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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.
11

Uncovering Transcriptional Activators and Targets of HSF-1 in Caenorhabditis elegans

Brunquell, Jessica 06 April 2017 (has links)
In order to survive, cells must be able to cope with a variety of environmental stressors. The heat shock response (HSR) is a pro-survival mechanism employed by cells in response to protein denaturing stress, such as heat. Since its discovery in 1960, the heat shock response has been found to be regulated by the transcription factor heat shock factor 1 (HSF1). During periods of increased stress, HSF1 undergoes a multi-step process of activation that involves homotrimerization, DNA-binding, and post-translational regulatory modifications, all of which ultimately function to control the transcription of chaperone genes. These chaperone genes encode molecular chaperone proteins which function to promote survival during stress by restoring protein homeostasis to the cell. Although HSF1 is classically studied for its role in regulating the HSR, HSF1 also has roles in regulating metabolism, development, and longevity. Studies in the nematode Caenorhabditis elegans demonstrate the HSF1 homolog, HSF-1, as a global regulator of gene expression that has both stress-dependent and -independent functions. Modulating HSF1 activity therefore has implications beyond stress-induced processes, and has been suggested as a promising therapeutic target for diseases of aging and protein dysfunction. We were interested in determining regulators of the HSR using C. elegans as a model to test for effects on proteostasis and longevity. In these studies, we observed the effects of compound treatment (Chapters 1 and 2), genetic manipulation (Chapters 3 and 4), and environmental stimuli (Chapters 5 and 6), on the HSR in C. elegans. In Chapters 1 and 2, we describe our findings that treatment with the DNA synthesis inhibitor Fluorodeoxyuridine, and treatment with coffee and caffeine, enhance the heat shock response and improve proteostasis in aging worms in an HSF-1-dependent manner. In Chapters 3 and 4, we uncovered that negative regulation of the HSR by the cell cycle and apoptosis regulator CCAR2 is conserved in C. elegans, and is mediated by the CCAR2 ortholog, LST-3. We also uncovered that negative regulation of the HSR by LST-3 requires the SIRT1 homolog Sir-2.1, and knockdown of LST-3 via lst-3 RNAi works through Sir-2.1 to enhance stress-resistance, fitness, proteostasis and longevity. In Chapters 5 and 6, we describe the global impact of HSF-1 in regulating transcriptional processes during a heat stress. The profiling of global HSF-1 mRNA and miRNA targets has allowed us to uncover a heat-dependent and -independent role for HSF-1 in regulating gene expression to impact stress-resistance, proteostasis, and longevity. Altogether, these studies demonstrate the impact of compound treatment, genetic manipulation, and environmental stimuli on the heat shock response, while also uncovering global stress-dependent and -independent roles for HSF-1. This work therefore provides insight into various methods of activating the HSR by modulating HSF-1 activity, and uncovering global HSF-1 target genes, which may be useful for designing therapeutic treatment strategies for diseases of protein dysfunction.
12

The combined effects of thermal and radiological stress on the embryonic development of lake whitefish (Coregonus clupeaformis)

Kulesza, Adomas January 2017 (has links)
Lake whitefish (Coregonus clupeaformis; LWF) are a cold-adapted freshwater species that are of both economic and cultural value. These fish spawn in lake areas where their embryos are exposed to thermal power plant effluents that may contain low levels of thermal, radiological and chemical stressors. Many studies on LWF embryonic development have looked at the individual effects of these stressors, but few have looked at the potential for combined effects. The combined effects of thermal and radiological stress were of interest due to growing evidence that mild thermal stress can produce an adaptive response, through the induction of the heat shock response (HSR), when followed with subsequent ionizing radiation stress. This thesis examined the combined impacts of thermal and radiological stress during LWF embryogenesis. LWF embryos were exposed to mild heat shocks (HS; Δ3 or 9°C) prior to a high dose of acute 137Cs gamma rays at 2, 6 and 24 hours post heat shock during the gastrulation or eyed stage. Heat shocked embryos were collected at each developmental stage and assessed for induction of heat shock protein (Hsp) genes. Following exposure, embryos were raised until hatch where mortality, morphometry, and embryo weight were measured. Mild HS induced Hsp70 mRNA expression at gastrulation, but not at the eyed stage. Embryos at hatch were not impacted by thermal or radiological exposure at the gastrulation stage. During the eyed stage, acute radiation treatment increased mortality and decreased body size at hatch. Mild HS prior to radiation did not provide protective effects and no adaptive response was observed. This thesis better defines the combined effects of thermal and radiological stress on the embryonic development of LWF. It also suggests that the ontogeny aspects of heat shock responses and radiosensitivity are important to consider for future adaptive response studies. / Thesis / Master of Science (MSc)
13

