Global ETD Search

71	An investigation into the neuroprotective effects of estrogen and progesterone in a model of homocysteine-induced neurodegeration Wu, Wing Man January 2006 (has links) Homocysteine (Hcy) is a sulfur containing amino acid and is a potent neurotoxin. It has been shown that elevated levels of Hcy, termed hyperhomocysteinemia, plays a role in the pathologies of Alzheimer’s disease (AD) and age-related cognitive decline. Hcy is a glutamate agonist, which causes in increase in Ca[superscript (2+)] influx via the activation of NMDA class of excitatory amino acid receptors, which results in neuronal cell death and apoptosis. Estrogen and progesterone are female hormones that are responsible for reproduction and maternal behaviour. However, in the last decade, it is evident that both female hormones have neuroprotective properties in many animal models of neurodegeneration. Collectively, both estrogen and progesterone reduce the consequences of the oxidative stress by enhancing the antioxidant defence mechanisms, reducing excitotoxicity by altering glutamate receptor activity and reducing the damage caused by lipid peroxidation. However, the mechanisms by which estrogen and progesterone provide such neuroprotection probably depend on the type and concentration of hormone present. Moreover, numerous studies have shown that hormone replacement therapy (HRT, estrogen and progestins) or estrogen-only replacement therapy (ERT) may prevent or delay the onset of AD and improve cognition for women with AD. Clinical trials have also shown that women taking HRT may modify the effects of Hcy levels on cognitive functioning. Oxidative stress increases in the aging brain and thus has a powerful effect on enhanced susceptibility to neurodegenerative disease. The detection and measurement of lipid peroxidation and superoxide anion radicals in the brain tissue supports the involvement of free radical reactions in neurotoxicity and in neurodegenerative disorders. The hippocampus is an important region of the brain responsible for the formation of memory. However, agents that induce stress in this area have harmful effects and could lead to dementia. This study aims to investigate and clarify the neuroprotective effects of estrogen and progesterone, using Hcy-induced neurodegenerative models. The initial studies demonstrate that estrogen and progesterone have the ability to scavenge potent free radicals. Histological studies undertaken reveal that both estrogen and progesterone protect against Hcy-induced neuronal cell death. In addition, immunohistochemical investigations show that Hcy-induced apoptosis in the hippocampus can be inhibited by both estrogen and progesterone. However, estrogen also acts at the NMDA receptor as an agonist, while progesterone blocks at the NMDA receptor. These mechanisms reduce the ability of Hcy to cause damage to neurons, since Hcy-induced neurotoxicity is dependent on the overstimulation of the NMDA receptor. SOD and GPx are important enzymatic antioxidants which can react with ROS and neutralize them before these inflict damage in the brain. Hcy can increase oxidative stress by inhibiting expression and function of these antioxidants. However, it has been shown that the antioxidant abilities of both estrogen and progesterone can up-regulate the activities of SOD and GPx. These results provide further evidence that estrogen and progesterone act as antioxidants and are free radical scavengers. The discovery of neuroprotective agents is becoming important as accumulating evidence indicates the protective role of both estrogen and progesterone in Hcy-induced neurodegeneration. Thus further work in clinical trials is needed to examine whether reducing Hcy levels with HRT can become the treatment of neurodegenerative disorders, such as Alzheimer’s disease. Homocysteine Estrogen Estrogen -- Therapeutic use Progesterone Hormone receptors Methyl aspartate Oxidative stress Alzheimer's disease -- Treatment
72	Epitranscriptomic Alterations in Alzheimer’s Disease: The Role of MicroRNA Methylation in the Regulation of Tau Proteostasis Kim, Yoon Anna January 2021 (has links) The imbalance in the levels of certain microRNAs (miRNAs) in Alzheimer’s disease (AD) brains promotes alterations in tau proteostasis and neurodegeneration. However, potential mechanisms governing how specific miRNAs are dysregulated in AD brains are still under investigation. Epitranscriptomics is a mode of post-transcriptional regulation that can control brain functions during development and adulthood. NOP2/Sun RNA methyltransferase 2 (NSun2) is one of the few known brain-enriched methyltransferases that has the ability to modify mammalian non-coding RNAs. Importantly, autosomal-recessive loss of function mutations in NSun2 have been associated with neurological abnormalities in humans. Here, we report that dysregulation of NSun2 can induce alterations in tau phosphorylation by modulating the levels of miR-125b, a main player in tau