Global ETD Search

81	Glutamate Excitotoxicity In Epilepsy And Ischemia Soundarapandian, Mangala Meenakshi 01 January 2007 (has links) 'Excitotoxicity' represents the excitatory amino acid mediated degeneration of neurons. Glutamate is the major excitatory neurotransmitter in the brain. Glutamate excitotoxicity has been implicated in a number of neurodegenerative disorders like Stroke, Epilepsy, Alzheimer's disease and traumatic brain injury. This neurotoxicity is summed up by the 'glutamate hypothesis' which describes the cause of neuronal cell death as an excessive release of glutamate causing over excitation of the glutamate receptors and subsequent increase in influx of calcium leading to cell death. An effort to counteract this neurotoxicity has lead to the development of glutamate receptor antagonists that can effectively serve as neuroprotective agents. Nevertheless, the downside to these drugs has been the side effects observed in clinical trial patients due to their disruptive action on the physiological function of these receptors like learning and memory. This work was undertaken to identify targets that can effectively be used to treat excitotoxicity without affecting any normal physiological functions. In one approach, (chapter I) we have identified the KATP channels as an effective modulator of epileptogenesis. In another approach, (Chapter II) we show that targeting the AMPA receptor subunit GluR2 is a practical strategy for stroke therapy. KATP channels that are gated by intracellular ATP/ADP concentrations are a unique subtype of potassium channels and play an essential role in coupling intracellular metabolic events to electrical activity. Opening of KATP channels during energy deficits in the central nervous system (CNS) induces efflux of potassium ions and in turn hyperpolarizes neurons. Thus, activation of KATP channels is thought to be able to counteract excitatory insults and protect against neuronal death. Here, we show that, functional Kir6.1 channels are located at excitatory pre-synaptic terminals as a complex with type-1 Sulfonylurea receptors (SUR1) in the hippocampus. The mutant mice with deficiencies in expressing the Kir6.1 or the SUR1 gene are more vulnerable to generation of epileptic form of seizures, compared to wild-type controls. Whole-cell patch clamp recordings demonstrate that genetic deletion of the Kir6.1/SUR1 channels enhances glutamate release at CA3 synapses. Hence, expression of functional Kir6.1/SUR1 channels inhibits seizure responses and possibly acts via limiting excitatory glutamate release. In addition to epilepsy, ischemic stroke is a leading cause of death in developed countries. A critical feature of this disease is a highly selective pattern of neuronal loss; certain identifiable subsets of neurons, particularly CA1 pyramidal neurons in the hippocampus are severely damaged, whereas others remain intact. A key step in this selective neuronal injury is Ca2+/Zn2+ entry into vulnerable neurons through [alpha]-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptor channels, a principle subtype of glutamate receptors. AMPA receptor channels are assembled from glutamate receptor (GluR) -1, -2, -3, and -4 subunits. Circumstance data have indicated that the GluR2 subunits dictate Ca2+/Zn2+ permeability of AMPA receptor channels and gate injurious Ca2+/Zn2+ signals in vulnerable neurons. Here we show that ischemic insults induce toxic Ca2+ entry through AMPA receptors into vulnerable neurons by modification of GluR2 RNA editing. Thus, targeting of GluR2 subunit can be considered as a promising target for stroke therapy. Glutamate excitotoxicity Ischemia Epilepsy KATP channels Glutamate receptors Microbiology Molecular and Cellular Neuroscience Molecular Biology
82	The Endocytic Protein Numb Regulates App Metabolism And Notch Signaling: Implications For Alzheimer's Disease Kyriazis, George 01 January 2008 (has links) Increased production of amyloid beta (A-beta) peptide, via altered proteolytic cleavage of amyloid protein precursor (APP), and abnormalities in neuronal calcium homeostasis play central roles in the pathogenesis of Alzheimer's disease (AD). Notch1, a membrane receptor that controls cell fate decisions during development of the nervous system, has been linked to AD because it is a substrate for the gamma-secretase protein complex in which mutations cause early-onset inherited AD. Numb is an evolutionarily conserved endocytic adapter involved in the internalization of transmembrane receptors. Mammals produce four Numb isoforms that differ in two functional domains, a phosphotyrosine-binding domain (PTB) and a proline-rich region (PRR). Recent studies showed that the PTB domain of Numb interacts with the cytoplasmic tails of APP and Notch but