Global ETD Search

31	Application of crispr/cas9-based reverse genetics in leishmania braziliensis: Conserved roles for hsp100 and hsp23 Adaui, Vanessa, Kröber-Boncardo, Constanze, Brinker, Christine, Zirpel, Henner, Sellau, Julie, Arévalo, Jorge, Dujardin, Jean Claude, Clos, Joachim 01 October 2020 (has links) The protozoan parasite Leishmania (Viannia) braziliensis (L. braziliensis) is the main cause of human tegumentary leishmaniasis in the New World, a disease affecting the skin and/or mucosal tissues. Despite its importance, the study of the unique biology of L. braziliensis through reverse genetics analyses has so far lagged behind in comparison with Old World Leishmania spp. In this study, we successfully applied a cloning-free, PCR-based CRISPR–Cas9 technology in L. braziliensis that was previously developed for Old World Leishmania major and New World L. mexicana species. As proof of principle, we demonstrate the targeted replacement of a transgene (eGFP) and two L. braziliensis single-copy genes (HSP23 and HSP100). We obtained homozygous Cas9-free HSP23-and HSP100-null mutants in L. braziliensis that matched the phenotypes reported previously for the respective L. donovani null mutants. The function of HSP23 is indeed conserved throughout the Trypanosomatida as L. major HSP23 null mutants could be complemented phenotypically with transgenes from a range of trypanosomatids. In summary, the feasibility of genetic manipulation of L. braziliensis by CRISPR–Cas9-mediated gene editing sets the stage for testing the role of specific genes in that parasite’s biology, including functional studies of virulence factors in relevant animal models to reveal novel therapeutic targets to combat American tegumentary leishmaniasis. / Alexander von Humboldt-Stiftung / Revisión por pares CRISPR–Cas9 Gene targeting Heat shock proteins Leishmania braziliensis Phenotyping Reverse genetics Animal cell Article Controlled study CRISPR-CAS9 system
32	Characterizing femoral structure of the Ts66Yah mouse model of Down syndrome Kourtney N Sloan (16642212) 30 August 2023 (has links) <p> </p> <p>Down syndrome (DS) is caused by the partial or complete trisomy of human chromosome 21 (Hsa21) and can result in skeletal deficits, including lower bone mineral density (BMD) and increased risk of fracture and osteoporosis or osteopenia earlier than the general population. Mouse models of DS have been developed to understand the genetic mechanisms resulting in these phenotypes, but models differ due to the complex genetic nature of DS and differing genome structures between humans and mice. Ts65Dn mice have been a popular model of DS as they contain ~50% of Hsa21 orthologous genes on a freely segregating minichromosome, but there is speculation that the phenotypes are exaggerated by non-Hsa21 orthologous trisomic genes also present. To address this issue, the Ts66Yah mouse model was developed to remove the non-Hsa21 orthologous trisomic genes. In this study, male and female Ts66Yah mouse femurs were evaluated during bone accrual and peak bone mass to investigate structural differences using micro-computed tomography. Additionally, the role of trisomic <em>Dyrk1a</em>, a Hsa21 gene previously linked to bone deficits in Ts65Dn mice, was evaluated through genetic and pharmacological means in Ts66Yah femurs at postnatal day 36. Ts66Yah mice were found to have little or no trabecular deficits at any age evaluated, but sex-dependent cortical deficits were present at all ages investigated. Reducing <em>Dyrk1a</em> copy number in Ts66Yah mice significantly improved cortical deficits but did not return cortical bone to euploid levels. Pharmacological treatment with DYRK1A inhibitor L21 was confounded by multiple variables, making it difficult to draw conclusions about DYRK1A inhibition in this manner. Overall, these results indicate trabecular deficits associated with Ts65Dn mice may be due to the non-Hsa21 orthologous trisomic genes, and more Hsa21 orthologous trisomic genes are necessary to produce trabecular deficits in DS model mice. As more mouse models of DS are developed, multiple models need to be assessed to accurately define DS-associated phenotypes and test potential treatments.</p> Animal cell and molecular biology Down syndrome appendicular skeleton long bones Ts66Yah mouse model
