Anatomy and Neuroscience - Theses

Permanent URI for this collection

Search Results

Now showing 1 - 6 of 6
  • Item
    Thumbnail Image
    Development of in vitro and in vivo models for the study of myelin plasticity
    Bujalka, Helena ( 2019)
    The central nervous system (CNS) constantly responds to changes in environmental stimuli by undergoing structural and functional modifications. Some stimuli induce persistent CNS changes which in turn underpin adaptive behaviours that enable individual animals to function in their unique environmental circumstances. This phenomenon, referred to as neuroplasticity, has been studied predominantly with respect to adaptive neuronal changes, and has focused primarily on synaptic changes and the molecular transduction mechanisms that mediate them. It is increasingly recognised, however, that glial cells can also be modified by external stimuli. Oligodendrocytes – the myelinating glia of the CNS which facilitate efficient nerve impulse conduction and support axonal metabolism – have also been demonstrated to undergo long term changes in response to environmental stimuli. Experience-dependent changes in oligodendrocyte number or myelination could underpin adaptive behaviours via modifications to neuronal metabolism and nerve impulse conduction. The emerging consensus is that stimulation – whether indirectly through modulating sensory, motor, or social experience, or directly through modulating neuronal activity – increases oligodendroglial lineage progression and myelin production. It has further been demonstrated that myelin plasticity is an axon-specific phenomenon whereby, when given the choice, myelin segments preferentially form on axons that are more highly active relative to those that are nearby but less active. The molecular mechanisms that mediate myelin plasticity are not well understood, and studies addressing this question have predominantly focused on the role of extracellular, pro-myelinating signals released by neurons in an activity-dependent manner. Comparatively little is known about the oligodendroglial intrinsic molecular transduction mechanisms that mediate myelin plasticity. This thesis aimed to develop a model system for studying myelin plasticity, including in particular to investigate the molecular transduction mechanisms that are triggered within oligodendroglia to mediate myelin plasticity. In developing such a model, two approaches were employed. First, an in vitro myelinating co-culture model was developed. A standard co-culture protocol was adopted and refined to produce robustly myelinating co-cultures of dorsal root ganglion (DRG) neurons and oligodendrocyte precursor cells (OPCs). To stimulate neuronal activity, both the hM3Dq pharmacogenetic and the channelrhodopsin-2 (ChR2) optogenetic techniques were explored. The pharmacogenetic stimulation technique was ineffective at driving DRG neurons to the levels of activity reportedly required for inducing myelin plasticity. In contrast, the optogenetic stimulation technique reliably drove DRG neurons to fire at the required frequency. Contrary to expectations, optogenetic stimulation did not increase myelin production in co-cultures, nor did it increase the propensity of myelin segments to preferentially form on optogenetically stimulated relative to control axons. The reasons for this are unclear, but are unlikely to be related to phototoxicity and are more likely to be explained by a negative effect of high ChR2 expression on myelination in these co-cultures. Second, an in vivo pharmacogenetic model was employed to drive activity of cortical neurons in juvenile hM3Dq transgenic mice. Contrary to expectations, there was no evidence for an activity-dependent increase in oligodendroglial lineage progression. The reasons for this are unclear, however they could relate to the young age of the animals in this relative to other studies of myelin plasticity or to the large population of neurons undergoing activity manipulation in this relative to other studies of myelin plasticity. The implications for glial plasticity, and for how it is studied, are discussed.
  • Item
    Thumbnail Image
    Using induced pluripotent stem cells to model primary open-angle glaucoma
    Daniszewski, Maciej Stanislaw ( 2019)
    Glaucoma is a group of optic neuropathies that may be characterized by gradual degeneration of retinal ganglion cells (RGCs) and their axons leading to irreversible vision loss [1, 2]. Glaucoma is the second leading cause of blindness worldwide [3-5] and it is estimated that the number of people affected by the disease will reach 80 million by 2020, while more than 11 millions will be bilaterally blind [6]. In this project I focus on primary open-angle glaucoma (POAG), as it accounts for the majority of glaucoma cases worldwide. So far, multiple risk factors for glaucoma have been identified; however, the exact mechanism causing RGC loss in patients remains elusive. Furthermore, examination of RGCs affected in POAG is difficult pre-mortem due to their anatomical location. To overcome this problem, somatic cells can be reprogrammed into patient-specific induced pluripotent stem cells (iPSCs), which can be then differentiated into cell type of interest, i.e. RGCs. This PhD project consisted of several steps. First, I assessed the feasibility of transferring the iPSC culture into the automated platform. Using automation was essential to generate large number of samples required for analysis. The transition to automation was successful, as evidenced by maintenance of iPSC morphology, expression of pluripotency markers and ability to differentiate into derivatives of three germ layers. I also demonstrated that incorporating automation into human (h) iPSC culture allows standardization of maintenance and passaging procedures reducing inter-sample variability and human error. I subsequently used the platform to generate over 300 hiPSC lines for POAG modelling. In parallel, I optimized RGC differentiation protocol to obtain sufficient number of cells for their examination with single cell RNA sequencing (scRNA-seq). Next, iPSC-derived RGCs were subjected to scRNA-seq to gain in-depth information about transcriptomic differences between healthy controls and POAG patients. Understanding mechanisms underlying RGC function, maintenance of homeostasis and those conferring susceptibility to POAG is crucial to discover new therapeutic targets and commence the process of drug discovery.
