protein activity in health and disease of C. elegansIburg, Manuel 22 February 2021 (has links)
Die erfolgreiche Synthese und Faltung von Proteinen ist eine Voraussetzung der Zellfunktion und ein Versagen der Proteinhomöostase führt zu Krankheit oder Tod. In der Zelle sichern molekulare Chaperone die korrekte Faltung der Proteine oder tragen zur Entsorgung unwiederbringlich fehlgefalteter Proteinsubstrate bei. Unter diesen Chaperonen sind kleine Hitzeschockproteine (sHsp) ein ATP-unabhängiger Teil des Proteostasenetzwerks.
In dieser Arbeit habe ich das bisher wenig erforschte sHsp HSP-17 aus C. elegans untersucht. Im Gegensatz zu anderen sHsps zeigte HSP-17 nur eine geringe Aktivität beim Verhindern der Aggregation von Proteinsubstraten. Stattdessen konnte ich in vitro zeigen, dass HSP-17 die Aggregation von Modellsubstraten fördert, was hier für Metazoen-sHsps erstmals gezeigt wurde. HSP-17 kopräzipitiert mit Substraten und modifiziert deren Aggregate möglicherweise. HSP-17 kolokalisiert in vivo mit Aggregaten, und seine aggregationsfördernde Aktivität konnte ich für das physiologische Substrat KIN-19 und heterolog exprimierte polyQ-Peptide validieren. Durch ex vivo Analysen konnte ich zeigen, dass die Aktivität von HSP-17 für die Fitness relevant ist
In einem zweiten Projekt habe ich zur Entwicklung eines neuen Modelles für Aß-Pathologie in C. elegans beigetragen, welches substöchiometrische Markierungen verwendet, um eine zeitnahe Visualisierung der Aß-Aggregation in spezifischen Zelltypen zu ermöglichen. Das Modell spiegelt bekannte Phänotypen der Aß-Proteotoxizität aus Menschen und bestehenden C. elegans Aß-Stämmen wider. Interessanterweise zeigt eine Untergruppe der Neuronen, die IL2-Neuronen, eine höhere Anfälligkeit für die Aggregation und Proteotoxizität von Aß1-42. Eine gezielte Reduktion von Aß1-42 in IL2 Neuronen führt zu einer systemischen Reduktion der Pathologie. Somit bietet das Modell eine neue Plattform, um die Bedeutung molekularer Chaperone, wie z. B. der sHsps, für Amyloidosen zu untersuchen, auch im Hinblick auf menschliche Erkrankungen. / Successful synthesis and folding of proteins is a prerequisite for cellular function and failure of protein homeostasis leads to disease or death. Within the cell, molecular chaperones ensure correct protein folding or aid in the disposal of terminally misfolded protein substrates. Among these chaperones, small heat shock proteins (sHsps) are ATP-independent members of the proteostasis network.
In this work, I analyzed the so far under-researched C. elegans sHsp HSP-17. Unlike other sHsps, HSP-17 exhibited only weak activity in preventing aggregation of protein substrates. Instead, I could show in vitro that HSP-17 can promote the aggregation of protein substrates, which is the first demonstration for metazoan sHsps. HSP-17 co-precipitates with substrates and potentially modifies the aggregates. HSP-17 colocalizes with aggregates and pro-aggregation activity is present in vivo, which I demonstrated for the physiological substrate KIN-19 and heterologously expressed amyloidogenic polyQ peptides. By physiological, biochemical and proteomic analysis I showed that HSP-17 activity is relevant for organismal fitness
In a second project, I contributed to the development and characterization of a novel model of Aß pathology in C. elegans. This new AD model employs sub-stoichiometric labeling to allow live visualization of Aß aggregation in distinct cell types. The model mirrors known phenotypes of Aß proteotoxicity in humans and existing C. elegans Aß strains. Interestingly, a subset of neurons, the IL2 neurons, is shown to be more vulnerable to Aß proteotoxicity and targeted depletion of Aß in these neurons systemically ameliorates pathology. Thereby, the model presents a new platform to assess the relevance of molecular chaperones such as sHsps in amyloidosis with a perspective on human disease.
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