the functional relevance of these interactions with respect to AD pathogenesis is not clear. In the current studies, we proposed to investigate the biological consequences of the interaction of the Numb proteins with APP and Notch in neural cells stably overexpressing each of the four human Numb proteins. In the first part of our studies, we found that expression of the Numb isoforms lacking the insert in the PTB (SPTB-Numb) caused the abnormal accumulation of cellular APP in the early endosomes, and increased the levels of C-terminal APP fragments and A-beta. By contrast, expression of the Numb isoforms with the insert in PTB (LPTB-Numb) leads to the depletion of cellular APP and coincides with significantly lower production of APP derivatives and A-beta. The contrasting effects of the Numb isoforms on APP metabolism were not attributed to differences in the expression of APP nor the activities of the various APP-processing secretases. In the second part of our studies, we found that expression of SPTB-Numb protein enhances neuronal vulnerability to serum deprivation-induced cell death by a mechanism involving the dysregulation of cellular calcium homeostasis. Neural cells expressing SPTB-Numb exhibited enhanced Notch activity, which markedly upregulated the expression of transient receptor potential canonical 6 (TRPC6) channels enhancing calcium entry in response to store depletion. We also found that serum deprivation increased TRPC6 expression, mediating the serum deprivation-induced death in neural cells. Interestingly, expression of LPTB-Numb protein suppressed serum deprivation-induced activation of Notch and the subsequent upregulation of TRPC6 and cell death. Finally, we showed that the Numb proteins differentially impact Notch activation by altering the endocytic trafficking and processing of Notch. Taken together, these studies demonstrate that aberrant expression of the Numb proteins may influence APP metabolism and Notch-mediated cellular responses to injury by altering their endocytic trafficking and processing. Alzheimer's numb APP notch TRPC calcium cell death protein trafficking Microbiology Molecular and Cellular Neuroscience Molecular Biology
83	Mcp-1 And App Involvement Of Glial Differentiation And Migration Of Neuroprogenitor Cells Vrotsos, Emmanuel 01 January 2009 (has links) Neuroprogenitor cells are an important resource because of their potential to replace damaged cells in the brain caused by trauma and disease. It is of great importance to better understand which factors influence the differentiation and migration of these cells. Previously it has been reported that neuroprogenitor cells undergoing apoptotic stress have increased levels of Amyloid precursor protein (APP) and increased APP expression results in glial differentiation. APP activity was also shown to be required for staurosporine induced glial differentiation of neuroprogenitor cells. Monocyte chemoattractant protein-1 (MCP-1) is a chemokine that is expressed during inflammatory. The binding of MCP-1 to its chemokine receptor induces expression of novel transcription factor MCP-1 induced protein (MCPIP). MCPIP expression subsequently leads to cell death. Previous studies have shown that pro apoptotic factors have the ability to induce neural differentiation. Therefore, we investigated if MCPIP expression leads to differentiation of NT2 neuroprogenitor cells. Results showed that MCPIP expression increased glial fibrillary acid protein expression and also caused distinct morphological changes, both indicative of glial differentiation. Similar results were observed with MCP-1 treatment. Interestingly, APP expression decreased in response to MCPIP. Instead, we found APP activity regulates expression of both MCP-1 and MCPIP. Furthermore, inhibition of either p38 MAPK or JAK signaling pathways significantly reduced APP's effect on MCP-1 and MCPIP. These data demonstrate the role APP has in glial differentiation of NT2 cells through MCP-1/MCPIP signaling. It is possible that increased APP expression after CNS injury could play a ii role in MCP-1 production, possibly promoting astrocyte activation at injured site. We next investigated the effect that MCP-1 has on NT2 cell migration. Studies have shown that when neuroprogenitor cells are transplanted into the brain they migrate towards damaged areas, suggesting that these areas express factors that recruit migrating cells. Generally, after neuronal injury there is a neuroinflammatory response that results in increased chemokine production. We demonstrate that MCP-1 significantly induces the migration of NT2 neuroprogenitor cells. Activation of intracellular cyclic adenosine monophosphate (cAMP) or protein kinase C with forskolin and phorbol 12-myristate 13-acetate (PMA), respectively, was able to completely abolish the MCP-1 induced migration. Contrarily, neither extracellular signal-regulated kinase or p38 mitogen activated protein kinase was required for NT2 cells to respond to MCP-1. Interestingly, APP's ability to activate MCP-1 expression was shown to play a role in NT2 cell migration. We showed that NT2 cells expressing APP were capable of inducing migration of other neuroprogenitor cells. Utilizing a MCP-1 neutralizing antibody we discovered that APP induced migration was not caused solely by increased MCP-1 production. Interestingly, APP increased expression of several C-C chemokines: MCP-1, Regulated upon Activation, Normal T-cell Expressed, and Secreted (RANTES), and macrophage inflammatory protein alpha (MIP-1 alpha). This demonstrates the unique role APP has in regulating chemokine production, which directly affects cell migration. Taken together, this study provides us with a greater understanding of the mechanisms involved in both glial differentiation and migration of NT2 neuroprogenitor cells. APP MCP-1 differentiation migration astrocytes neuroprogenitor neurons Microbiology Molecular and Cellular Neuroscience Molecular Biology
84	The Effect of Caffeine on Migraine Headaches Shimshoni, Deborah 01 January 2016 (has links) As the most widely consumed drug around the globe, there is a vast array of contradicting research available on caffeine. One of the most debated and researched topics on caffeine is its effect on the brain. Meanwhile, the data on the neurological condition of migraine has information scattered throughout countless research articles and experiments. Although neither migraine or caffeine are completely understood by the medical world, this analysis attempts to give a more coherent understanding of the relationship between the two. This is done by first understanding the known and theorized mechanisms of caffeine as well as the pathologies of migraine. Discussions on channelopathies, current migraine medications, and case studies will be presented. After much background research, we hypothesized that caffeine could excite neurons at physiological concentrations to the point of activation. This was tested by targeting the transcription factor cFos using immunocytochemistry in vitro. The protein cFos was identified due to its rapid translation—just 15 minutes after stimuli—to indicate activation. In addition to a control culture, three different caffeine concentrations were tested on the neurons: 50 micromoles— average plasma level after 1-2 cups of coffee consumption, 100 micromoles—average plasma level after 5-6 cups of coffee also believed to be the therapeutic amount to defend against neurological diseases such as Alzheimers Disease, and 250 micromoles—the average plasma level considered to be toxic in humans. Indeed, we saw a 53.8% increase in cFos expression in the neurons as 100 micromolar of caffeine was added and exposed to the cell cultures for 24 hours. In order to ensure the results obtained in this study were physiologically relevant in vivo, known toxic levels were tested for in vitro neurotoxicity. It was found in vitro that at the non toxic plasma concentrations of 50 micromolar and 100 micromolar of caffeine did not display cellular death as tested by Trypan Blue viability testing, Crystal Violet morphologies, and fleurojade immunochemistry that tests for degeneration. Each of these experiments identified a significant death increase as the toxic level of 250 micromoles of caffeine were utilized. This allowed us to theorize that the activation of neurons found in these experiments due to caffeine exposure would apply the same effect in vivo. Caffeine Migraine cFos Channelopathy Excitation Neurons Medical Neurobiology Molecular and Cellular Neuroscience Neurosciences
85	Investigating the Role of Neuronal Aging in Fragile X-Associated Tremor/Ataxia Syndrome Hencak, Katlin Marie 01 January 2019 (has links) Fragile X-associated tremor/ataxia syndrome (FXTAS) is an X-linked late-onset neurodegenerative disorder caused by a noncoding trinucleotide repeat expansion in the FMR1 gene. This gene produces fragile x mental retardation protein (FMRP), an RNA binding protein whose targets are involved in brain development and synaptic plasticity. One of the proposed mechanisms of FXTAS pathogenesis is an RNA gain-of-function in which the repeat expansion causes toxic mRNA that sequesters important proteins in the cell, interfering with their functions. Another suggested method of pathogenesis is through a mutant protein called FMRpolyG. This protein results from repeat-associated non-AUG (RAN) translation, in which the expanded repeats are translated where they otherwise would not be. This protein co-localizes with intranuclear inclusions