510 research outputs found

    Investigation of inflammatory and oxidative stress mechanisms in the disruption of white matter structure and function following chronic cerebral hypoperfusion

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    Vascular cognitive impairment (VCI) describes a heterogeneous condition caused by cerebrovascular disease and disturbances in cerebral blood flow delivery. It is the second leading form of dementia and vascular factors such as hypertension, diabetes and obesity are associated with an increased risk of developing VCI. White matter alterations are a prominent pathological feature observed in patients with VCI thought to underlie cognitive impairment. Neuroimaging studies show a positive correlation between the burden of white matter alterations and progressive cognitive impairment. Similarly associated both with white matter alterations and cognitive impairment is chronic cerebral hypoperfusion, sustained subtle reductions in cerebral blood flow. Cerebral hypoperfusion is observed before the onset of cognitive decline in humans and reducing cerebral blood flow in animal models replicates important aspects of VCI, suggesting hypoperfusion is an early driver of white matter disruption and VCI. Human neuropathology and preclinical animal models of chronic cerebral hypoperfusion studies have repeatedly identified increased inflammation and oxidative stress. This led to the hypothesis for this thesis; that inflammation and oxidative stress are key drivers of structural and functional white matter disruption when cerebral blood flow is reduced. The studies reported in this thesis were developed to investigate mechanisms involving inflammation and oxidative stress that can inform future treatments aimed at preventing the disruption of white matter and cognitive impairment in VCI. One such mechanism is the Nrf2 (Nuclear factor erythroid 2-related factor 2) signalling pathway. Nrf2 is a transcription factor that acts to detect and resolve inflammation and oxidative stress via induction of over 200 antioxidant and anti-inflammatory genes. Studies have shown that modulation of Nrf2 alters levels of inflammation and oxidative stress which impact on disease progression in models of Alzheimer’s disease, Parkinson’s disease and multiple sclerosis. To date, no one has investigated the direct role of Nrf2 in cerebral hypoperfusion-induced white matter disruption. While Nrf2 represents a promising network approach, another targeted mechanism of interest is microglial proliferation. Many neurodegenerative diseases including human VCI demonstrate increases in microglia, a sign of chronic neuroinflammation thought to be detrimental to cells, tissues and synapses. Work by our group has found an association between increasing numbers of microglia and the progressive disruption of white matter structure and function when cerebral blood flow is reduced in a mouse model, however, whether this is cause or consequence has yet to be determined. The first study of this thesis aimed to test the hypothesis that deficiency of Nrf2 exacerbates white matter pathology and cognitive decline when cerebral blood flow is reduced. Using wild type and Nrf2 knockout mice the study investigated cortical perfusion, white matter disruption and gliosis, cognitive impairment and white matter gene changes following sham or surgically-induced cerebral hypoperfusion (bilateral carotid artery stenosis). There were no differences in the severity of blood flow reductions between genotypes initially, however, wild type mice displayed improved recovery compared to Nrf2 deficient mice. Hypoperfusion induced white matter disruption and microgliosis in the corpus callosum and the optic tract in both genotypes, exacerbated by the absence of Nrf2. Further, hypoperfusion induced white matter astrogliosis and upregulated pro-inflammatory gene signalling in the optic tract and induced an impairment in spatial working memory. However, these measures were not affected by Nrf2 deficiency. The results demonstrate that the absence of Nrf2 exacerbates white matter pathology and microgliosis following cerebral hypoperfusion but does not impact on functional outcome. The second study aimed to test the hypothesis that enhancing astrocytic Nrf2- signalling preserves white matter structure and cognitive decline when cerebral blood flow is reduced. Astrocytes have larger antioxidant capacity than other cell types in the brain and overexpressing Nrf2 in astrocytes is associated with reduced white matter damage in a model of multiple sclerosis, as well as improved outcome in models of Parkinson’s and Huntington’s disease. Similar to the first study, wild type mice and mice overexpressing Nrf2 in astrocytes (GFAP-Nrf2) were subjected to bilateral carotid artery stenosis and cortical perfusion, white matter disruption and gliosis, cognitive impairment and white matter gene changes were assessed. There were no differences in the severity of blood flow reductions between genotypes. Akin to the first study, hypoperfusion induced white matter disruption, micro- and astrogliosis and pro-inflammatory gene signalling in the optic tract. The majority of these alterations were ameliorated in GFAP-Nrf2 mice. In addition, the impairment in spatial working memory induced by cerebral hypoperfusion was modestly improved in GFAP-Nrf2 mice compared to wild type controls. These findings support the hypothesis that astrocytic Nrf2 preserves white matter structure and function following cerebral hypoperfusion. The first two studies identified structural and functional consequences of altered inflammation mediated via alterations in Nrf2 signalling. To thoroughly investigate the Nrf2 signalling pathway following cerebral hypoperfusion the next step would ideally have been to study microglial Nrf2, however due to the lack of a suitable animal model, the third and final study instead aimed to test the hypothesis that microglial colony-stimulating factor 1 receptor (CSF1R) signalling is a driver of white matter disruption and cognitive decline when cerebral blood flow is reduced. Wild type mice treated with a pharmacological inhibitor of CSF1R (GW2580) or vehicle control, as an oral gavage or in diet, were studied by a similar experimental protocol as the first two studies. There were no differences in the severity of cerebral hypoperfusion between GW2580- or vehicle-treated animals either at one or six weeks following bilateral carotid artery stenosis. One week of GW2580 treatment was shown to modulate microglial proliferation and pro-inflammatory signalling in white matter. Remarkably, treatment with GW2580 for six weeks completely rescued impairments in spatial learning, protected against white matter disruption and prevented increased both white matter micro- and astrogliosis compared to wild type controls. These results suggest that CSF1R signalling in microglia is an important driver of the pathophysiological mechanisms that lead to white matter disruption and cognitive impairment when cerebral blood flow is reduced, and importantly, that targeted inhibition of this improves functional outcome. In conclusion, the work described in this thesis provides evidence of the contribution of inflammation and oxidative stress to the disruption and functional impairment of cerebral white matter. The results indicate that these mechanisms are amenable to alteration, and that direct microglial inflammatory mechanisms play an important role in the pathogenesis of white matter disruption and cognitive decline. The results demonstrate that targeted inhibition of CSF1R signalling in microglia and increased astrocytic Nrf2 expression leads to improved structural and functional outcome and as such represent a basis for potential treatment which warrants further investigation