33	Evalutation of Human Platelet Lysate in NK Cell Culture Williamson, Elizabeth 01 January 2020 (has links) Natural Killer (NK) cells can recognize and lyse a large variety of tumor cells and have been of interest as a potential cancer treatment option. Our group has developed a particle-based NK cell expansion method that utilizes plasma membrane particles (PM-particles) derived from K562 cells genetically engineered to express membrane bound IL21 and 41BBL(K562-mbIL21-41BBL), two proteins that stimulate growth and activity of NK cells. This method selectively expands highly cytotoxic NK cells > 400-fold in 14 days of culture. Currently NK cells are expanded in vitro using Fetal Bovine Serum (FBS) as a serum-supplement to promote cell growth. While effective, the use of animal products is not preferred in cell cultures grown for clinical purposes. This project tested Human Platelet Lysates (HPL) as a potential replacement for FBS in NK cell culture. NK cells were expanded using PM21-particle based expansion method with either FBS or HPL as supplements. Their growth characteristics, phenotype and functionality were assessed and compared. Results of this study determined that HPL is a viable option to replace FBS in NK cell culture for clinical applications, as there was no significant difference between the two serum supplements. Natural Killer Cells Fetal Bovine Serum Human Platelet Lysate cell culture animal cell culture Cancer Biology Cell and Developmental Biology
34	Mechanotransduction in Living Bone: Effects of the Keap1-Nrf2 Pathway Carlie Nicole Priddy (7023215) 15 August 2019 (has links) The Keap1-Nrf2 pathway regulates a wide range of cytoprotective genes, and has been found to serve a protective and beneficial role in many body systems. There is limited information available, however, about its role in bone homeostasis. While Nrf2 activation has been suggested as an effective method of increasing bone mass and quality, there have been conflicting reports which associate Keap1 deficiency with detrimental phenotypes. As Keap1 deletion is a common method of Nrf2 activation, further study should address the impacts of various methods of regulating Nrf2 expression. Also, little research has been conducted on the specific pathways by which Nrf2 activation improves bone quality. In this study, the effects of alterations to Nrf2 activation levels were explored in two specific and varied scenarios. In the first experiment, moderate Nrf2 activation was achieved via partial deletion of its sequestering protein, Keap1, in an aging mouse model. The hypothesis tested here is that moderate Nrf2 activation improves bone quality by affecting bone metabolism and response to mechanical loading. The results of this first experiment suggest a subtle, sex-specific effect of moderate Nrf2 activation in aging mice which improves specific indices of bone quality to varying degrees, but does not affect loading-induced bone formation. It is likely that the overwhelming phenotypic impacts associated with aging or the systemic effects of global Keap1 deficiency may increase the difficulty in parsing out significant effects that can be attributed solely to Nrf2 activation. In the second experiment, a cell-specific knockout of Nrf2 in the osteocytes was achieved using a Cre/Lox breeding system. The hypothesis tested here is that osteocyte-specific deletion of Nrf2 impairs bone quality by affecting bone metabolism and response to mechanical loading. The results of this experiment suggest an important role of Nrf2 in osteocyte function which improves certain indices of bone quality, which impacts male and female bones in different 7 ways, but did not significantly impact loading-induced bone formation. Further studies should modify the method of Nrf2 activation in an effort to refine the animal model, allowing the effects of Nrf2 to be isolated from the potential systemic effects of Keap1 deletion. Future studies should also utilize other conditional knockout models to elucidate the effects of Nrf2 in other specific cell types. Cell Biology Animal Cell and Molecular Biology Nrf2 Keap1 Bone Mechanotransduction Bone Remodeling cytoprotective Osteoporosis Antioxidant Aging Antiaging
35	Neurotoxicity of methylmercury : analysis of molecular mechanisms and behavioral alterations / Daré, Elisabetta, January 2002 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 6 uppsatser.
