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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Argos and the Spitz Group/der Pathway Function to Regulate Midline Glial Cell Numbers in Drosophila Embryos / Argos and Spitz Group/der Pathway Function in the MG

Stemerdink, Christopher 02 1900 (has links)
The midline glia (MG) perform an active role in the pioneering and morphogenesis ofthe commissural axons of the central nervous system (CNS) during Drosophila embryogenesis. Following the establishment of these commissural axon pathways, a subset of the MG undergoes apoptosis and the surviving MG remain to ensheath the commissures. Previous studies demonstrated that the pattern ofthis developmental apoptosis is stochastic. The surviving MG exhibit intersegment variability in their final number and position relative to the commissures. Interestingly, argos, a gene which encodes a diffusible extracellular factor with an epidermal growth factor (EGF) motif, is only expressed in MG which survive. argos expression in this subset of MG is initiated at the onset of apoptosis, reflecting the temporal pattern of cell death of the other MG. In argos loss-of-function mutants, there are extra surviving MG in each segment while ectopic over-expression of argos results in increased apoptosis among the MG. Therefore, Argos has a negative regulatory effect on MG survival. Its effects are opposite to the spitz group/Drosophila EGF receptor (DER) pathway, a cassette of genes required for MG survival. However, argos is hypostatic to the spitz group/DER pathway function and its expression requires a certain threshold of spitz group and DER pathway activity. Argos is postulated to act as an EGF receptor antagonist. It attenuates signaling of the DER pathway. Therefore, the regulation of MG survival is mediated by a balance of extracellular inductive and inhibitory signals. How can this signaling pathway be reconciled with the stochastic pattern of MG survival and the observation that only argos expressing MG survive? We propose a model in which the adherens junction along with possible accessory proteins like Rhomboid and Star mediate the close apposition of MG and promote intense Spitz mediated DER pathway signaling. The MG with the most concentrated coupling of this adhesion and signaling pathway network achieve sufficient DER signaling to express argos. These MG are in tum fated to assume a final differentiated identity and will remain to ensheathe the commissures. Argos is secreted and it mediates the apoptosis of MG with reduced levels of adhesion contacts and lower DER signaling (MG not expressing argos). The other mesectodermal cell (MEC) lineages appear to develop independently of argos function. The repercussions of HSargos elicited MG loss to the commissural axons and CNS cytoarchitecture was also examined. Removal of the MG through ectopic expression ofargos results in a loss of ensheathment and the commissural axon tracts are exposed to the haemolymph. Furthermore, the commissural axons are wider and they misexpress Fasciclin II, a phenotype reminiscent of mutations in roundabout. / Thesis / Master of Science (MSc)
2

The GDNF family of neurotrophic factors : effects on adult sensory neurons

Boucher, Timothy John January 2001 (has links)
No description available.
3

The protein kinase C of glia

Murphy, John Anthony January 1989 (has links)
No description available.
4

Interactions Between Dopamine Neurons and Radial Glial Cells In the Adult Goldfish Forebrain

Xing, Lei January 2016 (has links)
Aromatase is the only enzyme that converts androgens into estrogens, which is found in the brain, testes and ovaries. In teleosts, brain aromatase is exclusively expressed in radial glial cells, which are the abundant stem-like non-neuronal progenitors involved in neuroendocrine functions and neurogenesis in the central nervous system. With little information about radial glial cell regulation by neurotransmitters and neurohormones available, the overall goal of this thesis is to investigate the interactions between dopamine neurons and radial glial cells in the adult goldfish (Carassius auratus) forebrain. Immunocytochemistry and confocal imaging revealed a close anatomical relationship between dopamine neurons and radial glial cells along the ventricular surface in the telencephalon. Transcriptional regulation of brain aromatase by dopamine indicated a brain region-specific pattern and suggested the involvement of other regulators in the goldfish forebrain. A novel goldfish primary radial glial cell culture model was established and characterized for brain aromatase regulation studies. Pharmacological studies demonstrated that specific activation of dopamine D1 receptors up-regulates brain aromatase through a cAMP-dependent molecular mechanism, which can be enhanced or attenuated by the product of aromatase action, 17β-estradiol. Proteome profiling and the response following treatment with the specific dopamine D1 receptor agonist SKF 38393 revealed that proteins involved in cell proliferation and growth are regulated through small molecules- and transcription factors-mediated signaling pathways. Analysis of genes related to radial glial cell and dopamine neuron functions demonstrated that glial activation and dopamine neuron recovery are estrogen-dependent in a neurotoxin MPTP-induced goldfish model of Parkinson’s disease. This thesis illustrates novel molecular mechanisms underlying brain aromatase regulation as well as radial glial cell function regulation and provides a framework for future investigation of existing endocrine disruptors modulating neurosteroid levels in the teleost brain.
5