pathology. We were able to provide supporting evidence by utilizing several model systems such as Drosophila, human induced pluripotent stem cell (iPSC) derived neurons, rat primary neuronal cultures and mice. Our Western blot analysis not only shows that NSun2 is expressed in adult human neurons in the hippocampal formation and prefrontal cortex, but also NSun2 protein expression levels are downregulated in post-mortem brain tissues from AD patients. Remarkably, we also found decreased NSun2 protein levels in AD mice and human cellular models. To prove these observed alterations were unique to AD, we further evaluated brain tissues from other tauopathies. Strikingly, NSun2 protein levels were similar between tauopathy cases and controls indicating that dysregulation of NSun2 might be unique to AD cases. Further, we investigated the pathological role of NSun2 by utilizing a well-established Drosophila melanogaster model of tau-induced toxicity. We found that a reduction of NSun2 protein levels exacerbated tau toxicity while overexpression of NSun2 partially abrogated toxicity proving bidirectionality. We used a lentiviral system to knock down NSun2 expression in iPSC derived neuronal cultures. Western blot analysis and immunofluorescence staining showed a significant change in tau phosphorylation levels. To investigate what could be triggering observed alterations in NSun2 levels, we performed experiments in rat primary hippocampal neurons. We found that the treatment with oligomeric amyloid-beta A caused a decrease in NSun2 protein levels and at the same time, increased tau phosphorylation levels in primary hippocampal neurons. Lastly, we performed RNA immunoprecipitation coupled with qPCR and histological analysis using NSun2 conditional knockout (KO) mice and observed that NSun2 deficiency promoted aberrant levels of m6A methylated miR-125b and tau hyperphosphorylation. Altogether, our study demonstrates that neuronal NSun2 deficiency in AD promotes neurodegeneration by altering tau phosphorylation and tau toxicity through an epitranscriptomic regulatory mechanism and highlights a potential novel therapeutic target. Neurosciences Pathology Molecular biology Alzheimer's disease--Genetic aspects MicroRNA Methyltransferases Nervous system--Degeneration Phosphorylation Drosophila--Genetics Rats--Genetics Mice--Genetics
73	The effect of air pollution on aggravation of neurodegenerative diseases: an analysis of long-term exposure to fine particulate matter and its components Nunez, Yanelli January 2020 (has links) Background: Air pollution is one of the leading environmental issues in the world today. In 2015, pollution-related diseases accounted for 16% of all deaths worldwide — that is an estimated 9 million premature deaths were linked to air pollution. In addition to the substantial effects on human health, air pollution-related diseases result in productivity losses that reduce countries’ gross domestic product. Although air pollution disproportionately affects middle- and low-income countries, it is still a major issue in high-income countries, such as the United States, where 25% of Americans breath air with pollutant levels above the national regulatory standards. Fine particle matter (particles with diameter ≤ 2.5 μm, PM₂.₅ ) is the most extensively studied air pollutant and it has been causally linked with a wide range of adverse health outcomes, including cardiovascular and pulmonary disease, myocardial infarction, hypertension, congestive heart failure, arrhythmias, chronic obstructive pulmonary disease, and lung cancer. Moreover, recent scientific evidence suggests that PM₂.₅ affects the nervous system and possibly contributes to the development and exacerbation of neurodegenerative diseases. This is increasingly relevant as populations are aging and the number of adults living with neurodegenerative diseases increases, negatively affecting families, communities, and health-care systems around the world. Although millions of people suffer from neurodegenerative diseases, there is currently no treatment that slows the progression of these conditions and no known cure or cause. Thus, determining whether a link exists between air pollution and neurodegenerative diseases is a goal of increasing importance. Objective: The research presented in this dissertation has two main objectives: (1) to characterize the relationship between long-term exposure to PM₂.₅ and disease aggravation in two of the most prevalent neurodegenerative diseases worldwide: Alzheimer’s (AD) and Parkinson’s disease (PD), as well as in the rare and devastating neurodegenerative motor disorder amyotrophic lateral sclerosis (ALS); (2) to identify the specific PM₂.