Global ETD Search

111	Investigating Immune Responses and Pathology During HIV/Mtb Co-Infection Within Humanized Mice Yang, Jack (Xiaozhi) January 2022 (has links) There are an estimated 2 billion individuals infected with Mtb, and 37.7 million people living with HIV (PLWH) worldwide. HIV/Mtb co-infection increases the risk of developing active tuberculosis by over 20-fold, and 210,000 of 1.5 million deaths from TB were among co-infected PLWH in 2020. Therefore, development of effective TB vaccination, particularly within the vulnerable PLWH population, is an urgent global issue. With limited in vivo models to study co-infection, humanized NRG (huNRG) mice and humanized DRAG-A2 mice (a next-generation of huNRG mice expressing HLA class I and II transgenes with improved human immune reconstitution, huDRAG-A2) are promising tools for HIV and TB reserach as they develop robust human immune cell populations and recapitulate many aspects of HIV or TB clinical disease. HIV/Mtb co-infection was investigated using huNRG and hu-DRAG-A2 mice in separate experiments where intravaginal (with DMPA pre-treatment) or intraperitoneal HIV-1 infection was administered, respectively, and intranasal infection of Mtb was administered 3.5 weeks later. Both huNRG and huDRAG-A2 mice recapitulated hallmark features of HIV/Mtb co-infection such as severe granuloma pathology, hCD4+ T cell depletion in lung and spleen tissue, and human like lung pathology such as Mtb-infected foamy macrophages in the granuloma. Co-infected huDRAG-A2 mice also displayed significantly higher bacterial burden in the lungs, increased extrapulmonary dissemination into spleen and liver, and significantly lower hCD4+ T cells in the peripheral blood post-Mtb infection when compared to the Mtb-only infected group. To investigate TB vaccine immunogenicity, huNRG and huDRAG-A2 mice were immunized with a novel trivalent vaccine, AdCh68MV. Upon intranasal immunization, both models showed trends of developing higher Mtb antigen-specific hCD4+ T cell responses in the lung and spleen. Overall, this project sets the initial stages of a pre-clinical HIV/Mtb co-infection model in huNRG and huDRAG-A2 mice appropriate for immune investigations, therapeutic and vaccination development. / Thesis / Master of Science in Medical Sciences (MSMS) / There are over 2 billion individuals infected with TB and 37.7 million people living with HIV (PLWH) worldwide. When someone is co-infected with both diseases, the risk of death is greatly increased. Research in co-infection and developing effective TB vaccination for PLWH are urgent global issues. Animal studies are currently limited because studying HIV requires human immune cells. Our lab has established humanized mice (hu-mice) that develop many different human immune cells and are useful for HIV/Mtb co-infection research. When hu-mice were co-infected, they showed more dying lung tissue, immune cell loss, and bacteria in the lungs. Hu-mice were also used to study human immune responses to a novel TB vaccine delivered to the lungs. Trends of higher immune responses towards TB were observed in the lung and spleen of immunized hu-mice. Overall, this project shows the utility of hu-mice as pre-clinical models of HIV/Mtb co-infection and Mtb vaccine studies. HIV TB humanized mouse models co-infection granuloma TB vaccine HIV/TB co-infection pre-clinical model in vivo HIV/TB co-infection
112	Exploring the Three-Dimensional Regional Myocardial Function in Transgenic Mouse Models of Cardiac Diseases using Novel MR Tissue Tracking Techniques Zhong, Jia January 2009 (has links) No description available. Biomedical Research Engineering transgenic mouse models cardiac diseases harmonic phase (HARP) strain regional myocardial function
113	Developing Methods to Validate Tissue Specific Growth Hormone Receptor Knockout Mouse Models Sigman, Meredith Jane January 2011 (has links) No description available. Molecular Biology Biology Microbiology Growth Hormone Growth Hormone Receptor GHR Knockout Mouse Models GHR Protein Western Blot Analysis Polymerase Chain Reaction PCR
