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Effect of umbilical cord matrix stem cells on Parkinson’s disease model ratsMedicetty, Satish January 1900 (has links)
Doctor of Philosophy / Department of Anatomy and Physiology / Mark L. Weiss / Umbilical cord matrix or Wharton’s Jelly is a mucous connective tissue ensheathing the cord blood vessels and contains mesenchymal-like stem cells. Previously, we have shown that pig umbilical cord matrix stem (pUCMS) cells transplanted into normal rat brain were recovered up to 6 weeks post-transplantation, where a sub-population of pUCMS cells exhibited neuronal morphology and expressed a variety of neuronal markers. Here, approximately 150 pUCMS cells were transplanted into non-immunesuppressed rats that previously received a brain lesion by neurotoxin, 6-hydroxydopamine (6-OHDA), which specifically affects midbrain dopaminergic neurons, leading to pathologic findings similar to that of Parkinson’s disease (PD). The pUCMS cells proliferated up to 8 weeks post-transplantation and there was a significant increase in the percentage and number of pUCMS cells expressing tyrosine hydroxylase (TH), which is a marker for dopaminergic cells. We conclude that 1. Xenotransplants of pig UCMS cells are not rejected by rats at least up to 8 weeks after transplantation and 2. The pig UCMS cells proliferate and differentiate after transplantation into PD model rats.
The surface antigen and gene expression profile of human umbilical cord matrix stem (hUCMS) cells resemble that of mesenchymal stem cells. Apomorphine-induced rotatory behavior was used to analyze the motor deficits of the PD model rats. In different experiments 1000, 2500 and 25000 hUCMS cells were transplanted into the brain of non-immunesuppressed PD model rats. There was a dose-dependent decrease in apomorphine-induced rotations; the maximum benefit was found in the rats that received 1000 hUCMS cells. The graft cells were recovered at 2 days and 1 week, but not at 6, 10 or 12 weeks post-transplantation. Quantitative assessment of host TH-positive midbrain dopaminergic neurons revealed a positive correlation between the behavioral improvement and TH-positive cell number in the low-density (1000 cells) transplant group, showing that the hUCMS cells may play a role in rescuing damaged host dopaminergic neurons and promote improvement of motor deficits in PD-model rats. In summary, hUCMS cells appear to be mesenchymal stem cells that can be harvested in great numbers from a non-controversial, inexhaustible source. Human UCMS cells show therapeutic benefit in PD model rats, but the mechanism by which they promote improvement is presently unknown.
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Inhibition of RVLM synaptic activation at peak hyperthermia reduces visceral sympathetic nerve dischargeHosking, Kimberley Gowens January 1900 (has links)
Master of Science / Department of Anatomy and Physiology / Michael J. Kenney / Hyperthermia is an environmental stressor that produces marked increases in visceral sympathetic nerve discharge (SND) in young rats. The brainstem in rats contains the essential neural circuitry for mediating visceral sympathetic activation; however, specific brainstem sites involved remain virtually unknown. The rostral ventral lateral medulla (RVLM) is a key central nervous system region involved in the maintenance of basal SND and in mediating sympathetic nerve responses evoked from supraspinal sites. In the present study we tested the hypothesis that inhibition of RVLM synaptic activation at peak hyperthermia (internal body temperature, Tc, increased to 41.5°C) would affect heating-induced visceral sympathetic activation. Experiments were completed in chloralose-urethane anesthetized, baroreceptor-intact and sinoaortic-denervated, 3-6 month-old Sprague-Dawley rats. Bilateral inhibition of RVLM synaptic activation produced by muscimol microinjections (400 and 800 pmol) at 41.5°C resulted in immediate and significant reductions in peak heating-induced renal and splenic sympathoexcitation. Interruption of RVLM synaptic activation and axonal transmission by lidocaine microinjections (40 nmol) at 41.5°C produced significant reductions in hyperthermia-induced sympathetic activation to similar levels produced by RVLM muscimol microinjections. The total amount of SND inhibited by RVLM muscimol and lidocaine microinjections was significantly more during hyperthermia (41.5°C) than normothermia (38°C). These findings demonstrate that maintenance of sympathetic activation at peak hyperthermia is dependent on the integrity of RVLM neural circuits.