₅ chemical components that are associated with disease aggravation in PD. Methods: We used data from the New York Department of Health Statewide Planning and Research Cooperative System from 2000–2014 to identify patients’ first hospitalization with a primary or secondary diagnosis of AD, PD, or ALS. With these data, we constructed annual AD, PD, and ALS first hospitalization county counts (total and sex- and age-stratified) for all of New York State (NYS). A patient’s first hospital admission was used as a surrogate for disease aggravation, indicating the crossing point into a more severe stage of the disease. We used prediction estimates from well-validated models that incorporate satellite information and ground-based monitoring data to estimate annual PM₂.₅ and PM₂.₅ chemical component (nitrate, sulfate, organic matter, sea salt, black carbon, and soil) concentrations across NYS at a high spatial resolution. In Chapter 2, we used outcome-specific (AD, PD, or ALS) mixed quasi-Poisson models with county-specific random intercepts to assess the relationship between long-term exposure to PM₂.₅ and disease aggravation. In Chapter 3, we used a multi-pollutant mixed quasi-Poisson model with county-specific random intercepts to identify specific PM₂.₅ components associated with disease aggravation in PD. In all analyses, we evaluated potential nonlinear exposure–outcome relationships using penalized splines and accounted for potential confounders. Results: We observed a total of 264,075 AD, 114,514 PD, and 5,569 ALS first admissions between 2000 and 2014. The hospitalization annual average counts per county were 284, 131, and 6 for AD, PD, and ALS, respectively. In Chapter 2, we found a nonlinear association between total PM₂.₅ exposure and PD hospitalizations, which plateaued at higher concentrations of PM₂.₅ (> 13 μg/m³, RR=1.08, 95% CI: 1.04–1.13 for a PM₂.₅ increase from 8 to 10 μg/m³, Figure 2.3). We also found that patients with a first PD hospitalization at age 70 or younger are at slightly higher risk for disease aggravation at lower PM₂.₅ concentrations relative to those age >70. In the case of AD, we observed evidence of a potential association between annual increases in PM₂.₅ exposure and disease aggravation, but only in a sensitivity analysis aiming to decrease outcome misclassification. We found no association for ALS in the main analysis, but we observed an unexpected negative association in those <70 years in the stratified analysis. We found no evidence of effect modification by sex for any of the outcomes. In Chapter 3, we observed a linear association between disease aggravation in PD and long-term exposure to the PM₂.₅ components nitrate (RR = 1.05, 95%CI: 1.02–1.09 per one standard deviation (SD) increase) and organic matter (RR = 1.05, 95%CI: 1.02– 1.07 per one SD increase), and a nonlinear association for black carbon with a negative association above the 96th percentile of the BC concentration distribution (Figure 3.4). We found no evidence of an association with sulfate, sea salt or soil. Conclusion: Overall, our studies provide an analysis of the potential association between long-term exposure to PM₂.₅ , both as an overall pollution mixture and by chem- ical composition, and disease aggravation in AD, PD, and ALS. Our findings suggest that annual increases in county-level PM₂.₅ concentrations are associated with disease aggravation in PD and possibly AD. We found that the PM₂.₅ components organic matter and nitrate are particularly harmful in the association between PM₂.₅ and dis- ease aggravation in PD. Additionally, our results indicate that current national PM₂.₅ standards may not be strict enough to safeguard the population’s neurological health. Specifically, in Chapter 2, we observed that the PM₂.₅ –PD association has a steeper slope at lower concentrations that are well below the current annual National Ambient Air Quality Standards for PM₂.₅ . Thus, our findings warrant further investigation into the potential link between long-term PM₂.₅ exposure and disease aggravation, particularly in the context of PD. Our results also indicate that the chemical composition of PM2.5 affects its neurotoxicity. Further research into how PM₂.₅ composition influences the overall PM₂.₅ adverse effects is needed to fully understand the mechanisms that underlie the association between exposure to PM₂.₅ and aggravation of neurodegenerative diseases. Environmental health Epidemiology Toxicology Air--Pollution Nervous system--Degeneration Alzheimer's disease--Pathogenesis Amyotrophic lateral sclerosis Parkinson's disease