114	The Identification of Colorectal Cancer Susceptibility Genes Using a Cross-Species, Systems Genetics Approach Gerber, Madelyn Margaret 19 May 2015 (has links) No description available. Genetics Biology Biomedical Research Cellular Biology Medicine Molecular Biology Colon Cancer Colorectal Cancer Genetics Allele-Specific Imbalance Mouse Models Candidate Genes Susceptibility
115	Biological functions of microRNA-216 and microRNA-217 during the development of pancreatic cancer Azevedo-Pouly, Ana Clara P. 17 October 2013 (has links) No description available. Pharmaceuticals Oncology Molecular Biology microRNA miR-217 miR-216a miR-216b cancer pancreas pancreatic cancer development PDAC REST CDH1 Zeb1 embryonic lethality GEMM mouse models ADM acinar ductal
116	Molecular mechanisms of OXR1 function Liu, Kevin Xinye January 2014 (has links) By 2040, the World Health Organization expects neurodegenerative diseases, such as Alzheimer’s disease, amyotrophic lateral sclerosis (ALS), and Parkinson’s disease, to surpass cancer as the second most common cause of death worldwide. Currently, only treatments for symptoms of these diseases are available. Thus, research is critical to alleviate this public health burden by elucidating the pathogenic processes and developing novel therapies. While exact mechanisms by which these heterogeneous neuropathological conditions become manifest in patients remain unclear, growing evidence suggests that oxidative stress (OS) makes a significant contribution to neuronal dysfunction and apoptosis in all major neurodegenerative diseases. Recently, the gene oxidation resistance 1 (Oxr1) has emerged as a critical regulator of neuronal survival in response to OS. Oxr1 is expressed throughout the central nervous system, and its highly conserved TLDc domain protects neurons from oxidative damage through an unknown mechanism. This thesis aimed to define mechanisms by which Oxr1 confers neuronal sensitivity to OS, and to determine its role in neurodegenerative diseases. I found that Oxr1 mediates cytoplasmic localization of ALS-associated proteins Fused in Sarcoma (FUS) and transactive response DNA binding protein 43 kDa (TDP-43) through a TLDc domain- and arginine methylation-dependent pathway. Next, I investigated in vivo neuroprotective functions of Oxr1, and demonstrated that neuronal Oxr1 over-expression extends survival and ameliorates behavioural dysfunction and pathology of an ALS mouse model. In particular, neuronal Oxr1 over-expression strikingly delays neuroinflammation during ALS pathogenesis. Finally, I characterised a mouse model that specifically deletes Oxr1 from motor neurons. While loss of Oxr1 in ChAT-positive motor neurons does not cause overt neurodegeneration in the spinal cord, constitutive loss of Oxr1 leads to neuroinflammation in the cerebellum and spinal cord. Taken together, these studies illuminate functions of Oxr1 in the complex antioxidant defence network and present implications for future therapeutic strategies. 616.8
117	Characterization of polycystin-1 in ADPKD pathogenetic mechanism : biogenesis and functional implications by genetic approaches in mouse Kurbegovic, Almira 03 1900 (has links) La polykystose rénale autosomique dominante (ADPKD) est une des maladies génétiques les plus communes. ADPKD se manifeste le plus souvent au stade adulte par la présence de kystes rénaux, et bien souvent de kystes hépatiques, avec une progression très variable. ADPKD mène à une insuffisance rénale: les seuls recours sont la dialyse puis la transplantation rénale. Les mutations dispersées sur les gènes PKD1 (majoritairement; la protéine polycystine-1, PC1) et PKD2 (la protéine polycystine-2, PC2) sont responsables de l’ADPKD. Le mécanisme pathogénétique de perte de fonction (LOF) et donc d’un effet récessif cellulaire est évoqué comme causatif de l’ADPKD. LOF est en effet supporté par les modèles murins d’inactivation de gènes PKD1/PKD2, qui développent de kystes, quoique in utéro et avec une rapidité impressionnante dans les reins