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Novel peptide-based materials assemble into adhesive structures: circular dichroism, infrared spectroscopy, and transmission elect[r]on microscopy studiesWarner, Matthew D. January 1900 (has links)
Master of Science / Department of Biochemistry / John M. Tomich / Biologically based adhesives offer many industrial advantages over their chemically synthesized counterparts, not the least of which are reduced environmental impact and limited toxicity. They also represent a renewable resource. In addition, nanoscale biomaterials also show an incredibly large potential for biomedical uses, including possible drug delivery and novel wound bandaging, as well as tissue engineering. Understanding the adhesion mechanisms at work in peptide-based nanomaterials is key for producing viable industrial and clinical biomimetic
compounds. Our previous work has shown that small hydrophobic oligopeptide segments flanked by short tri-lysine sequences display adhesion strength that is dependent on the
formation of β-structure and large-scale association of monomers. In this study, three oligopeptides were synthesized based on putative amyloid fibril nucleation sites. Two of the
sequences originate from the Alzheimer’s beta amyloid peptide Aβ1-40, while the third sequence comes from a nucleation site for islet amyloid polypeptide (IAPP). These peptides show unusual
structural properties associated with adhesive ability. Furthermore, they represent a third category of requirements for β-structure formation. In addition, I report the first morphological
evidence for the previously predicted structural mechanism underlying our previous peptide based adhesives.
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Central activation of sympathetic neural circuits alters Splenic cytokine gene expressionGanta, Chanran Kumar January 1900 (has links)
Doctor of Philosophy / Department of Anatomy and Physiology / Michael J. Kenney / Important bidirectional interactions exist between the central nervous system and the
immune system. Neural-immune interactions provide a regulatory system in the body and
disturbances in these interactions may lead to disease. Although the sympathetic nervous system is thought to play a key role in mediating neural-immune interactions, central neural mechanisms
mediating sympathetic-immune interactions and the effect of centrally-induced alterations in sympathetic nerve discharge on immune function is not known. We tested the hypothesis that central activation of sympathetic neural circuits alters splenic cytokine gene expression. In a separate study, we tested the hypothesis that hypothermia-induced changes in visceral sympathetic nerve discharge (SND) would be attenuated in middle-aged and aged compared with young rats. Previous studies have demonstrated that skin sympathoexcitatory responses to skin cooling are attenuated in aged compared with young subjects, suggesting that advancing age influences sympathetic nerve responsiveness to cooling. The effect of age on sympathetic nerves innervating other targets organs during acute cooling remains unknown. Central activation of splenic SND was produced using three different experimental interventions: increased core body
temperature produced by acute heating, intracerebroventricular injection of angiotensin II (ANGII), and decreased core body temperature produced by acute cooling. Changes in gene expression profiles were analyzed using inflammatory cytokine-specific gene-array and further validated using real-time RT-PCR analysis. The following observations were made. 1)Splenic SNDincreased in response to each experimental intervention except in acute cooled young rats where there was a decrease in splenic SND. 2) Splenic cytokine gene expression of pro-inflammatory
cytokines (e.g., IL-1β, IL-6, IL-2) and chemokines (GRO1, CXCL2, CCCL2 and, CXCL10) was increased in response to each experimental intervention. 3) Expression of splenic cytokine genes was reduced after splenic-denervation except in acute cooled rats. 4) Progressive hypothermia reduced splenic, renal, and adrenal SND in rats and was generally attenuated in middle-aged and aged rats. These results demonstrate the functional significance of changes in sympathetic nerve activity on splenic immune cell activation and the effect of age on SND responses to core body cooling.