and nuclear membrane proteins, causing disorganization of the nuclear lamina in FXTAS patient brain samples and neurons differentiated from FXTAS patient-derived induced pluripotent stem cells (iPSCs). iPSC technology involves reprogramming an adult somatic cell back to an embryonic-like state, allowing it to be differentiated into all cell types. A limit with iPSCs, though, is modeling late-onset disorders because the cells lose all age-related features during reprogramming. Progerin, a truncated form of the lamin A protein, has been used to age neurons differentiated from Parkinson Disease (PD) patient-derived iPSCs. Progerin-mediated aging was found to unmask PD-like phenotypes in those neurons, making it a promising technology for modeling late-onset disorders such as FXTAS. In this study, we investigated the link between the aging process and FXTAS pathogenesis in neurons differentiated from FXTAS patient-derived iPSCs with the use of progerin. Progerin transduction was successful in aging the FXTAS neurons. The presence of FMRpolyG was confirmed and an interaction with Lap2b was observed. In some neurons, there was also an observed interaction between FMRpolyG and progerin. Overall, this data suggests that there is an interaction between the mutant FMRpolyG protein and the nuclear membrane during aging, which may contribute to the cell death that causes neurodegeneration in FXTAS patients. stem cells aging neurodegeneration neurons Biology Molecular and Cellular Neuroscience Nervous System Diseases
86	The Role of Sox4 in Regulating Choroid Fissure Closure and Retinal Neurogenesis Wen, Wen 01 January 2016 (has links) The development of the vertebrate eye is tightly controlled by precise genetic regulations. From a single ocular primordium to bilateral eyes with complex structures and cell types, it requires intensive proliferation and migration for cells in both the ectoderm and mesoderm to accomplish ocular morphogenesis, and during this process cell differentiation and interaction takes place to establish the complex composition of ocular cell types and cellular connections. Genetic defects can lead to severe abnormalities in eye morphogenesis and cell differentiation during ocular development. A tremendous amount of work has been done to identify both intrinsic and extrinsic factors that regulate ocular development. However, much more work is needed to fully understand this complex process. Sox4 is known as a transcription activator that regulates cell survival and differentiation in multiple embryonic tissues during development. Evidence of its requirement during ocular development has recently emerged, but the mechanism by which Sox4 regulates ocular development is far from elucidated. Chapter 1 of this dissertation provides an overview of different stages in embryonic eye development and known genetic interactions during each stage. It also reviews recent knowledge about SoxC proteins and their roles in ocular development. Chapter 2 presents data characterizing the expression profile of the zebrafish sox4 co-orthologs, sox4a and sox4b, in the developing eye. Additionally, it presents data from morpholino-mediated sox4 knockdown in zebrafish, which indicate that Sox4 deficiency leads to defects in choroid fissure closure through elevation in the Hedgehog (Hh) signaling pathway. Sox4 knockdown causes upregulation of the Hh ligand indian hedgehog b (ihhb), which alters the proximal-distal boundary of the optic vesicle and inhibits choroid fissure closure. Chapter 3 presents data reporting the generation of sox4 mutant zebrafish lines using the CRISPR/Cas9 genome editing system. Characterization of one sox4a maternal zygotic (MZ) mutant line confirms Sox4’s role in negative regulation of Hh signaling and reveals new evidence that maternal and zygotic sox4 are both critical for ocular development. Chapter 4 presents data demonstrating that sox4 is required for rod photoreceptor neurogenesis. Rod photoreceptor terminal differentiation is delayed in both sox4 morphants and sox4 CRISPR mutants, while rod progenitor and precursor cells are properly specified. In Chapter 5, the roles of Sox4 in regulating ocular development are summarized based on the results, and implications of the results are discussed to expand our understanding of the genetic regulation of ocular morphogenesis and retinal neurogenesis. Sox4 Eye development Coloboma Hedgehog signaling Rod photoreceptor CRISPR/Cas9 Developmental Biology Eye Diseases Genetics Molecular and Cellular Neuroscience