mais pas dans le foie. Malgré de nombreuses études in vitro, le rôle de PC1/PC2 membranaire/ciliaire reste plutôt hypothétique et contexte-dépendant. Ces études ont associé PC1/PC2 à une panoplie de voies de signalisation et ont souligné une complexité structurelle et fonctionnelle exceptionnelle, dont l’implication a été testée notamment chez les modèles de LOF. Toutefois, les observations patho-cellulaires chez l’humain dont une expression soutenue, voire augmentée, de PKD1/PC1 et l’absence de phénotypes extrarénaux particuliers remet en question l’exclusivité du mécanisme de LOF. Il était donc primordial 1) d’éclaircir le mécanisme pathogénétique, 2) de générer des outils in vivo authentiques d’ADPKD en terme d’initiation et de progression de la maladie et 3) de mieux connaitre les fonctions des PC1/PC2 indispensables pour une translation clinique adéquate. Cette thèse aborde tous ces points. Tout d’abord, nous avons démontré qu’une augmentation de PKD1 endogène sauvage, tout comme chez l’humain, est pathogénétique en générant et caractérisant en détail un modèle murin transgénique de Pkd1 (Pkd1TAG). Ce modèle reproduit non seulement les caractéristiques humaines rénales, associées aux défauts du cil primaire, mais aussi extrarénales comme les kystes hépatiques. La sévérité du phénotype corrèle avec le niveau d’expression de Pkd1 ce qui supporte fortement un modèle de dosage. Dans un deuxième temps, nous avons démontré par les études de complémentations génétiques que ces deux organes reposent sur une balance du clivage GPS de Pc1, une modification post-traductionelle typique des aGPCR, et dont l’activité et l’abondance semblent strictement contrôlées. De plus, nous avons caractérisé extensivement la biogénèse de Pc1 et de ses dérivés in vivo générés suite au clivage GPS. Nous avons identifié une toute nouvelle forme et prédominante à la membrane, la forme Pc1deN, en plus de confirmer deux fragments N- et C-terminal de Pc1 (NTF et CTF, respectivement) qui eux s’associent de manière non-covalente. Nous avons démontré de façon importante que le trafic de Pc1deN i.e., une forme NTF détachée du CTF, est toutefois dépendant de l’intégrité du fragment CTF in vivo. Par la suite, nous avons généré un premier modèle humanisant une mutation PKD1 non-sens tronquée au niveau du domaine NTF(E3043X) en la reproduisant chez une souris transgénique (Pkd1extra). Structurellement, cette mutation, qui mimique la forme Pc1deN, s’est également avérée causative de PKD. Le modèle Pkd1extra a permis entre autre de postuler l’existence d’une cross-interaction entre différentes formes de Pc1. De plus, nos deux modèles murins sont tous les deux associés à des niveaux altérés de c-Myc et Pc2, et soutiennent une implication réelle de ces derniers dans l’ADPKD tou comme une interaction fonctionnelle entre les polycystines. Finalement, nous avons démontré un chevauchement significatif entre l’ADPKD et le dommage rénal aigüe (ischémie/AKI) dont une expression augmentée de Pc1 et Pc2 mais aussi une stimulation de plusieurs facteurs cystogéniques tel que la tubérine, la β-caténine et l’oncogène c-Myc. Nos études ont donc apporté des évidences cruciales sur la contribution du gène dosage dans l’ADPKD. Nous avons développé deux modèles murins qui serviront d’outil pour l’analyse de la pathologie humaine ainsi que pour la validation préclinique ADPKD. L’identification d’une nouvelle forme de Pc1 ajoute un niveau de complexité supplémentaire expliquant en partie une capacité de régulation de plusieurs voies de signalisation par Pc1. Nos résultats nous amènent à proposer de nouvelles approches thérapeutiques: d’une part, le ciblage de CTF i.e., de style chaperonne, et d’autre part le ciblage de modulateurs intracellulaires (c-Myc, Pc2, Hif1α). Ensemble, nos travaux sont d’une importance primordiale du point de vue informatif et pratique pour un avancement vers une thérapie contre l’ADPKD. Le partage de voies communes entre AKI et ADPKD ouvre la voie aux approches thérapeutiques parallèles pour un traitement assurément beaucoup plus