74	Increased Glutathione Metabolic Defense Capabilities in Cultured Alzheimer's Diseased Lymphoblast Cell Lines Shaw, Collin M. 09 November 1998 (has links) The hypothesis to be tested states that the pathology of Alzheimer's disease (AD) involves elevated levels of oxidative stress, resulting in elevated levels of cellular oxidative defense mechanisms. If the premise is true, than AD pathologically afflicted cells should have a higher demand for glutathione (GSH) as an innate oxidative defense mechanism hence; greater GSH concentrations, increased GSH resynthesis capabilities, and increased levels of cystathionine gamma-lyase (CNase). Alzheimer diseased and age matched control lymphoblast cells, obtained from OHSU's Oregon Brain Aging Study, were cultured, and GSH biochemistry was subsequently evaluated. GSH was depleted by exposing cells to the GSH depleting agent diethylmaleate (DEM) and the resulting GSH concentrations were measured. GSH resynthesis was measured after depleting GSH with DEM, to a level of approximately half base GSH concentration, then removing the depleting agent, resuspending the cells in fresh medium (DEM-free), and subsequently measuring GSH levels. GSH concentrations were measured by HPLC, and all data was normalized to cellular protein concentration. Cellular CNase specific activity levels were measured by adding cytasthionine, the CNase substrate, and then measuring the amount of cysteine produced by means of the DTNB assay. The AD cell lines showed no increase in base levels of GSH as compared to control cell lines. The AD cell lines showed a statistically significant increase in GSH resynthesis capabilities and cystathionine gamma-lyase specific activity levels. These findings add further weight to the AD oxidative stress hypothesis, which is based on the premise that the causative agent of AD pathogenesis is an increase in the level of cellular free radicals produced. Alzheimer's disease -- Pathophysiology Glutathione -- Metabolism Lymphocytes Oxidative stress Nervous system -- Degeneration Nervous System Diseases Other Cell and Developmental Biology
75	NEURAL CORRELATES AND PROGRESSION OF SACCADE IMPAIRMENT IN PREMANIFEST AND MANIFEST HUNTINGTON DISEASE Rupp, Jason Douglas 15 October 2010 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Huntington disease (HD) is an autosomal dominant disorder characterized by progressive decline of motor, cognitive, and behavioral function. Saccades (rapid, gaze-shifting eye movements) are affected before a clinical diagnosis of HD is certain (i.e. during the premanifest period of the disease). Fundamental questions remain regarding the neural substrates of abnormal saccades and the course of premanifest disease. This work addressed these questions using magnetic resonance imaging (MRI) and a longitudinal study of premanifest disease progression. Gray matter atrophy is a characteristic of HD that can be reliably detected during the premanifest period, but it is not known how such changes influence saccadic behavior. We evaluated antisaccades (AS) and memory guided saccades (MG) in premanifest and manifest HD, then tested for associations between impaired saccadic measures and gray matter atrophy in brain regions involved in these saccadic tasks. The results suggest that slowed vertical AS responses indicate cortical and subcortical atrophy and may be a noninvasive marker of atrophic changes in the brain. We also investigated the brain changes that underlie AS impairment using an event-related AS design with functional MRI (fMRI). We found that, in premanifest and manifest HD, blood oxygenation level dependent (BOLD) response was abnormally absent in the pre-supplementary motor area and dorsal anterior cingulate cortex following incorrect AS responses. These results are the first to suggest that abnormalities in an error-related response network underlie early disease-related saccadic changes, and they emphasize the important influence of regions outside the striatum and frontal cortex in disease manifestations. Though saccadic abnormalities have been repeatedly observed cross sectionally, they have not yet been studied longitudinally in premanifest HD. We found different patterns of decline; for some measures the rate of decline increased as individuals approached onset, while for others the rate was constant throughout the premanifest period. These results establish the effectiveness of saccadic measures in tracking premanifest disease progression, and argue for their use in clinical trials. Together, these studies establish the utility of saccade measures as a marker of HD neurodegeneration and suggest that they would be a valuable component of batteries evaluating the efficacy of neuroprotective therapies. longitudinal fMRI MRI saccades Huntington disease Saccadic eye movements -- Research Huntington's chorea -- Research
76	EVALUATION OF GENE REGULATION AND THERAPEUTIC DRUGS RELATED TO ALZHEIMER’S DISEASE IN DEGENERATING PRIMARY CEREBROCORTICAL CULTURES Bailey, Jason A. 16 March 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Alzheimer’s disease (AD) is a neurological disorder defined by the presence of plaques comprised mostly of amyloid-β (Aβ), and neurofibrillary tangles consisting of hyperphosphorylated microtubule associated protein tau (MAPT). AD is also characterized by widespread synapse loss and degeneration followed by death of neurons in the brain. Inflammatory processes, such as glial activation, are also implicated. In order to study mechanisms of neurodegeneration and evaluate potential therapeutic agents that could slow or reverse this process, a tissue culture system was developed based on primary embryonic