  • Item
    Thumbnail Image
    TAM signalling in CNS demyelination and multiple sclerosis
    MA, ZHI-MING ( 2015)
    Multiple sclerosis (MS) is an immune-mediated demyelinating disease of the central nervous system (CNS). Involvement of the immune system in the pathogenesis of MS is a key feature of the disease, and an understanding of the mechanisms underlying how immune responses are shaped during CNS demyelination will provide insight into the development of new therapeutic strategies. The TAM (Tyro3, Axl, Mertk) family of receptor tyrosine kinases and their ligands Growth Arrest-Specific 6 (Gas6) and Protein S (ProS) have been shown to modulate many immunological processes important during central demyelination. The major aim of this thesis is to provide further insight into TAM biology in the context of both an animal model of inflammatory demyelination and human MS. By conducting a study examining MS patients and common genetic variations within TAM genes, I identified the MERTK gene as a novel MS susceptibility gene. Examination of plasma from MS patients revealed that levels of the TAM ligand PROS are decreased in MS and that low PROS levels are associated with increased MS disease severity. To interrogate the role of TAM signalling in modulating disease severity during inflammatory demyelination, I used the experimental autoimmune encephalomyelitis (EAE) animal model and observed major changes in TAM gene expression within the CNS and peripheral immune cells during EAE. Examination of Gas6-/- mice during EAE showed that absence of the TAM receptor ligand Gas6 results in both attenuated microglial/macrophage responses and disease severity during the effector phase of EAE. Conditional deletion of Mertk from dendritic cells (DC) resulted in worse disease during the effector phase of EAE. Stratification by sex revealed sexual dimorphism in TAM gene expression and also in the outcome of EAE in both Gas6-/- mice and mice with DC-specific deletion of Mertk. In summary, the data presented in this thesis suggest that the TAM family plays key roles in MS susceptibility and modulating innate immune responses during inflammatory demyelination, providing evidence for members of the TAM family as either markers of disease severity and/or therapeutic targets for the treatment of MS.
  • Item
    Thumbnail Image
    Investigation of the mechanisms BDNF utilises to promote central nervous system myelination
    Ferner, Anita Hilja ( 2014)
    Brain-derived neurotrophic factor (BDNF) promotes CNS myelination, which is crucial for normal CNS function. This thesis investigates the influence BDNF and its signalling exerts upon myelination. Surprisingly, I found that conditional deletion of TrkB in oligodendroglia exerted no effect on myelination in vivo. However, over-expression of Erk2, a molecule activated by BDNF signalling, promotes myelination in vitro. I found that Erk1/2 interacts with and phosphorylates the oligodendroglial transcription factors Olig1 and Olig2, which may contribute to Erk1/2’s promyelinating effects.