rapide. / Autosomal dominant polycystic kidney disease (ADPKD) is one of the most common genetic diseases. ADPKD is manifested by the presence of renal cysts detected most often in the adult stage, and frequently liver cysts, with highly variable progression. ADPKD leads to kidney failure with the only recourse of dialysis and eventual kidney transplantation. Mutations dispersed throughout the PKD1 gene (major player, the polycystin-1 protein, PC1) and the PKD2 gene (polycystin-2 protein, PC2) are responsible for ADPKD. The loss of function (LOF) pathogenetic mechanism, and therefore a cellular recessive effect, has been suggested as causative of ADPKD. LOF is indeed supported by the PKD1/PKD2 gene inactivation mouse models, which develop cysts, although in utero with impressive speed in the kidney but not in the liver. Despite many in vitro studies, the membrane/ciliary role of PC1/PC2 remains rather hypothetical and context-dependent. These studies have associated PC1/PC2 to a variety of signaling pathways and underlined exceptional structural and functional complexity, whose involvement has been tested especially in LOF models. However, pathocellular observations in humans with sustained and even increased expression of PKD1/PC1, and the absence of particular human extrarenal phenotypes questions the exclusivity of the LOF mechanism. It was therefore essential 1) to clarify the pathogenetic mechanism, 2) to generate in vivo tools authentic of ADPKD in terms of initiation and progression of the disease and 3) to better understand the essential functions of PC1/PC2 for an adequate clinical translation. This thesis addresses all of these issues. First, we demonstrated that an increase in endogenous PKD1, just like in humans, is pathogenetic by generating and characterizing in detail a transgenic mouse model of Pkd1 (Pkd1TAG). This model not only reproduces the renal human characteristics associated with defects of the primary cilium, but also the extrarenal, namely, liver cysts. The severity of the phenotype correlates with the expression level of Pkd1, which strongly supports a dosage model. Secondly, we have demonstrated with genetic complementation studies that these two organs rely on a balance of Pc1 GPS cleavage, a typical post-translational modification of aGPCR, whose activity and abundance seem strictly controlled. Furthermore, we have extensively characterized Pc1 biogenesis and its derivatives in vivo generated upon GPS cleavage. We have identified a new form, predominantly on the membrane, the Pc1deN form, in addition to confirming the two N- and C-terminal Pc1 fragments (NTF and CTF, respectively), which associate non-covalently. Importantly, we have demonstrated that traffic of Pc1deN i.e., the NTF form detached from the CTF, is still dependant on the integrity of the CTF fragment. Next, we generated a first model humanizing a PKD1 nonsense truncated mutation at the level of the NTF(E3043X) domain by reproducing it in a transgenic mouse (Pkd1extra). Structurally, this mutation, which mimics Pc1deN, has also been shown to be causative of PKD. The Pkd1extra model allowed the proposition of the existence of a cross-interaction between different forms of Pc1. In addition, our two mouse models are both associated with altered levels of c-Myc and Pc2, which is supportive of their involvement in ADPKD and a functional interaction between the polycystins. Finally, we have shown a significant overlap between ADPKD and acute renal injury (ischemia/AKI) namely increased expression of Pc1 and Pc2 but also stimulation of several cystogenic factors such as tuberin, β-catenin and the oncogene c-Myc. Our studies have therefore given crucial evidence to the contribution of PKD1 gene dosage mechanism in ADPKD. We have developed two mouse models, which can serve as a tool for the analysis of human pathology as well as for preclinical validation of ADPKD. The identification of a new form of Pc1 adds an additional level of complexity in part explaining the regulation capacity of Pc1 on several signaling