cerebrocortical neurons. This culture system was observed to exhibit time-dependent neurodegeneration, glial proliferation, and synaptic marker loss consistent with AD-affected brains. The regulatory promoter regions of several genes implicated in AD, including the Aβ precursor protein (APP), β-amyloid cleaving enzyme (BACE1), and MAPT, were studied in this culture model. The MAPT gene promoter activity followed the pattern of neuronal maturation and degeneration quite closely, increasing in the initial phase of the tissue culture, then reducing markedly during neurodegeneration while APP and BACE1 gene promoters remained active. Deletion series of these promoters were tested to give an initial indication of the active regions of the gene promoter regions. Furthermore, the effects of exogenous Aβ and overexpression of p25, which are two possible pathogenic mechanisms of gene regulation in AD, were studied. Response to Aβ varied between the promoters and by length of the Aβ fragment used. Overexpression of p25 increased MAPT, but not APP or BACE1, promoter activity. This neurodegeneration model was also used to study the putative neuroprotective action of the NMDA receptor antagonist memantine. Treatment with memantine prevented loss of synaptic markers and preserved neuronal morphology, while having no apparent effect on glial activation. The protective action on synaptic markers was also observed with two other structurally distinct NMDA receptor antagonists, suggesting that the effects of memantine are produced by its action on the NMDA receptor. It is concluded that this tissue culture model will be useful for the study of gene regulation and therapeutic agents for neurodegeneration, and that the efficacy of memantine may result from preservation of synaptic connections in the brain. Alzheimer synapse neurodegeneration primary culture memantine Alzheimer's disease -- Research Genetic regulation -- Research
77	NEUROPROTECTIVE STUDIES ON THE MPTP AND SOD1 MOUSE MODELS OF NEURODEGENERATIVE DISEASES Fontanilla, Christine V. 29 February 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The main, underlying cause of neurodegenerative disease is the progressive loss of neuronal structure or function, whereby central and/or peripheral nervous system circuitry is severely and irreversibly damaged, resulting in the manifestation of clinical symptoms and signs. Neurodegenerative research has revealed many similarities among these diseases: although their clinical presentation and outcomes may differ, many parallels in their pathological mechanisms can be found. Unraveling these relationships and similarities could provide the potential for the discovery of therapeutic advances such that a treatment for one neurologic disease may also be effective for several other neurodegenerative disorders. There is growing awareness that due to the complexity of pathophysiological processes in human disease, specifically targeting or inactivating a single degenerative process or a discrete cellular molecular pathway may be ineffective in the treatment of these multifaceted disorders. Rather, potential therapeutics with a multi-target approach may be required to successfully and effectively control disease progression. Recent advances in neurodegenerative research involve the creation of animal disease models that closely mimic their human counterparts. The use of both toxin- exposure and genetic animal models in combination may give insight into the underlying pathologic mechanisms of neurodegenerative disorders (target identification) leading to the development and screening of prospective treatments and determination of their neuroprotective mechanism (target validation). Taken together, ideal candidates for the treatment of neurodegenerative disease would need to exert their neuroprotective effect on multiple pathological pathways. Previous studies from this laboratory and collaborators have shown that the naturally-occurring compound, caffeic acid phenethyl ester (CAPE), is efficacious for the treatment against neurodegeneration. Because of its versatile abilities, CAPE was chosen for this study as this compound may be able to target the pathogenic pathways shared by two different animal models of neurodegeneration and may exhibit neuroprotection. In addition, adipose-derived stem cell conditioned media (ASC-CM), a biologically-derived reagent containing a multitude of neuroprotective and neurotrophic factors, was selected as ASC-CM has been previously shown to be neuroprotective by using both animal and cell culture models of neurodegeneration. ALS MPTP SOD1 neurodegeneration Amyotrophic lateral sclerosis Methylphenyltetrahydropyridine Superoxide dismutase