  • Item
    Thumbnail Image
    Sodium channels and epilepsy: neuronal dysfunction in genetic mouse models
    LEAW, BRYAN ( 2014)
    Mutations in sodium channels have long been linked to inherited epilepsies. Recent clinical findings identified patients with Dravet syndrome that were homozygous for a mutation in SCN1B which encodes the β1 auxiliary subunit of sodium channels. Dravet syndrome is a severe childhood epileptic encephalopathy, and patients commonly present with frequent seizures, developmental regression, ataxia with associated gait abnormalities, and shorter lifespans. We have engineered a mouse model based on the human C121W epilepsy mutation (β1-C121W). Mice homozygous for this C121W mutation displayed similar deficits in health and motor skills to Dravet syndrome. Our experiments showed that β1-C121W homozygous neurons fired more action potentials per current injection, had significantly higher membrane resistance, and were more prone to demonstrate a bursting subtype. These hallmarks of neuronal excitability may contribute to the increased sensitivity to thermal seizures in the homozygous mice. Neuron morphology analysis also revealed that neurons within the subiculum of these animals were significantly smaller in size, consistent with the observed increased input resistance. Application of a new anti-epileptic drug, retigabine, successfully reversed the input resistance in homozygous animals down to wildtype levels, and dampened neuronal excitability. Retigabine injected intraperitoneally into homozygous mice was extremely efficient at reducing thermal seizure susceptibility. These findings highlight the potential utility of applying disease-mechanism based strategies to aid anti-epileptic therapy. In order to examine network excitability in another genetic model of epilepsy, the function of the Nav1.2 sodium channel alpha subunit during development was studied. The NaV1.2 gene has two developmentally regulated splice variants; the ‘neonatal’ and ‘adult’ isoforms. A mutation discovered in patients with benign familial neonatal-infantile epilepsy (BFNIE) increases the excitability of the ‘neonatal’ isoform such that it resembles the adult isoform. Moreover, previous work from the current laboratory using human NaV1.2 expressed in HEK293 cells showed that the ‘neonatal’ form is less excitable than the ‘adult’ form. Based on these data and because the proportion of the neonatal Nav1.2 mRNAs gradually decreases with age during development we hypothesize that the ‘neonatal’ NaV1.2 isoform reduces neuronal excitability in infant brain and therefore plays a protective physiological role. To test this the current laboratory engineered a mouse line which continuously expresses the adult form of Nav1.2 from birth (NaV1.2adult) and investigated seizure susceptibility and neuronal phenotypes. Homozygous NaV1.2adult mice were of normal size and had no obvious seizures under observation during routine video analysis. However, NaV1.2adult mice had increased susceptibility to PTZ-induced seizures, suggesting that the neonatal isoform of NaV1.2 may confer an a novel form of seizure protection. Pyramidal neurons recorded from cortical layers 2/3 of postnatal day 3 (P3) Nav1.2adult neonates show heightened excitability reflected by the presence of a fast-firing neuronal population, which was not seen in the wild-type. At P15, the differences between Nav1.2adult and wildtype at a single neuron level were no longer evident. Interestingly, we also identified an increase in the amplitude of miniature inhibitory post synaptic currents in Nav1.2adult mice compared to the wildtype mice. These results suggest that inherent changes in the neuronal networks occur as a consequence of continuous expression of the adult isoform of NaV1.2 during development. Although further investigation is required to fully understand the biological roles of the two NaV1.2 isoforms, it is predicted that the neonatal isoform of NaV1.2 confers seizure protection in the NaV1.2 mouse model of BFNIE.
  • Item
    Thumbnail Image
    The effects of stress on the onset and progression of Huntington's disease in a transgenic mouse model
    MO, CHRISTINA ( 2014)
    Huntington’s disease (HD) is a neurodegenerative disorder largely governed by genetics. The cause of the disease is a fully penetrant gene mutation, inherited by autosomal dominant transmission. The length of this mutation also predicts the age of disease onset, which can range from childhood to late adulthood. Work from our lab on the R6/1 transgenic mouse model of HD was the first to show that environmental factors can alter symptom progression. Environmental enrichment and voluntary wheel running delayed or ameliorated the triad of motor, affective and cognitive dysfunctions in HD mice. Recent clinical studies also suggest that lifestyle factors can affect the age of onset. Currently, there are no treatments to slow or change the course of HD so environmental interventions may offer a feasible approach to extend the symptom-free years in HD gene-positive individuals. There is evidence to suggest that the stress response is abnormal in HD mice and patients. The present study is the first to investigate the impact of stressors on the onset and progression in an animal model of HD. We used an acute (Chapter 3) and two chronic stress paradigms (Chapters 4 and 6) to assess the impact on characteristic symptoms of HD. We also extended the phenotyping of R6/1 HD mice to include behaviours of ethological relevance (Chapter 5). All 3 stress protocols were able modify various functions in R6/1 HD mice, notably accelerating cognitive decline and further impairing olfactory deficits. This work contributes data for sex differences in the HD phenotype and to the general stress literature. Importantly, we show that stress is not only able to modulate specific behaviours in HD mice, but that the gene mutation may confer a susceptibility to the negative effects of stress. Therefore, behavioural management therapy in combination with other lifestyle changes may help manage the course of the disease in gene positive individuals.