Intrathecal GDNF Gene Delivery Enhances Recovery from Neuropathic Pain in Rats

Wu, Ping-Ching 14 July 2003 (has links)
Neuronal cell death may be responsible for the pathogenesis of neuropathic pain. Glial cell line-derived neurotrophic factor (GDNF) protects sensory neurons after injury and offers a promising alternative for the management of intractable pain. However, continuous administration of trophic factors into the central nervous system is costly and difficult to maintain. Therefore, we evaluated the potential of intrathecal GDNF gene delivery for the treatment of neuropathic pain. Recombinant adenovirus encoding GDNF (Ad-GDNF) was characterized and shown to enhance viability of neuronal cultures. After intrathecal injection of Ad-GDNF, an elevated GDNF level was observed in spinal cord for four weeks. In rats with sciatic nerve axotomy,intrathecal injection of Ad-GDNF significantly ameliorated the duration of neuropathic pain. However, animals treated with Ad-GDNF developed hyperalgesia in the early stage of treatment. Immunofluorescence analysis indicated that intrathecal GDNF gene delivery prominently attenuated the neuronal loss due to nerve injury. Unexpectedly, varying degrees of hair loss was found in some rats receiving Ad-GDNF. Histological analysis revealed that hair loss resulted from severe degeneration of hair follicles in skin from Ad-GDNF-treated animals. In summary, the present study demonstrate the feasibility and limitations of GDNF gene delivery for the management of neuropathic pain.
6

Neuronal influences are necessary to produce mitochondrial co-localization with glutamate transporters in astrocytes.

Ugbode, Christopher I., Hirst, W.D., Rattray, Marcus 09 1900 (has links)
Yes / Abstract Recent evidence suggests that the predominant astrocyte glutamate transporter, GLT-1/ Excitatory Amino Acid Transporter 2 (EAAT2) is associated with mitochondria. We used primary cultures of mouse astrocytes to assess co-localization of GLT-1 with mitochondria, and tested whether the interaction was dependent on neurons, actin polymerization or the kinesin adaptor, TRAK2. Mouse primary astrocytes were transfected with constructs expressing V5-tagged GLT-1, pDsRed1-Mito with and without dominant negative TRAK2. Astrocytes were visualized using confocal microscopy and co-localization was quantified using Volocity software. Image analysis of confocal z-stacks revealed no co-localization between mitochondria and GLT-1 in pure astrocyte cultures. Co-culture of astrocytes with primary mouse cortical neurons revealed more mitochondria in processes and a positive correlation between mitochondria and GLT-1. This co-localization was not further enhanced after neuronal depolarization induced by 1 h treatment with 15 mM K+. In pure astrocytes, a rho kinase inhibitor, Y27632 caused the distribution of mitochondria to astrocyte processes without enhancing GLT-1/mitochondrial co-localization, however, in co-cultures, Y27632 abolished mitochondrial: GLT-1 co-localization. Disrupting potential mitochondrial: kinesin interactions using dominant negative TRAK2 did not alter GLT-1 distribution or GLT-1: mitochondrial co-localization. We conclude that the association between GLT-1 and mitochondria is modest, is driven by synaptic activity and dependent on polymerized actin filaments. Mitochondria have limited co-localization with the glutamate transporter GLT-1 in primary astrocytes in culture. Few mitochondria are in the fine processes where GLT-1 is abundant. It is necessary to culture astrocytes with neurones to drive a significant level of co-localization, but co-localization is not further altered by depolarization, manipulating sodium ion gradients or Na/K ATPase activity.
7

NIGROSTRIATAL DOPAMINE-NEURON FUNCTION FROM NEUROTROPHIC-LIKE PEPTIDE TREATMENT AND NEUROTROPHIC FACTOR DEPLETION

Littrell, Ofelia Meagan 01 January 2011 (has links)
Trophic factors have shown great promise in their potential to treat neurological disease. In particular, glial cell line-derived neurotrophic factor (GDNF) has been identified as a potent neurotrophic factor for midbrain dopamine (DA) neurons in the substantia nigra (SN), which lose function in Parkinson’s disease (PD). GDNF progressed to phase II clinical trials, which did not meet proposed endpoints. The large size and binding characteristics of GDNF have been suspected to contribute to some of the shortcomings of GDNF related to delivery to target brain regions. Smaller peptides derived from GDNF (Dopamine-Neuron Stimulating Peptides – DNSPs) have been recently investigated and appear to demonstrate trophic-like effects comparable to GDNF. In the described studies, a time course study was conducted to determine in vivo DA-release characteristics 1-, 2- and 4- weeks after peptide treatment. These studies determined the effects on DA terminals within striatal sub-regions using microelectrodes. A heterogeneous effect on striatal sub-regions was apparent with the maximum effect in the dorsal striatum – corresponding to terminals originating from the SN. Dysregulation of GDNF or GDNF signaling is believed to contribute to motor dysfunction in aging and PD. Thus, it is hypothesized that GDNF is necessary for the maintenance and function of neurons. To extend this line of investigation, in vivo functional measures (DA-release and -uptake) and behavioral and cellular alterations were investigated in a transgenic mouse model (Gdnf+/-) with reduced GDNF protein levels. The described studies determined that both DA-uptake and -release properties were altered in middle-aged Gdnf+/- mice with only modest reductions in DA neurochemical levels. GDNF levels in Gdnf+/- mice were restored to levels comparable to wild-type (WT) counterparts by treatment with GDNF. GDNF protein supplementation led to enhanced motor behavior and increased markers for DA neurons in the SN of Gdnf+/- mice. Gdnf+/- mice appeared to show a heightened sensitivity to GDNF treatment compared to WT counterparts. Overall, this body of work examines novel synthetic peptides with potential to enhance DA-neuron function and expands upon the current understanding of GDNF’s role in the nigrostriatal pathway.
8