36	Approche méthodologique innovante pour le suivi en ligne de procédés de production d’anticorps par cellules animales : apport des techniques spectroscopiques in situ à la stratégie PAT / Innovative methodological approach for online monitoring of animal cell culture processes for antibody production : contribution of in situ spectroscopic techniques to the PAT strategy Li, Mengyao 09 November 2018 (has links) Les bioprocédés industriels mettant en œuvre la culture de cellules animales sont devenus incontournables pour la production d’anticorps monoclonaux (AcM). Cependant, l'état physiologique des cellules et la qualité des AcM produits, en particulier leur glycosylation, sont tributaires des variations intervenant au cours du procédé. Il en découle des risques d'altération de l'efficacité et de la sûreté des AcM. C'est pourquoi, depuis quelques années, l'initiative Process Analytical Technology (PAT) encourage le développement du suivi en ligne de ces procédés, avec l'objectif de mieux les maîtriser et d'assurer la qualité finale des produits. Dans ce contexte, cette thèse propose des approches innovantes pour le suivi en ligne de procédés de culture de cellules CHO (Chinese Hamster Ovary) en bioréacteur, basées sur l'utilisation de trois types de spectroscopies in situ (diélectrique, Raman, proche infrarouge(NIR)). Le premier chapitre présente une nouvelle démarche permettant de prédire en temps réel l'état physiologique des cellules, au travers de la vitesse spécifique de croissance cellulaire (μ). A partir de la mesure en ligne de la permittivité grâce à la spectroscopie diélectrique, la µ a été calculée en temps réel, permettant de détecter le moment critique correspondant au moment où μ diminue. Comparée à une démarche hors ligne, l'utilisation de cette méthode pour le pilotage de cultures en mode recharge-récolte, permet d’assurer à la fois la quantité et la qualité de glycosylation des AcM. Le second chapitre aborde l'utilisation des spectroscopies NIR et Raman in situ combinées à des méthodes chimiométriques. Les performances de ces deux spectroscopies ont été comparées en parallèle. Des modèles en ligne ont été développés pour prédire la concentration de différents paramètres (cellules viables, glucose, lactate, glutamine, ions ammonium, anticorps). L'évaluation de ces modèles par facteurs de mérite (FOM), a révélé certains avantages de la spectroscopie Raman. La combinaison de ces deux spectroscopies par diverses stratégies de fusion de données a été également évaluée. Dans le troisième chapitre, l'intérêt de la spectroscopie Raman a été démontré pour le suivi en ligne, non seulement, de la concentration, mais aussi, de la glycosylation des AcM. Des modèles ont été développés pour la prédiction en ligne, à la fois, de la macro-hétérogénéité (sites de glycosylation), et de la micro-hétérogénéité (structures glycanniques) de la glycosylation des AcM dans le cas de cultures en mode discontinu et recharge-récolte. Le dernier chapitre a utilisé les spectroscopies NIR et diélectrique, en les intégrant à un « capteur logiciel » combinant des équations de bilans de matière. Ce « capteur logiciel », mis en œuvre au cours d'une culture en mode semi-continu pour le contrôle automatique du débit d'alimentation, a conduit à une augmentation de la productivité du procédé ainsi qu'à une meilleure glycosylation des AcM produits / Bioprocesses of mammalian cell culture have become essential for the production of therapeutic recombinant proteins, such as monoclonal antibodies (mAb). However, the physiological state of the cells and the quality of the mAb produced, in particular their glycosylation, may vary during the process, and may lead to the alteration of the safety and efficacy of the final product. Consequently, the Process Analytical Technology (PAT) initiative has encouraged the development of online monitoring techniques, with the aim to better control the process and ensure the quality of the final product. In this context, this thesis proposes innovative approaches for online monitoring of CHO (Chinese Hamster Ovary) cells bioreactor cultures, by using three types of in situ spectroscopic measurements (dielectric, Raman, near infrared (NIR)). The first chapter presents a novel approach to predict in real-time one of the major cell physiological state parameters, the specific growth rate (µ). Based on online permittivity measured by in situ dielectric spectroscopy, the cell concentration was estimated and µ was calculated in real-time, making possible to detect the critical moment when µ begins to decrease significantly. Compared to an offline approach, this online approach allowed to maintain the cells in a stable physiological state, ensuring