78	Drivers of Immune Dysregulation in Late-onset Alzheimer's Disease Roy, Nainika January 2024 (has links) The dysregulation of immune system function has been centrally implicated in numerous age-related and neurodegenerative disorders, including Alzheimer’s disease (AD). Genetic susceptibility studies have positioned microglia, brain-resident immune cells, as critical actors in the development and the progression of the disease. Microglia are highly plastic cells with diverse functions across many modalities, and the appropriate regulation of their activities are a prerequisite for central nervous system homeostasis and cognitive health. Aging and pathogenic contexts are posited to modify microglial behavior, inhibiting their neuroprotective function and promoting a dysfunctional state that drives disease. However, the mechanisms underlying these pathogenic alterations in microglial state and function are complex and poorly understood. This thesis identifies three elements that are altered in the AD brain and investigates how these mechanisms may serve as triggers producing microglial dysregulation in AD. Chapter 3 examines the role of expression of the transposable element LINE-1 in AD-related microglial dysfunction. Chapter 4 explores the regulation of PLCG2, which encodes a critical AD-associated signaling enzyme. Chapter 5 investigates the role of the AD-linked sorting receptor SORL1 in microglia. Together, these data expand our understanding of mechanisms driving altered microglial pathophysiology in AD and illuminate pathways of interest with potential therapeutic applications meriting deeper exploration. Neurosciences Alzheimer's disease--Pathophysiology Microglia Immunologic diseases Older people--Diseases Nervous system--Degeneration Nervous system--Diseases--Etiology
79	A molecular investigation of a mixed ancestry family displaying dementia and movement disorders Abrahams-Salaam, Fatima 12 1900 (has links) Thesis (MScMedSc (Biomedical Sciences. Molecular Biology and Human Genetics))--Stellenbosch University, 2008. / A South African family of Mixed Ancestry presented with a rapidly progressive dementia and a movement disorder which affected a number of individuals across three generations. The initial symptoms included personality changes and tremors that escalated to severe dementia and eventually a completely bedridden state. It was determined that the mean age at onset was in the third decade of life and affected individuals died within 10-15 years after the onset of symptoms. The aim of the present study was to elucidate the genetic cause of the disorder in this family and to further investigate the patho-biology of the disease. Mutations that could possibly cause the observed phenotype in this family were screened for. These included loci implicated in Huntington’s disease, Parkinson’s disease, Dentatorubral-Pallidoluysian Atrophy, Spinocerebellar ataxias (types 1, 2, 3, 6, and 7), Huntington’s disease-like 2 (HDL2) and several mitochondrial disorders. Single-strand Conformation Polymorphism (SSCP) analysis and direct sequencing were used to detect possible mutations while genotyping on an ABI genetic analyser was used to detect disorders caused by repeat expansions. Haplogroup and Short Tandem Repeats (STRs) analyses of the Y-chromosome and mitochondrial DNA of one affected family member was used to determine the family’s genetic ancestry. Reverse transcriptase polymerase chain reaction (RT- PCR) and complementary DNA (cDNA) analyses of the Junctophlin-3 (JPH3) gene was performed to provide information on the expression profile of this gene. After the exclusion of several genetic loci it was shown that this family had HDL2. This is a rare disease caused by a CAG/CTG repeat expansion in an alternatively spliced version of the JPH3 gene. HDL2 occurs almost exclusively in individuals of Black African ancestry. The genetic ancestry data suggested that the family member was most likely of South African Mixed Ancestry making this the first reported family of South African Mixed Ancestry with HDL2. A pilot study investigated the repeat distribution amongst three South African sub-populations in order to determine whether there was a bias in the repeat distribution that possibly predisposes Black Africans to develop the disease. The results showed a statistically significant difference (P= 0.0014) in the distribution of the repeats between the Black African and Caucasian cohorts. However, no conclusions could be drawn as to whether Black Africans harboured larger repeats that predisposes them to developing HDL2. The expanded repeat is located in an alternatively spliced version of the JPH3 mRNA. Interestingly, this repeat is not present in the mouse homologue of the gene although the rest of the genomic sequence is highly conserved across the human, mouse and chimpanzee genomes. Using foetal brain cDNA and PCR primers designed to be specific for different JPH3 isoforms, independent confirmation of the presence of two JPH3 mRNA transcripts (the full length and a shorter alternatively spliced version) was provided. In the absence of brain tissue from an HDL2-affected individual, it was investigated whether both JPH3 mRNA transcripts could be detected in lymphocytes. Using RNA isolated from the