pathways. Our findings lead us to propose new therapeutic approaches: firstly, targeting the CTF i.e., chaperone style, and also targeting intracellular modulators (c-Myc, Pc2, Hif1α). Together, our work is of paramount importance in an informative point of view and practical perspective for progress towards a therapy for treating ADPKD. The sharing of common pathways between AKI and ADPKD paves the way for parallel therapeutic approaches for assured much faster treatment. ADPKD Polycystine-1 Clivage GPS Dommages rénaux Souris Foie C-Myc Pc2 ADPKD Polycystin-1 GPS cleavage AKI Mouse models Kidney Liver C-Myc Pc2
118	Mechanismus karcinogenity a nefrotoxicity aristolochových kyselin / Mechanism of carcinogenicity and nephrotoxicity of aristolochic acids Bárta, František January 2012 (has links) Aristolochic acids (AA) are human carcinogens which have also very strong nephrotoxic properties. A mixture of AA is present in Aristolochiacae plant species. These plants were and still are used in traditional medicine in some countries, particularly in Asia. Aristolochic acids participate in development of two types of nephropathies. The first disease is designated as Aristolochic Acid Nephropathy (AAN), the second one is Balkan Endemic Nephropathy (BEN). Both nephropathies are associated with urothelial malignancies, which are caused by AA. One of the common features of ANN and BEN is that not all individuals exposed to AA suffer from nephropathy and tumour development. One cause for these different responses may be individual differences in the activities and expression levels of the enzymes catalyzing the biotransformation of AAI, the major toxic component of AA contained in Aristolochia species. Detailed knowledge of enzymes which participate in metabolism of AAI may contribute to elucidation of inter-individual susceptibility to AAN, BEN and later urothelial malignancies. Aristolochic acid I is either oxidative detoxicated or reductive activated by biotransformation enzymes. Reductive bioactiovation of AAI leads to formation of covalent AA-DNA adducts in organism which result in producing of...
119	Gitelman & Gordon : mirror image syndromes reveal the roles of WNKs in blood pressure homeostasis and novel anti-hypertensive targets Siew, Keith January 2019 (has links) Study of Gordon (PHAII) and Gitelman (GS) syndromes revealed the importance of the WNK pathway and thiazide-sensitive Na-Cl Cotransporter (NCC) in the renal control of blood pressure. PHAII mutations lead to WNK accumulation resulting in the hyperphosphorylation of the downstream effector, SPAK, which overactivates NCC causing salt retention and hypertension. Mutations causing deletion of exon-9 in Cullin-3, which normally ubiquitylates WNKs for degradation, were recently discovered to cause the severest subtype of PHAII (PHA2E) with early onset salt-sensitive hypertension and hyperkalaemia. The reasons for this severity have remained elusive, however clues came from SPAK knock-out mice which recapitulate GS, the phenotypic mirror image of PHAII, typically caused by activation-inhibiting NCC phosphorylation site mutations resulting in salt-wasting and hypotension. As these mice were also discovered to have reduced vascular tone, it suggests the WNK pathway may have extra-renal roles in vascular smooth muscle function and highlights inhibition of SPAK function as a promising anti-hypertensive strategy with multiple sites of action. To address these possibilities the work aimed to phenotype: (1) heterozygous CUL3$^{WT/\Delta403-459}$ mice to investigate a possible vascular contribution to PHAII pathophysiology, (2) homozygous knock-out mice of MO25, a master regulator known to increase SPAK activity up to 100-fold independent of WNKs, and (3) homozygous SPAK$^{L502A/L502A}$ knock-ins, predicted to have disrupted SPAK binding to WNK/NCC, in order to validate SPAK signalling inhibition as a viable anti-hypertensive strategy. In mice, the CUL3$^{\Delta403-459}$ proteins are hyperflexible, hypermodified and ultimately have reduced WNK ubiquitylation. This