the glycosylation of the mAb produced in feed-harvest cultures. The second chapter shows the use of in situ NIR and Raman spectroscopies combined with chemometric methods. For the first time, the performances of these two spectroscopies were compared in parallel in the same cultures. Online models were developed to predict in real-time the concentration of different parameters (viable cells, glucose, lactate, glutamine, ammonium ions and antibodies). The evaluation of these models by the multivariate Figures of Merit (FOM) revealed some of the advantages of Raman spectroscopy. The combination of the two spectroscopies by various data fusion strategies has also been evaluated. In the third chapter, the interest of Raman spectroscopy for the online monitoring of both the quantity and the glycosylation of the mAb was demonstrated. Models were developed for online prediction of both macroheterogeneity (glycosylation site occupancy) and microheterogeneity (glycan structures) of mAb glycosylation in batch and feed-harvest cultures. The last chapter used models previously developed for NIR and dielectric spectroscopies, to integrate into a “soft sensor” by combining with cell metabolic and mass balance equations. This “soft sensor”, implemented in a fed-batch cell culture for the automatic control of the feed rate, leads to an increased mAb productivity and better mAb glycosylation Suivi en temps réel Spectroscopies in situ Chimiométrie Anticorps monoclonaux Glycosylation Animal cell culture bioprocesses Real-time monitoring In situ spectroscopies Chemometrics Monoclonal antibodies Glycosylation 660 543.5
37	FBXO44-MEDIATED DEGRADATION OF RGS2 Harrison J McNabb (15361621) 27 April 2023 (has links) <p> G Protein Coupled Receptor (GPCR) signaling plays a key role in intercellular communication and regulates many physiological processes relevant to disease. Approximately 30-40% of all FDA approved drugs target GPCR pathways, but limitations and off-target side effects remain obstacles. Regulator of G protein Signaling (RGS) proteins negatively modulate GPCR signaling by accelerating deactivation of the Gα subunit and thus represent a novel alternative to current approaches. While research on RGS proteins and how they are regulated has expanded rapidly, there are still gaps in knowledge for some members of the RGS family. One example is RGS2, which is selective for Gαq signaling. Lowered RGS2 levels are implicated in numerous diseases, and while the E3 ligase responsible for facilitating degradation of RGS2 has been identified more work needs to be done to viably drug it to enhance RGS2 protein levels. In this thesis, I explore how FBXO44, an E3 ligase substrate recognition component responsible for RGS2 degradation, interacts with RGS2 to explore approaches to inhibit degradation.</p> <p><br></p> <p>While the FBXO44-RGS2 interaction has been demonstrated previously, the degron sequence of RGS2 remained unknown. We hypothesized that FBXO44 binds RGS2 at its Nterminus and investigated this using N-terminally truncated RGS2 constructs. Our results indicated that FBXO44 binds between residues 5 and 16 of RGS2, as removal of these stabilized RGS2 against proteasomal degradation. Based on these results we designed a peptide microarray to identify important residues and properties for FBXO44 in vitro and found that Cys13 is essential for FBXO44 binding.</p> <p><br></p> <p>We also developed and optimized a high-throughput split luciferase screen to identify potential inhibitors of the FBXO44-RGS2 interaction. After forming a cell-line stably expressing tagged FBXO44 and RGS2 and optimizing assay condition, we achieved a robust assay for screening as determined by Z’-factor. <br> </p> Signal transduction Animal cell and molecular biology Basic pharmacology RGS 2 deficiency FBXO44 Proteasomal Degradation High Throughput Screen development protein protein interaction
38	<strong>PHYSIOLOGICAL, IMMUNOLOGICAL, MICROBIOLOGICAL, AND MOLECULAR RESPONSES OF SEA URCHIN EXPOSED TO PHYSICAL AND CHEMICAL STRESSORS</strong> Nahian Fyrose Fahim (15634817) 30 May 2023 (has links) <p>Sea urchins are fascinating marine creatures belonging to the phylum Echinodermata that serve as an essential ecological component and hold promise as a prospective source of therapeutics. However, sudden environmental changes, such as global warming and marine pollution, are placing significant stress on these organisms. To maintain natural resources and exploit sea urchins commercially, researchers are investigating aquaculture as a solution.