87	DIET-INDUCED OBESITY: DOPAMINERGIC AND BEHAVIORAL MECHANISMS AS OUTCOMES AND PREDICTORS Narayanaswami, Vidya 01 January 2013 (has links) Obesity and drug abuse share common neural circuitries including the mesocoticolimbic and striatal dopamine reward system. In the current study, a rat model of diet-induced obesity (DIO) was used to determine striatal dopamine function, impulsivity and motivation as neurobehavioral outcomes and predictors of obesity. For the outcome study, rats were randomly assigned a high-fat (HF) or a low-fat (LF) diet for 8 wk. Following the 8-wk HF-diet exposure, rats were segregated into obesity-prone and obesity-resistant groups based on maximum and minimum body weight gain, respectively, and neurobehavioral outcomes were evaluated. For the predictor study, neurobehavioral antecedents were evaluated prior to an 8-wk high-fat diet exposure and were correlated with subsequent body weight gain. Striatal D2 receptor density was determined by in vitro kinetic analysis of [3H]raclopride binding. DAT function was determined using in vitro kinetic analysis of [3H]dopamine uptake, methamphetamine-evoked [3H]dopamine overflow and no net flux in vivo microdialysis. DAT cell-surface expression was determined using biotinylation and Western blotting. Impulsivity and food-motivated behavior were determined using a delay discounting task and progressive ratio schedule for food-reinforcers, respectively. Relative to obesity-resistant, obesity-prone rats exhibited 18% greater body weight, 42% lower striatal D2 receptor density, 30% lower total DAT expression, 40% lower in vitro and in vivo DAT function, 45% greater extracellular dopamine concentration, and 2-fold greater methamphetamine-evoked [3H]dopamine overflow. Obesity-prone rats exhibited higher motivation for food, but were less impulsive relative to obesity-resistant rats. Neurobehavioral antecedents of DIO included greater motivation for high-fat reinforcers in rats subsequently shown to be obesity-prone relative to obesity-resistant. Impulsivity, DAT function and extracellular dopamine concentration did not predict the DIO-phenotype. Thus, motivation for food is linked to both initiation and maintenance of obesity. Importantly, obesity results in decreased striatal DAT function, which may underlie the maintenance of compulsive food intake in obesity. Diet-induced obesity dopamine transporter impulsivity motivation striatum Behavioral Neurobiology Disease Modeling Molecular and Cellular Neuroscience Other Physiology Pharmacology
88	THE CELLULAR NUCLEIC ACID BINDING PROTEIN IN AGING AND DISEASE Webb, Robin 01 January 2013 (has links) The ZNF9 gene on chromosome 3 encodes the cellular nucleic acid binding protein (CNBP), a ubiquitously expressed, 177 amino acid (≈19.5kDa) protein that is highly conserved among vertebrates. The function of the protein is largely unknown, however an expansion in the first intron of the protein results in myotonic dystrophy type 2 (DM2), a multisystemic disease featuring cardiac arrhythmia, muscle wasting, cataracts, and a range of neuropathologies. Remarkably, we recently discovered that CNBP is involved in regulating the activity of β-secretase, the enzyme that produces the first cleavage event in the generation of the amyloid-β peptide (Aβ). The progressive fibrillization and deposition of Aβ is widely believed to be the primary causal factor in the development of Alzheimer’s disease (AD), and AD-like pathology in individuals with Down syndrome (DS). DS provides a unique model for evaluating how these factors change in the aged brain as compared to young brain, and how such changes affect the proportion of DS patients with AD. In the AD brain, both BACE1 and BACE2 increased from an early stage of disease; in DS brains, BACE1 significantly decreased (p<0.04) with age, whereas BACE2 was unchanged, even though the gene for BACE2 is located within the DS obligate region of chromosome 21. BACE1 and BACE2 activity levels were highly correlated in this series (r2 = 0.95), indicating that there may be a higher degree of shared regulation than previously believed. This implicates regulators of BACE as potentially critical for the development of AD, and our data suggests that CNBP may be one such regulator. In AD, CNBP increases early in the disease process, a change that does not occur in the normal aging process or in DS. CNBP and BACE protein levels were correlated in these cases (p<0.001), while there was no relationship between CNBP and age, or CNBP and Aβ, in either the human or mouse brain, indicating that CNBP does not increase as a consequence of normal aging. Thirty day overexpression of CNBP following adeno-associated viral delivery in murine gastrocnemius muscle resulted in an increase in BACE1 protein (p<0.01) and a consequential increase in Aβ production (p<0.01). Other experiments indicated that CNBP overexpression did not affect the half-life of BACE1 mRNA or protein, but resulted in an increase in BACE1 translation. These data indicate that CNBP is an important regulator of β-secretase, and may play an important role in the onset and progression of AD. Alzheimer’s disease Cellular Nucleic Acid Binding Protein Translational Regulation Down syndrome RNA binding protein Molecular and Cellular Neuroscience Molecular Biology