lead to hypertension, hyperkalaemia, hyperchloraemia with compensated metabolic acidosis and growth retardation, which closely recapitulates human PHA2E. The discovery of increased vascular tone suggests an explanation for the severity of CUL3$^{\Delta}$$^{ex9}$PHAII. In mice, homozygous MO25$\alpha$ knock-out proved embryonically lethal, while homozygous MO25$\beta$ knock-out did not meaningfully alter blood pressure or electrolyte homeostasis. However, the SPAK$^{L502A}$ protein had a decreased ability to bind WNKs and cation-chloride cotransporters NCC and NKCC1/2, serving to reduce their activation. SPAK$^{L502A/L502A}$ mice showed typical features of GS with mild hypokalaemia, hypomagnesaemia, hypocalciuria and salt-wasting hypotension. The mice also presented with decreased markers of vascular tone potentially due to effects on cardiovascular and neuronal NKCC1. These results show that SPAK binding is crucial for blood pressure control and pharmacological inhibition of this binding is an attractive anti-hypertensive strategy.
120	Effect of Epigallocatechin-3-gallate on Skeletal and Cognitive Phenotypes in a Down Syndrome Mouse Model Abeysekera, Irushi Shamalka January 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Down syndrome (DS), a genetic disorder that affects ~1 in 700 live births, is caused by trisomy of human chromosome 21 (Hsa21). Individuals with DS are affected by a wide spectrum of phenotypes which vary in severity and penetrance. However, cognitive and skeletal impairments can be commonly observed in all individuals with DS. To study these phenotypes, we utilized the Ts65Dn mouse model that carries three copies of approximately half the gene orthologs found on Hsa21 and exhibit similar phenotypes as observed in humans with DS. Individuals with DS and Ts65Dn mice have deficits in bone mineral density (BMD), bone architecture, bone strength, learning and memory. Over-expression of DYRK1A, a serine-threonine kinase encoded on Hsa21, has been linked to deficiencies in DS bone homeostasis and cognition. Epigallocatechin-3-gallate (EGCG), an aromatic polyphenol found in high concentrations in green tea, is a selective inhibitor of DYRK1A activity. Normalization of DYRK1A activity by EGCG therefore may have the potential to ameliorate skeletal and cognitive deficits. We hypothesized that supplements containing EGCG obtained from health food stores/ online vendors will not be as effective as EGCG from a chemical company in correcting bone deficits associated with DS. Our results suggest that EGCG improves the bone mineral density of trisomic femurs significantly better than the supplements while the EGCgNOW supplement from NOW FOODS improves trabecular and cortical bone structure. The results from HPLC analysis of supplements showed the presence of other catechins in EGCgNOW and degradation analysis revealed the rapid degradation of supplements. Therefore we hypothesize that the presence of EGCG degradation products and other green tea catechins in supplements may play a role in the differential skeletal effects we observed. We further hypothesized that a three week treatment of adolescent mice with EGCG will lead to an improvement in the learning and memory deficits that are observed in trisomic animals in comparison to control mice. However, our results indicate that three weeks of low-dose EGCG treatment during adolescence is insufficient to improve hippocampal dependent learning and memory deficits of Ts65Dn mice. The possibility remains that a higher dose of EGCG that begins at three weeks but lasts throughout the behavioral test period may result in improvement in learning and memory deficit of Ts65Dn mice. Down syndrome, Mouse models Down syndrome -- Research -- Analysis Human chromosome abnormalities Learning ability -- Genetic aspects Memory -- Physiological aspects Cognition -- Research Animal models in research Mice as laboratory animals Green tea -- Health aspects Phenotype Bone densitometry Biomineralization

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