transformed lymphocytes of two HDL2-affected family members, real-time PCR was attempted. These experiments produced inconclusive results and required further optimisation. Further RT-PCR experiments for JHP3 expression in different tissues (brain and other) obtained from HDL2-affected individuals would be of interest. The present study identified the first Mixed Ancestry family with HDL2. This family will now be able to request genetic counselling and pre-symptomatic testing for all at-risk family members. Aspects of this study provided independent confirmation of characteristics of the mutated gene. More research on HDL2 will be crucial in understanding the pathogenesis of this disease. Dementia -- Molecular aspects Nervous system -- Degeneration Huntington’s disease -- Diagnosis Parkinson's disease -- Diagnosis Mixed ancestry diseases -- Diagnosis Dissertations -- Biomedical sciences Theses -- Biomedical sciences Dissertations -- Human genetics Theses -- Human genetics
80	In vivo imaging of retinal ganglion cells and microglia. / CUHK electronic theses & dissertations collection January 2010 (has links) A confocal scanning laser ophthalmoscope (CSLO) was used to image the axonal and dendritic aborizations of RGCs in the Thy-1 YFP mice. With quantitative analysis of cell body area, axon diameter, dendritic field, number of terminal branches, total dendritic branch length, branching complexity, symmetry and distance from the optic disc, the morphologies of RGCs and the patterns of axonal and dendritic degeneration were analyzed. After optic nerve crush, RGC damage was observed prospectively to begin with progressive dendritic shrinkage, followed by loss of the axon and the cell body. Similar pattern of RGC degeneration was observed after 90 minutes of retinal ischemia although no morphological changes were detected when the duration of ischemia was shortened to 30 minutes. The rate of dendritic shrinkage was variable and estimated on average 2.0% per day and 11.7% per day with linear mixed modeling, after optic nerve crush and retinal ischemic injury, respectively. RGCs with a larger dendritic field had a slower rate of dendritic shrinkage. / In summary, we demonstrated that dendritic shrinkage could be evident even before axonal degeneration after optic nerve crush and retinal ischemic injury. We have established a methodology for in vivo and direct visualization of RGCs and retinal microglia, which could provide reliable and early markers for neuronal damage. Measuring the rate of dendritic shrinkage and tracking the longitudinal activation of microglia would provide new paradigms to study the mechanism of neurodegenerative diseases and offer new insights in testing novel therapies for neuroprotection. / Progressive neuronal cell death and microglial activation are the key pathological features in most neurodegenerative diseases. While investigating the longitudinal profiles of neuronal degeneration and microglial activation is pertinent to understanding disease mechanism and developing treatment, analyzing progressive changes has been obfuscated by the lack of a non-invasive approach that allows long term, serial monitoring of individual neuronal and microglial cells. Because of the clear optical media in the eye, direct visualization of the retinal ganglion cells (RGCs) and microglia is possible with high resolution in vivo imaging technique. In this study, we developed experimental models to visualize and characterize the cellular morphology of RGCs and retinal microglia in vivo in the Thy-1 YFP and the CX3CR1 +/GFP transgenic mice, described the patterns of axonal and dendritic shrinkage of RGCs, discerned the dynamic profile of microglial activation and investigated the relationship between RGC survival and microglial activation after optic nerve crush and retinal ischemic injury induced by acute elevation of intraocular pressure. / The longitudinal profile of microglial activation was investigated by imaging the CX3CR1GFP/+ transgenic mice with the CSLO. Activation of retinal microglia was characterized with an increase in cell number reaching a peak at a week after optic nerve crush and retinal ischemic injury, which was followed by a gradual decline falling near to the baseline at the 4 th week. The activation of retinal microglia was proportional to the severity of injury. The number of RGCs survival at 4 weeks post-injury was significantly associated with the number of activated retinal microglia. / Li, Zhiwei. / Adviser: Leung Kai Shun. / Source: Dissertation Abstracts International, Volume: 73-02, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 50-66). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. Mice as laboratory animals Microglia Nervous system--Degeneration Ophthalmoscopes Retinal ganglion cells Disease Models, Animal Mice Microglia--pathology Neurodegenerative Diseases--pathology Ophthalmoscopes--utilization Retinal Ganglion Cells--pathology

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