89	Elucidating the Role of Endogenous Electric Fields in Regulating the Astrocytic Response to Injury in the Mammalian Central Nervous System Baer, Matthew L 01 January 2015 (has links) Endogenous bioelectric fields guide morphogenesis during embryonic development and regeneration by directly regulating the cellular functions responsible for these phenomena. Although this role has been extensively explored in many peripheral tissues, the ability of electric fields to regulate wound repair and stimulate regeneration in the mammalian central nervous system (CNS) has not been convincingly established. This dissertation explores the role of electric fields in regulating the injury response and controlling the regenerative potential of the mammalian CNS. We place particular emphasis on their influence on astrocytes, as specific differences in their injury-induced behaviors have been associated with differences in the regenerative potential demonstrated between mammalian and non-mammalian vertebrates. For example, astrocytes in both mammalian and non- mammalian vertebrates begin migrating towards the lesion within hours and begin to proliferate after an initial delay of two days; subsequently, astrocytes in non-mammalian vertebrates support neurogenesis and assume a bipolar radial glia-like morphology that guides regenerating axons, whereas astrocytes in mammals do not demonstrate robust neurogenesis and undergo a hypertrophic response that inhibits axon sprouting. To test whether injury-induced electric fields drive the astrocytic response to injury, we exposed separate populations of purified astrocytes from the rat cortex and cerebellum to electric field intensities associated with intact and injured mammalian tissues, as well as to those electric field intensities measured in regenerating non-mammalian vertebrate tissues. Upon exposure to electric field intensities associated with uninjured tissue, astrocytes showed little change in their cellular behavior. However, cortical astrocytes responded to electric field intensities associated with injured mammalian tissues by demonstrating dramatic increases in migration and proliferation, behaviors that are associated with their formation of a glial scar in vivo; in contrast, cerebellar astrocytes, which do not organize into a demarcated glial scar, did not respond to these electric fields. At electric field intensities associated with regenerating tissues, both cerebellar and cortical astrocytes demonstrated robust and sustained responses that included morphological changes consistent with a regenerative phenotype. These results support the hypothesis that physiologic electric fields drive the astrocytic response to injury, and that elevated electric fields may induce a more regenerative response among mammalian astrocytes. Astrocyte electric field CNS injury regeneration Cell and Developmental Biology Laboratory and Basic Science Research Molecular and Cellular Neuroscience Other Neuroscience and Neurobiology
90	Neuromodulation Therapy Mitigates Heart Failure Induced Hippocampal Damage DiPeri, Timothy P 01 May 2014 (has links) Cardiovascular disease (CVD) is the leading cause of death in the United States. Nearly half of the people diagnosed with heart failure (HF) die within 5 years of diagnosis. Brain abnormalities secondary to CVD have been observed in many discrete regions, including the hippocampus. Nearly 25% of patients with CVD also have major depressive disorder (MDD), and hippocampal dysfunction is a characteristic of both diseases. In this study, the hippocampus and an area of the hippocampal formation, the dentate gyrus (DG), were studied in a canine model of HF. Using this canine HF model previously, we have determined that myocardial infarction with mitral valve regurgitation (MI/MR) + spinal cord stimulation (SCS) can preserve cardiac function. The goal of this study was to determine if the SCS can also protect the brain in a similar fashion. Both the entire hippocampus and the DG tissues were dissected from canine brains and analyzed. These findings provide strong evidence that, in addition to the cardioprotective effects observed previously, SCS following MI/MR induces neuroprotective effects in the brain. cardiovascular disease heart failure major depressive disorder spinal cord stimulation hippocampus dentate gyrus Biological Psychology Cardiovascular Diseases Molecular and Cellular Neuroscience

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