Anatomy and Neuroscience - Theses
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ItemEarly neuronal and glial cell changes in diabetic retinopathy(University of Melbourne, 2010)
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ItemModulation of the intermediate-conductance calcium-activated potassium (IKca) channel by protein kinase a (PKA)(University of Melbourne, 2010)
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ItemNeural plasticity and gene-environment interactions in the PLC-?1 knockout mouse(University of Melbourne, 2007)
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ItemFlamingo/Starry Night in embryonic abdominal sensory axon development of Drosophila( 2008)The seven-pass transmembrane atypical cadherin, Flamingo (also known as Starry Night) is evolutionally conserved in both structure and function in vertebrates and invertebrates. It plays important roles during the establishment of planar cell polarity (PCP) of epithelial tissues and during the development of axons and dendrites in both peripheral and central neurons. This thesis looks at the role of Flamingo/Starry Night in axon growth and guidance in the embryonic abdominal peripheral nervous system (PNS) of Drosophila. It describes the expression pattern of Flamingo in the PNS and its environment. A combination of single cell labelling and immunohistochemical techniques was used to define the effect of mutations in flamingo as well as several genes coding for potential Flamingo interaction partners. Rescue- and over-/mis-expression experiments featuring targeted expression of either a wild type version or mutant versions of flamingo provide information on the cellular and molecular mechanisms by which Flamingo regulates sensory axon development. Loss of Flamingo function results in a highly penetrant axon stall phenotype. Both sensory and motor axons frequently halt their advance early along their normal trajectories. Flamingo appears to mediate an axon growth promoting signal upon contact of sensory growth cones with specific early intermediate targets. Expression of Flamingo in sensory neurons is sufficient to rescue the mutant sensory axon phenotype. This rescue is at least partially independent of most of the extracellular region of the Flamingo protein. While Flamingo was previously found to have homophilic adhesion properties in vitro and appears to function by a homophilic mechanism during the neurite development of several types of neurons, this study supports a heterophilic signalling mechanism by which Flamingo fulfils its role in abdominal sensory axon growth promotion.
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ItemEnteric serotonin interneurons: connections and role in intestinal movement( 2008)5-HT powerfully affects gastrointestinal function. However, the study of these effects is complicated because 5-HT from both mucosa and a subset of enteric neurons acts on multiple receptor subtypes in enteric tissues. The role of neural 5-HT has been difficult to isolate with current techniques. This thesis aimed to elucidate the role of 5-HT neurons in motility using anatomical and functional methods. In Chapter 2, confocal microscopy was used to examine over 95% of myenteric neurons in guinea pig jejunum, categorized neurochemically, to identify neurons that received anatomically-defined input from 5-HT interneurons. The data showed that cholinergic secretomotor neurons were strongly targeted by 5-HT interneurons. In another key finding, excitatory motor neurons were surrounded by 5-HT terminals; this could provide an anatomical substrate for the descending excitation reflex. Subgroups of ascending interneurons and neurons with immunoreactivity for NOS, were also targeted by 5-HT interneurons. Thus, subtypes of these neurons might act in separate reflex pathways. Despite strong physiological evidence for 5-HT inputs to AH/Dogiel type II neurons, few contacts were identified. In Chapter 3, the confocal microscopy survey was extended to the three other interneuron classes (VIP/NOS and SOM descending interneurons; calretinin ascending interneurons) of guinea pig small intestine. A high degree of convergence between the otherwise polarized ascending and descending interneuron pathways was identified.
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ItemCloning and characterisation of gripe: a novel interacting partner of e12 during brain development( 2002-10)The mammalian cerebral cortex is a remarkable product of brain evolution, and is the structure that most distinctively delineates the human species from others (Northcutt and Kaas, 1995; Rakic, 1988). Neurons in the adult brain are organised into cytoarchitectonic areas, defined by distinct biochemical, morphological and physiological characteristics (Rakic 1988). Remarkably, this complex structure is generated from a simple neuroepithelium. What are the signalling mechanisms that direct neuron formation and subsequent functional-parcellation of the cerebral cortex? Key to the study of this process is an understanding of neuronal fate determination. Available evidence demonstrates an intrinsic programming potential by neuronal progenitors within subdomains of the developing cerebral cortex that is instructive for proper corticogenesis. These regional domains are demarcated by expression of certain transcription factors, including members of the Helix-Loop-Helix (HLH) family of proteins. The HLH family of transcription factors are key contributors to a wide array of developmental processes, including neurogenesis and haematopoiesis. These factors are thought to exert their regulatory influences by binding to cognate promoter-DNA sequences as dimers. While studies in mice have convincingly demonstrated that neurogenic HLH proteins such as NeuroD (Lee et al., 1995; Miyata et al., 1999; Liu et al., 2000) and Mash1 (Casarosa et al., 1999) are intimately involved in neuronal fate determination and terminal differentiation, the role of the ubiquitously expressed HLH protein, E12, in mammalian neurogenesis remains ambiguous. Originally discovered as an important regulator of lymphopoiesis, expression studies revealed its widespread expression in proliferative zones of multiple nascent organs of the embryo, including the developing cerebral cortex; implying a role for E12 in development of the nervous system. Since the function of E12 is, in part, coded by its capacity for protein dimerisation, a search was undertaken for binding partners in developing mouse brain, and using a yeast 2-hybrid assay. Yeast 2-hybrid prey libraries were constructed using complementary DNA (cDNA) isolated from embryonic mouse forebrain tissue at early (embryonic day e11.5) and peak (e15.5) stages of neurogenesis. Screening of these libraries for binding partners to an E12 bait resulted in cloning of HLH factors, such as Mash1, NSCL and Id2. Importantly, a novel binding partner, named GRIPE, was cloned as a novel GAP Related Interacting Protein to E12. GRIPE binds to the HLH region of E12, and may require E12 for nuclear import. Furthermore, GRIPE may negatively regulate E12-dependent target gene transcription. High levels of GRIPE and E12 mRNA were coincidently detected during embryogenesis, but only GRIPE mRNA levels remained high in adult brain, particularly in neurons of the cortex and hippocampus. These observations were reconfirmed through an in vitro model of neurogenesis. Taken together, these results indicate that GRIPE is a novel protein whose dimerisation with E12 has important consequences for cells undergoing neuronal differentiation. A model is proposed to suggest how neurogenic HLH proteins that dimerise to E12 may promote signalling cascades driving early neuroblast differentiation.