Nardilysin determines hematopoietic stem cell fitness by regulating protein synthesis / ナルディライジンはタンパク質合成を制御することにより造血幹細胞の機能維持に関与する

Oshima, Shinichiro 25 March 2024 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第25196号 / 医博第5082号 / 新制||医||1072(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 金子 新, 教授 滝田 順子, 教授 河本 宏 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM
14

Evolutionary Innovations In Ants To Thermally Stressful Environments

Nguyen, Andrew D. 01 January 2017 (has links)
Temperature is a fundamental environmental force shaping species abundance and distributions through its effects on biochemical reaction rates, metabolism, activity, and reproduction. In light of future climate shifts, mainly driven by temperature increases, how will organisms persist in warmer environments? One molecular mechanism that may play an important role in coping with heat stress is the heat shock response (HSR), which protects against molecular damage. To prevent and repair protein damage specifically, Hsps activate and become up-regulated. However, the functional diversity and relevance of heat shock proteins (Hsps) in extending upper thermal limits in taxonomic groups outside marine and model systems is poorly understood. Ants are a good system to understand the physiological mechanisms for coping with heat stress because they have successfully diversified into thermally stressful environments. To identify and characterize the functional diversity of Hsps in ants, I surveyed Hsp orthologues from published ant genomes to test for signatures of positive selection and to reconstruct their evolutionary history. Within Hymenoptera, ants utilize unique sets of Hsps for the HSR. Stabilizing selection was the prevailing force among Hsp orthologues, suggesting that protein activity is conserved. At the same time, regulatory regions (promoters) governing transcriptional up-regulation diversified: species differ in the number and location of heat shock elements (HSEs). Therefore, Hsp expression patterns may be a target for selection in warm environments. I tested whether Hsp expression corresponded with variation in upper thermal limits in forest ant species within the genus Aphaenogaster. Whole colonies were collected throughout the eastern United States and were lab acclimated. There was a positive relationship between upper thermal limits (Critical Thermal maxima, CTmax) and local temperature extremes. Upper thermal limits were also higher in ant species that lived in open habitats (shrub-oak and long-leaf pine savannah) than species occupying closed habitats (deciduous forest). Ant species with higher CTmax expressed Hsps more slowly, at higher temperatures, and at higher maximum levels than those with low CTmax. Because Hsps sense and repair molecular damage, these results suggest the proteomes of open relative to closed canopy forests are more stable. Although deciduous forest ant species may be buffered from temperature stress, it is likely that temperature interacts with other environmental stressors such as water and nutrient availability that may impact upper thermal limits. I measured the influence of dehydration and nutrition stress on upper thermal limits of forest ants from a single population. Ants that were initially starved were much less thermally tolerant than controls and ants that were initially desiccated. Because ants are likely to experience similar combination of stressors in the wild, upper thermal limits may be severely overestimated in single factor experiments. Therefore, realistic forecasting models need to consider multiple environmental stressors. Overall, adaptive tuning of Hsp expression that reflects better protection and tolerance of protein unfolding may have facilitated ant diversification into warm environments. However, additional stressors and mechanisms may constrain the evolution of upper thermal limits.
15

The identification of novel regulatory elements in the promoters of heat shock response genes

Ncube, Sifelani January 2010 (has links)
The main objective of this study was to investigate promoter sequences of putative HSR genes for the presence of unique regulatory elements and modules that might be involved in the regulation of HSR. In order to achieve this objective, an in silico promoter analysis strategy was devised, which focused on the identification of promoter sequences and regulatory elements, and modelling of promoter modules by using Genomatix software tools such as MatInspector and ModelInspector. Results showed that two modules (EGRF_SP1F_01 and SP1F_CEBP_01) were conserved in the promoter sequences of three well-known Hsp-genes (Hsp90, Hsp105β and αβ-crystallin). Screening the 60 target gene promoters for the presence of the two modules revealed that 12 genes (20 %) contained both modules. These included Moesin, Proline-4 hydroxylase, Poly(A) binding protein and Formin-binding protein. None of these genes had been previously associated with heat shock response.
16