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Real-time PCR analysis of age-dependent alterations in the RVLM neurotransmitter gene expression profile of F344 ratsCraig, Robin Ann January 1900 (has links)
Doctor of Philosophy / Department of Anatomy and Physiology / Michael J. Kenney / It is well established that normal aging is associated with progressive increases in efferent sympathetic nerve discharge (SND). Type II diabetes, obesity, heart failure, and hypertension are pathologies that have been attributed to both the processes of aging and sympathetic dysfunction, exemplifying the importance of understanding central regulation of SND during aging. However, the central mechanisms mediating altered SND with advancing age remain unclear. The rostral ventral lateral medulla (RVLM) is a brainstem region critically involved in setting the basal level of sympathetic outflow and cardiovascular function. Indeed, the RVLM is the only presympathetic region that when bilaterally inactivated results in profound reductions in both SND and arterial pressure. Glutamatergic influences in RVLM activity are powerfully inhibited by tonic GABAergic neural inputs originating from the caudal ventral lateral medulla (CVLM); effects that are mediated by GABAA receptors located on presympathetic neuronal cell bodies within the RVLM. In the present study we proposed that reductions in GABA[subscript A] receptor subunit gene expression may reflect withdrawal of GABAergic tone in the RVLM thereby contributing to the basal sympathetic activation that occurs with advancing age. Therefore, the objective of the current study was to identify age-related changes in the constitutive expression of genes related to GABAergic and muscarinic, nicotinic and dopaminergic receptor systems due to their reported involvement in modulating GABA[subscript A] receptor function, in the RVLM of adult young (3-5 mo. old), middle-aged (12 mo. old), weight stable presenescent (24-25 mo. old) and senescent (>24 mo. old) Fischer 344 (F344) rats using a commercially available real-time PCR array. Real-time analysis revealed nonuniform and age-associated changes in the RVLM GABA, muscarinic, nicotinic and dopaminergic neurotransmitter gene expression profile between young and middle-aged F344 rats. Heterogeneous expression of genes related to these neurotransmitters was also observed between presenescent and senescent F344 rats. Our results suggest that potential changes in neurotransmitter synthesis and degradation, uptake, transport, signaling and receptor subunit composition may account for the sympathoexcitatory state that is commonly observed in the aged.
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Phenotypic characterisation of the tremor mutant and AAV mediated aspartoacylase gene transfer in the rat model of Canavan diseaseMcPhee, Scott William John January 2004 (has links)
The doctoral studies described in this thesis involve the phenotypic characterization of the tremor rat, an animal model of Canavan disease, and a proof of principle gene transfer study in this model. The phenotype of the tremor rat is examined at the genetic, molecular, cellular, neurochemical, physical and behavioural levels, and tremor mutants are described within the context of Canavan disease. Tremor mutants appear to share many phenotypes with both human patients and to the knock-out mouse model. The deletion of aspartoacylase results in a total loss of the capacity to metabolize N-acetyl-aspartate to acetate and aspartate in brain, leading to elevations in brain N-acetyl-aspartate levels, changes in cell and tissue morphology, and physical and behavioural deficits including mild akinesia and loss of normal motor coordination and balance. Parallel to this work was the development of a gene transfer approach to treat Canavan disease, involving Adeno-associated virus mediated delivery of aspartoacylase to the mammalian central nervous system. Gene transfer was undertaken in tremor rat mutants, and analysis was made of gene expression and function as well as the effect of aspartoacylase expression on improving the phenotypic deficits observed in mutant animals. Gene expression was observed at the RNA and protein level, with recombinant protein observed in cell soma and processes. Although not significant the data suggested a trend of decreased NAA levels after aspartoacylase transfer in comparison to animals injected with a vector encoding green fluorescent protein. Improvement was noted in the rotorod phenotype with mutant animals receiving aspartoacylase gene transfer performing better at tests of balance and coordinated locomotion than animals receiving a control vector. The study provided evidence that Adeno-associated virus mediated aspartoacylase gene transfer to the brain improves some of the deficits in tremor mutants, and supports the rationale of human gene transfer for Canavan disease. / Subscription resource available via Digital Dissertations only.