Sex Differences in Adolescent Methylphenidate Sensitization: Effects on Glial Cell-Derived Neurotrophic Factor and Brain-Derived Neurotrophic Factor

Roeding, Ross L., Perna, Marla K., Cummins, Elizabeth D., Peterson, Daniel J., Palmatier, Matthew I., Brown, Russell W. 15 October 2014 (has links)
This study analyzed sex differences in methylphenidate (MPH) sensitization and corresponding changes in glial cell-derived neurotrophic factor (GDNF) and brain-derived neurotprhic factor protein (BDNF) in adolescent male and female rats. After habituation to a locomotor arena, animals were sensitized to MPH (5mg/kg) or saline from postnatal day (P) 33–49, tested every second day. On P50, one group of animals were injected with saline and behavior assessed for conditioned hyperactivity. Brain tissue was harvested on P51 and analyzed for GDNF protein. A second group of animals was also sensitized to MPH from P33 to 49, and expression of behavioral sensitization was analyzed on a challenge given at P60, and BDNF protein analyzed at P61. Females demonstrated more robust sensitization to MPH than males, but only females given MPH during sensitization demonstrated conditioned hyperactivity. Interestingly, MPH resulted in a significant increase in striatal and accumbal GDNF with no sex differences revealed. Results of the challenge revealed that females sensitized and challenged with MPH demonstrated increased activity compared to all other groups. Regarding BDNF, only males given MPH demonstrated an increase in dorsal striatum, whereas MPH increased accumbal BDNF with no sex differences revealed. A hierarchical regression analysis revealed that behavioral sensitization and the conditioned hyperactivity test were reliable predictors of striatal and accumbal GDNF, whereas sensitization and activity on the challenge were reliable predictors of accumbal BDNF, but had no relationship to striatal BDNF. These data have implications for the role of MPH in addiction and dopamine system plasticity.
9

Effects of glial cell line-derived neurotrophic factor (GDNF) on mouse fetal ventral mesencephalic tissue

Nevalainen, Nina January 2008 (has links)
<p>The symptoms of Parkinson's disease occur due to degeneration of dopamine neurons in substantia nigra. It has been demonstrated that glial cell line-derived neurotrophic factor (GDNF) is a potent neurotrophic factor when it comes to protect and enhance survival of dopamine neurons in animal models of Parkinson's disease. The aim of this study was to evaluate short- and long-term effects of GDNF on survival and nerve fiber outgrowth of dopamine cells and astrocytic migration in mouse fetal ventral mesencephalic (VM) tissue. Primary tissue cultures were made of mouse fetal VM tissue and evaluated at 7 and 21 days in vitro (DIV) in terms of dopaminergic nerve fiber outgrowth and astrocytic migration when developed with GDNF present, partially, or completely absent. The results revealed that VM tissue cultured in the absence of GDNF did not exhibit any significant differences in migration of astrocytes or dopaminergic nerve fiber outgrowth neither after 7 DIV nor after 21 DIV, when compared with tissue cultured with GDNF present. Migration of astrocytes and dopaminergic nerve fiber outgrowth reached longer distances when tissue was left to develop for 21 DIV in comparison with 7 DIV. In order to study the long-term effects of GDNF, mouse fetal dopaminergic tissue was transplanted into the ventricles of adult mice and evaluated after 6 months. No surviving dopamine neurons were present in the absence of GDNF. In contrast dopamine neurons developed with GDNF did survive, indicating that GDNF is an essential neurotrophic factor when it comes to long-term dopamine cell survival. More cases have to be assessed in the future in order to strengthen the findings. Thus, transplanted dopamine neurons will be assessed after 3 and 12 months in order to map out when dopamine neurons deprived of GDNF undergo degeneration.</p>
10

Chemical Transmission between Dorsal Root Ganglion Somata via Intervening Satellite Glial Cell

Kim, Hyunhee 04 December 2012 (has links)
The structure of afferent neurons is pseudounipolar. Studies suggest that they relay action potentials (APs) to both directions of the T-junctions to reach the cell body and the spinal cord. Moreover, the somata are electrically excitable and shown to be able to transmit the signals to associated satellite cells. Our study demonstrates that this transmission can go further and pass onto passive neighbouring somata, if they are in direct contact with same satellite cells. The neurons activate the satellite cells by releasing ATP. This triggers the satellite cells to exocytose acetylcholine to the neighbouring neurons. In addition, the ATP inhibits the nicotinic receptors of the neurons by activating P2Y receptors and initiating the G-protein-mediated pathway, thus reducing the signals that return to the neurons that initiated the signals. This “sandwich synapse” represents a unique pathway by the ectopic release between the somata and the satellite cells.

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