The identification of novel regulatory elements in the promoters of heat shock response genes

Ncube, Sifelani January 2010 (has links)
The main objective of this study was to investigate promoter sequences of putative HSR genes for the presence of unique regulatory elements and modules that might be involved in the regulation of HSR. In order to achieve this objective, an in silico promoter analysis strategy was devised, which focused on the identification of promoter sequences and regulatory elements, and modelling of promoter modules by using Genomatix software tools such as MatInspector and ModelInspector. Results showed that two modules (EGRF_SP1F_01 and SP1F_CEBP_01) were conserved in the promoter sequences of three well-known Hsp-genes (Hsp90, Hsp105β and αβ-crystallin). Screening the 60 target gene promoters for the presence of the two modules revealed that 12 genes (20 %) contained both modules. These included Moesin, Proline-4 hydroxylase, Poly(A) binding protein and Formin-binding protein. None of these genes had been previously associated with heat shock response.
17

The identification of novel regulatory elements in the promoters of heat shock response genes

Ncube, Sifelani January 2010 (has links)
Masters of Science / The main objective of this study was to investigate promoter sequences of putative HSR genes for the presence of unique regulatory elements and modules that might be involved in the regulation of HSR. In order to achieve this objective, an in silico promoter analysis strategy was devised, which focused on the identification of promoter sequences and regulatory elements, and modelling of promoter modules by using Genomatix software tools such as MatInspector and ModelInspector. Results showed that two modules (EGRF_SP1F_01 and SP1F_CEBP_01) were conserved in the promoter sequences of three well-known Hsp-genes (Hsp90, Hsp105β and αβ-crystallin). Screening the 60 target gene promoters for the presence of the two modules revealed that 12 genes (20 %) contained both modules. These included Moesin, Proline-4 hydroxylase, Poly(A) binding protein and Formin-binding protein. None of these genes had been previously associated with heat shock response. / South Africa
18

Identification of Heat Shock Factor Binding Sites in the Drosophila Genome

Gonsalves, Sarah E. 12 December 2012 (has links)
The heat shock response (HSR) is a highly conserved mechanism that enables organisms to survive environmental and pathophysiological stress. In Drosophila, the HSR is regulated by a single transcription factor, heat shock factor (HSF). During stress, HSF trimerizes and binds to over 200 loci on Drosophila polytene chromosomes with only nine mapping to major heat shock (HS) inducible gene loci. The function of HSF binding to the other sites in the genome is currently unknown. Some of these sites may contain yet unidentified “minor” HS genes. Interestingly, the binding of HSF also coincides with puff regression at some sites. Two such sites contain the major developmentally regulated genes Eip74 and Eip75: key regulators in the response to 20-hydroxyecdysone (20E), the main hormone responsible for the temporal co-ordination of post-embryonic development in Drosophila. Previous work in our and other labs indicates that the regression of non-HS puffs during the HSR is dependent on the presence of functional HSF. Using chromatin immunoprecipitation (ChIP) followed by hybridization to genome tiling arrays (Chip), I have identified 434 regions in the Drosophila Kc cell genome that are bound by HSF during HS, and have determined that 57% of these sites are located within the transcribed regions of genes. By examining the transcriptional response to HS in Kc cells and third instar larvae using expression microarrays, I found that only about 10% of all genes within 1250 bp of an HSF binding site are transcriptionally regulated by HS and many genes whose transcript levels change during HS do not appear to be near an HSF binding site. Furthermore, genes with an HSF binding site within their introns are significantly enriched (modified Fisher Exact p-value between 2.0x10-3 and 1.5x10-6) in gene ontology terms related to developmental processes and reproduction. Using expression microarray technology, I characterized the transcriptional response to 20E and its structural analog ponasterone A. I have identified multiple HSF binding sites within Eip74 and Eip75, and show that induction of the HSR correlates with repression of these genes and all other 20E-inducible genes. Taken together, this work provides a basis for further investigation into the role of HSF binding to sites not associated with HS genes and its possible function as a repressor of gene transcription during conditions of stress and as a regulator of developmental genes under stress and non-stress conditions.
19