</p> <p>This investigation discloses the physiological and immunological effects of physical and chemical stressors on one of the most common edible species of sea urchin, <em>Arbacia punctulata</em>. The study employed an elevated temperature as a physical stressor (1°C/day), lipopolysaccharides (LPS) inoculation as a chemical stressor (4µg/ml/day), and a combination of both LPS and elevated temperature as combined stressors. The results demonstrated a significant alteration in the total and differential coelomocyte count in the LPS-stressed group (p<0.05) and combined stressed group (p<0.05) followed by abnormal behavioral activity compared to those of control. Additionally, exposure to acute LPS exposure (at day 1 and day 3) and combined stressors led to an increase in phagocytic capacity (p<0.05) and lysozyme activity (p<0.05). Chronic exposure to LPS and combined stressors resulted in a decrease in gonadosomatic index (p<0.05, at day 10) and lysozyme activity (at day 7). A significant increase in coelomic fluid (CF) protein (p<0.05)was observed in the temperature-stressed group on days 5 and 10, while the combined stressed group had significantly more CF protein on days 1, 5, 7, and 10. An upregulation of Nf-kB gene expression was also observed (p>0.05) in temperature stressed group. </p> <p>The study also revealed that sea urchins contain bioactive compounds that protect against external and internal injury, cell death, and body wall extract of sea urchin exhibited high antioxidant activity(p<0.05). Furthermore, it confirmed the antibacterial activity (p<0.05) of sea urchin (<em>Arbacia punctulata </em>and<em> Lytechinus variegatus</em>) body wall and coelomic fluid (cell-free plasma) extracts against ten pathogenic bacteria. The ethyl acetate body wall extract of both sea urchin species demonstrated higher inhibitory activity against the pathogenic bacteria tested. Overall sea urchin has potentials to meet the demand of food and medicine. </p> Animal behaviour Animal cell and molecular biology Animal immunology Animal physiology - cell Invertebrate biology Echinoderms Sea Urchins Stress physiology Microbiology Antioxidants Molecular response
39	Lethal and sub-lethal effects of hydrodynamic forces on animal cell culture Godoy, Ruben D. 21 August 2008 (has links) No description available. Chemical Engineering Pharmaceuticals Animal Cell Culture CHO THP1 Cell Death Shear Sensitivity Stress Hydrodynamic Force Antibody Monoclonal Glycosylation Apoptosis Necrosis CFD Fluent Flow Cytometry
40	Cilia Associated Signaling In Adult Energy Homeostasis Ruchi Bansal (12476844) 28 April 2022 (has links) <p> </p> <p>Cilia are cell appendages that sense our environment and are critical in cell-to-cell communication. Dysfunction of cilia can result in several disease states including obesity. While cilia in the brain are known to be important for feeding behavior, it is unclear how they regulate energy homeostasis. Classically, cilia coordinate signaling through surface receptors called G-protein coupled receptors (GPCRs). For example, cilia mediated GPCR signaling is critical for both our senses of vision and smell. How cilia regulate the signaling of GPCRs in other areas of the body including the brain is only now emerging. To answer cell biology questions around cilia mediated GPCR signaling in neurons, we developed a system for primary neuronal cultures. We discovered that the cilia mediated hedgehog pathway influences the ability of neurons to respond to GPCR ligands. For the first time, this result highlights the role of the hedgehog pathway in neurons. We continue to explore how cilia integrate the hedgehog pathway and GPCR signaling in the central nervous system, and the potential connections to energy homeostasis. We discovered that hedgehog pathway activity in feeding centers of the brain changes based upon feeding conditions like fasting. We also learned that activating the hedgehog pathway in these brain regions is sufficient to cause obesity in mice. These novel results highlight an unrecognized role for the hedgehog pathway in the regulation of feeding behavior. Overall, this work provides a better understanding of ciliopathy associated obesity and may reveal more common mechanisms of obesity in the general population. In addition, this work implicates the hedgehog pathway in regulating behaviors and new modes of cell-cell communication within the central nervous system.</p> Animal behaviour Animal cell and molecular biology Animal neurobiology Neurosciences not elsewhere classified energy homeostasis Hypothalamus Hedgehog pathway neuronal signaling Bardet Biedl Syndrome Primary Cilia ciliopathies Obesity leptin signaling MCHR1 smoothened signaling pathway Animal Behaviour Animal Neurobiology Animal Cell and Molecular Biology Cell Biology Neuroscience

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