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Phenotypic characterisation of the tremor mutant and AAV mediated aspartoacylase gene transfer in the rat model of Canavan diseaseMcPhee, Scott William John January 2004 (has links)
The doctoral studies described in this thesis involve the phenotypic characterization of the tremor rat, an animal model of Canavan disease, and a proof of principle gene transfer study in this model. The phenotype of the tremor rat is examined at the genetic, molecular, cellular, neurochemical, physical and behavioural levels, and tremor mutants are described within the context of Canavan disease. Tremor mutants appear to share many phenotypes with both human patients and to the knock-out mouse model. The deletion of aspartoacylase results in a total loss of the capacity to metabolize N-acetyl-aspartate to acetate and aspartate in brain, leading to elevations in brain N-acetyl-aspartate levels, changes in cell and tissue morphology, and physical and behavioural deficits including mild akinesia and loss of normal motor coordination and balance. Parallel to this work was the development of a gene transfer approach to treat Canavan disease, involving Adeno-associated virus mediated delivery of aspartoacylase to the mammalian central nervous system. Gene transfer was undertaken in tremor rat mutants, and analysis was made of gene expression and function as well as the effect of aspartoacylase expression on improving the phenotypic deficits observed in mutant animals. Gene expression was observed at the RNA and protein level, with recombinant protein observed in cell soma and processes. Although not significant the data suggested a trend of decreased NAA levels after aspartoacylase transfer in comparison to animals injected with a vector encoding green fluorescent protein. Improvement was noted in the rotorod phenotype with mutant animals receiving aspartoacylase gene transfer performing better at tests of balance and coordinated locomotion than animals receiving a control vector. The study provided evidence that Adeno-associated virus mediated aspartoacylase gene transfer to the brain improves some of the deficits in tremor mutants, and supports the rationale of human gene transfer for Canavan disease. / Subscription resource available via Digital Dissertations only.
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Phenotypic characterisation of the tremor mutant and AAV mediated aspartoacylase gene transfer in the rat model of Canavan diseaseMcPhee, Scott William John January 2004 (has links)
The doctoral studies described in this thesis involve the phenotypic characterization of the tremor rat, an animal model of Canavan disease, and a proof of principle gene transfer study in this model. The phenotype of the tremor rat is examined at the genetic, molecular, cellular, neurochemical, physical and behavioural levels, and tremor mutants are described within the context of Canavan disease. Tremor mutants appear to share many phenotypes with both human patients and to the knock-out mouse model. The deletion of aspartoacylase results in a total loss of the capacity to metabolize N-acetyl-aspartate to acetate and aspartate in brain, leading to elevations in brain N-acetyl-aspartate levels, changes in cell and tissue morphology, and physical and behavioural deficits including mild akinesia and loss of normal motor coordination and balance. Parallel to this work was the development of a gene transfer approach to treat Canavan disease, involving Adeno-associated virus mediated delivery of aspartoacylase to the mammalian central nervous system. Gene transfer was undertaken in tremor rat mutants, and analysis was made of gene expression and function as well as the effect of aspartoacylase expression on improving the phenotypic deficits observed in mutant animals. Gene expression was observed at the RNA and protein level, with recombinant protein observed in cell soma and processes. Although not significant the data suggested a trend of decreased NAA levels after aspartoacylase transfer in comparison to animals injected with a vector encoding green fluorescent protein. Improvement was noted in the rotorod phenotype with mutant animals receiving aspartoacylase gene transfer performing better at tests of balance and coordinated locomotion than animals receiving a control vector. The study provided evidence that Adeno-associated virus mediated aspartoacylase gene transfer to the brain improves some of the deficits in tremor mutants, and supports the rationale of human gene transfer for Canavan disease. / Subscription resource available via Digital Dissertations only.