Identification of Heat Shock Factor Binding Sites in the Drosophila Genome

Gonsalves, Sarah E. 12 December 2012 (has links)
The heat shock response (HSR) is a highly conserved mechanism that enables organisms to survive environmental and pathophysiological stress. In Drosophila, the HSR is regulated by a single transcription factor, heat shock factor (HSF). During stress, HSF trimerizes and binds to over 200 loci on Drosophila polytene chromosomes with only nine mapping to major heat shock (HS) inducible gene loci. The function of HSF binding to the other sites in the genome is currently unknown. Some of these sites may contain yet unidentified “minor” HS genes. Interestingly, the binding of HSF also coincides with puff regression at some sites. Two such sites contain the major developmentally regulated genes Eip74 and Eip75: key regulators in the response to 20-hydroxyecdysone (20E), the main hormone responsible for the temporal co-ordination of post-embryonic development in Drosophila. Previous work in our and other labs indicates that the regression of non-HS puffs during the HSR is dependent on the presence of functional HSF. Using chromatin immunoprecipitation (ChIP) followed by hybridization to genome tiling arrays (Chip), I have identified 434 regions in the Drosophila Kc cell genome that are bound by HSF during HS, and have determined that 57% of these sites are located within the transcribed regions of genes. By examining the transcriptional response to HS in Kc cells and third instar larvae using expression microarrays, I found that only about 10% of all genes within 1250 bp of an HSF binding site are transcriptionally regulated by HS and many genes whose transcript levels change during HS do not appear to be near an HSF binding site. Furthermore, genes with an HSF binding site within their introns are significantly enriched (modified Fisher Exact p-value between 2.0x10-3 and 1.5x10-6) in gene ontology terms related to developmental processes and reproduction. Using expression microarray technology, I characterized the transcriptional response to 20E and its structural analog ponasterone A. I have identified multiple HSF binding sites within Eip74 and Eip75, and show that induction of the HSR correlates with repression of these genes and all other 20E-inducible genes. Taken together, this work provides a basis for further investigation into the role of HSF binding to sites not associated with HS genes and its possible function as a repressor of gene transcription during conditions of stress and as a regulator of developmental genes under stress and non-stress conditions.
20

Räumlich-zeitliche Dynamik der laserinduzierten Hsp70-Expression in einem humanen Hautexplantatmodell

Konz, Maximilian 29 November 2016 (has links) (PDF)
Die Narbenbildung des Hautorgans stellt für die gegenwärtige Medizin weiterhin eine schwierige Aufgabe dar. Die frühzeitige Beeinflussung des Wundheilungspro- zesses hin zu einer verminderten oder narbenlosen Heilung scheint von entschei- dender Bedeutung. Ein vielversprechender Ansatz ist die präoperative Laserthe- rapie und dadurch erzeugte Hitzeschockantwort. Auf molekulare Ebene kommt es u.a. zur Expression von Hitzeschockproteine. Die vorliegende in-vitro Studie beschäftigte sich mit der laserinduzierten Hochregulation des Hitzeschockproteins 70 in den epidermalen Schichten. Hierfür wurden drei nicht ablative Lasersysteme mit insgesamt 12 verschiedenen Parametereinstellungen verwendet (1.540-nm Er:Glass- , 755-nm Alexandrit-, 1.064-nm Nd:YAG-Laser). Mithilfe eines humanen Hautexplantatmodells sollte unter gleichbleibenden Bedingungen Zeitpunkt und Konzentration der maximal induzierten Hsp70-Expression sowie epidermale Schä- digungen dargestellt werden. In der verfügbaren Literatur waren hierzu nur begrenzt Daten vorhanden. Alle drei Lasersysteme zeigten signifikante Hsp70-Expressionen. Der Zeitpunkt der maximalen Hsp70-Expression konnte zwischen Tag 1 und 3 festgehalten werden. Dabei zeigten die Lasersysteme unterschiedliche Hsp70- Maxima und unterschiedliche Epidermisschädigungen. Die Ergebnisse ließen schlussfolgern, dass eine potenzielle präoperative Narbenprävention tendeziell ein Tag vor dem chirurgischen Eingriff und mit den stärkeren Parametereinstellungen des 1.064-nm Nd:YAG Lasers durchgeführt werden sollte.

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