    JCB887777 Supplementary material - Supplemental material for The mitochondrial calcium uniporter is crucial for the generation of fast cortical network rhythms

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    Supplemental material, JCB887777 Supplementary material for The mitochondrial calcium uniporter is crucial for the generation of fast cortical network rhythms by Carlos Bas-Orth, Justus Schneider, Andrea Lewen, Jamie McQueen, Kerstin Hasenpusch-Theil, Thomas Theil, Giles E Hardingham, Hilmar Bading and Oliver Kann in Journal of Cerebral Blood Flow & Metabolism</p

    Control of anti-apoptotic and antioxidant pathways in neural cells

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    Oxidative stress is a feature of many chronic neurodegenerative diseases as well as a contributing factor in acute disorders including stroke. Fork head class of transcription factors (Foxos) play a key role in promoting oxidative stress-induced apoptosis in neurons through the upregulation of a number of pro-apoptotic genes. Here I demonstrate that synaptic NMDA receptor activity not only promotes Foxos nuclear exclusion but also suppresses the expression of Foxo1 in a PI3K-dependent fashion. I also found that Foxo1 is in fact, a Foxo target gene and that it is subject to a feed-forward inhibition by synaptic activity, which is thought to result in longerterm suppression of Foxo downstream gene expression than previously thought. The nuclear factor (erythroid 2-related) factor 2 (Nrf2) is another transcription factor involved in oxidative stress and the key regulator of many genes, whose products form important intrinsic antioxidant systems. In the CNS, artificial activation of Nrf2 in astrocytes has been shown to protect nearby neurons from oxidative insults. However, the extent to which Nrf2 in astrocytes could respond to endogenous signals such as mild oxidative stress is less clear. The data presented herein, demonstrate for the first time that endogenous Nrf2 could be activated by mild oxidative stress and that this activation is restricted to astrocytes. Contrary to the established dogma, I found that mild oxidative stress induces the astrocytic Nrf2 pathway in a manner distinct from the classical Keap1 antagonism employed by prototypical Nrf2 inducers. The mechanism was found to involve direct regulation of Nrf2's transactivation properties. Overall these results advance our knowledge of the molecular mechanism(s) associated with the control of endogenous antioxidant defences by physiological signals