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Phenotypic characterisation of the tremor mutant and AAV mediated aspartoacylase gene transfer in the rat model of Canavan diseaseMcPhee, Scott William John January 2004 (has links)
The doctoral studies described in this thesis involve the phenotypic characterization of the tremor rat, an animal model of Canavan disease, and a proof of principle gene transfer study in this model. The phenotype of the tremor rat is examined at the genetic, molecular, cellular, neurochemical, physical and behavioural levels, and tremor mutants are described within the context of Canavan disease. Tremor mutants appear to share many phenotypes with both human patients and to the knock-out mouse model. The deletion of aspartoacylase results in a total loss of the capacity to metabolize N-acetyl-aspartate to acetate and aspartate in brain, leading to elevations in brain N-acetyl-aspartate levels, changes in cell and tissue morphology, and physical and behavioural deficits including mild akinesia and loss of normal motor coordination and balance. Parallel to this work was the development of a gene transfer approach to treat Canavan disease, involving Adeno-associated virus mediated delivery of aspartoacylase to the mammalian central nervous system. Gene transfer was undertaken in tremor rat mutants, and analysis was made of gene expression and function as well as the effect of aspartoacylase expression on improving the phenotypic deficits observed in mutant animals. Gene expression was observed at the RNA and protein level, with recombinant protein observed in cell soma and processes. Although not significant the data suggested a trend of decreased NAA levels after aspartoacylase transfer in comparison to animals injected with a vector encoding green fluorescent protein. Improvement was noted in the rotorod phenotype with mutant animals receiving aspartoacylase gene transfer performing better at tests of balance and coordinated locomotion than animals receiving a control vector. The study provided evidence that Adeno-associated virus mediated aspartoacylase gene transfer to the brain improves some of the deficits in tremor mutants, and supports the rationale of human gene transfer for Canavan disease. / Subscription resource available via Digital Dissertations only.
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Phenotypic characterisation of the tremor mutant and AAV mediated aspartoacylase gene transfer in the rat model of Canavan diseaseMcPhee, Scott William John January 2004 (has links)
The doctoral studies described in this thesis involve the phenotypic characterization of the tremor rat, an animal model of Canavan disease, and a proof of principle gene transfer study in this model. The phenotype of the tremor rat is examined at the genetic, molecular, cellular, neurochemical, physical and behavioural levels, and tremor mutants are described within the context of Canavan disease. Tremor mutants appear to share many phenotypes with both human patients and to the knock-out mouse model. The deletion of aspartoacylase results in a total loss of the capacity to metabolize N-acetyl-aspartate to acetate and aspartate in brain, leading to elevations in brain N-acetyl-aspartate levels, changes in cell and tissue morphology, and physical and behavioural deficits including mild akinesia and loss of normal motor coordination and balance. Parallel to this work was the development of a gene transfer approach to treat Canavan disease, involving Adeno-associated virus mediated delivery of aspartoacylase to the mammalian central nervous system. Gene transfer was undertaken in tremor rat mutants, and analysis was made of gene expression and function as well as the effect of aspartoacylase expression on improving the phenotypic deficits observed in mutant animals. Gene expression was observed at the RNA and protein level, with recombinant protein observed in cell soma and processes. Although not significant the data suggested a trend of decreased NAA levels after aspartoacylase transfer in comparison to animals injected with a vector encoding green fluorescent protein. Improvement was noted in the rotorod phenotype with mutant animals receiving aspartoacylase gene transfer performing better at tests of balance and coordinated locomotion than animals receiving a control vector. The study provided evidence that Adeno-associated virus mediated aspartoacylase gene transfer to the brain improves some of the deficits in tremor mutants, and supports the rationale of human gene transfer for Canavan disease. / Subscription resource available via Digital Dissertations only.
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