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ItemA morphological characterisation of central neural pathways to the kidney( 2005-04)This study was undertaken to locate and characterise the neurons in the central nervous system that project to the kidney. In particular, the aim was to illustrate and characterise the neural link between regions in the hypothalamus known to influence renal function and fluid balance, and nerves known to innervate the kidney.
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ItemProthymosin alpha, a gene differentially expressed in CD34+ cells( 2004)Haemopoietic stem and progenitor cells from bone marrow and cord blood are well characterised with respect to their phenotype, growth in clonal assays, responsiveness to cytokine stimulation, receptor profile and their ability to sustain multilineage engraftment of receptive hosts in animal models of transplantation and of course, clinically in the treatment of some haemopoietic and immunological disorders. It is generally accepted that cells bearing the CD34+ phenotype are enriched for the most primitive of haemopoietic stem cells that possess the cardinal features of self-renewal and multipotency. However, the molecular mechanisms, the spectrum of expressed genes that give rise to the physical characteristics of haemopoietic progenitor cells are not well understood. Furthermore, although CD34+ cells from different sources (bone marrow, cord blood, mobilised peripheral blood) share many common features, there are also significant differences. (For complete abstract open document)
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ItemRelaxin-3 systems in brain: effects on feeding, anxiety, depression and addiction( 2012)The neuropeptide, relaxin-3 (RLN3), and its major endogenous receptor, RXFP3 (relaxin family peptide receptor 3), have been postulated to modulate feeding, anxiety- and depressive-like behaviour, and reward based on neuroanatomical and neurochemical data. The major aim of the research described in this thesis, therefore, was to determine the effect of centrally administered RXFP3-selective peptides on these functions in the adult rat. Intracerebroventricular (icv) administration of the RXFP3-selective agonist peptides, R3/I5 and RXFP3-A2, and native rat/mouse relaxin-3 (rmRLN3) significantly increased acute food intake in male Sprague-Dawley rats, and this effect was prevented by prior icv injection of the RXFP3-selective antagonist peptides, RXFP3-A3 and R3(B1-22)R. Icv injection of RXFP3-A2 decreased anxiety-like behaviour in male Sprague-Dawley rats in a range of behavioural tests, including the light-dark box and elevated plus maze, and produced antidepressant-like effects in the repeat forced swim test, but notably only in rats that had previously been tested in anxiety-like paradigms. Icv injection of RXFP3-selective agonists had no significant effect on general activity assessed quantitatively in automated locomotor cells. Icv administration of an RXFP3 antagonist (R3(B1-22)R) decreased alcohol but not sucrose self-administration in male inbred alcohol-preferring (iP) rats in a dose-related manner, and decreased cue-induced reinstatement (a model of relapse) for alcohol but not sucrose, suggesting a possible role for relaxin-3/RXFP3 signalling in alcohol-seeking. In addition, endogenous relaxin-3 mRNA expression in the hindbrain nucleus incertus correlated with daily alcohol and sucrose intake in the two-bottle choice paradigm, suggesting a role for endogenous relaxin-3 in modulating intake of ‘rewarding’ substances. Overall, the results from this research suggest that the endogenous relaxin-3/RXFP3 system promotes ‘motivated’ or ‘goal-seeking’ aspects of behaviour. These studies contribute to a deeper understanding of the neurobiology underlying clinical disorders such as obesity, anxiety, depression and addiction, which may in turn lead to novel diagnostics and therapeutic approaches. These important findings are therefore predicted to have a significant impact within the fields of neuropeptide biology and behavioural neuroscience, and are associated with several published or submitted scientific journal articles and reviews. In addition, the data have helped stimulate interest in this research area, with several major pharmaceutical companies expressing interest in the relaxin-3/RXFP3 system as a possible target for the development of therapeutic treatments for individual and co-morbid psychiatric and metabolic disorders.