    TCN 201 selectively blocks GluN2A-containing NMDARs in a GluN1 co-agonist dependent but non-competitive manner

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    Antagonists that are sufficiently selective to preferentially block GluN2A-containing N-methyl-d-aspartate receptors (NMDARs) over GluN2B-containing NMDARs are few in number. In this study we describe a pharmacological characterization of 3-chloro-4-fluoro-N-[4-[[2-(phenylcarbonyl)hydrazino]carbonyl]benzyl]benzenesulphonamide (TCN 201), a sulphonamide derivative, that was recently identified from a high-throughput screen as a potential GluN2A-selective antagonist. Using two-electrode voltage-clamp (TEVC) recordings of NMDAR currents from Xenopus laevis oocytes expressing either GluN1/GluN2A or GluN1/GluN2B NMDARs we demonstrate the selective antagonism by TCN 201 of GluN2A-containing NMDARs. The degree of inhibition produced by TCN 201 is dependent on the concentration of the GluN1-site co-agonist, glycine (or d-serine), and is independent of the glutamate concentration. This GluN1 agonist-dependency is similar to that observed for a related GluN2A-selective antagonist, N-(cyclohexylmethyl)-2-[{5-[(phenylmethyl)amino]-1,3,4-thiadiazol-2-yl}thio]acetamide (TCN 213). Schild analysis of TCN 201 antagonism indicates that it acts in a non-competitive manner but its equilibrium constant at GluN1/GluN2A NMDARs indicates TCN 201 is around 30-times more potent than TCN 213. In cortical neurones TCN 201 shows only modest antagonism of NMDAR-mediated currents recorded from young (DIV 9-10) neurones where GluN2B expression predominates. In older cultures (DIV 15-18) or in cultures where GluN2A subunits have been over-expressed TCN 201 gives a strong block that is negatively correlated with the degree of block produced by the GluN2B-selective antagonist, ifenprodil. Nevertheless, while TCN 201 is a potent antagonist it must be borne in mind that its ability to block GluN2A-containing NMDARs is dependent on the GluN1-agonist concentration and is limited by its low solubility

    Investigation into the destructive and adaptive responses of neural cells to stress

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    Homeostasis within the neuro-glial unit is essential to the longevity of neurons. Conversely, loss of homeostasis, particularly of Ca2+ levels, of redox balance and of ATP, contribute to neuronal loss and dysfunction in many neurodegenerative and neurological disorders. This thesis is centred on better understanding the vulnerability of neurons to stress, as well as adaptive responses to these stresses. Since neurodegenerative conditions associated with Ca2+, redox and bioenergetic dyshomeostasis are often characterised by early dendritic pathology, I first studied dendritic vs. somatic responses of primary cortical neurons to these types of challenges in real-time. Using a wide range of genetically-encoded probes to measure Ca2+, ATP, NADH, glutathione and glutamate, I show that dendrites are selectively vulnerable to oxidative stress, excitotoxicity as well as to metabolic demand induced by action potential (AP) burst activity. However, I provide evidence that neurons undergoing energetically demanding AP burst activity can adjust their metabolic output by increasing mitochondrial NADH production in a manner dependent on the mitochondrial calcium uniporter (MCU), as well as increase their capacity to buffer their intracellular redox balance. Finally, I have studied transcriptional programs in astrocytes triggered by neurons and neuronal activity to better understand adaptive signaling between different cell types in the neuro-glial unit. I developed a novel system combining neurons and astrocytes from closely-related species, followed by RNA-seq and in silico read sorting. I uncovered a program of neuron-induced astrocytic gene expression which drives and maintains astrocytic maturity and neurotransmitter uptake function. In addition I identified a novel form of synapse-to-nucleus signaling, mediated by glutamatergic activity and acutely regulating diverse astrocytic genes involved in astrocyte-neuron metabolic coupling. Of note, neuronal activity co-ordinately induced astrocytic genes involved in astrocyte-to-neuron thyroid hormone signaling, extracellular antioxidant defences, and the astrocyte-neuron lactate shuttle, suggesting that this non cell-autonomous signaling may form part of the homeostatic machinery within the neuro-glial unit

    There and back again: functional outcomes of reciprocal neuron-astrocyte signalling

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    Neurons do not exist in isolation in the central nervous system, and there is a growing appreciation that the interactions between neuronal and non-neuronal cells are fundamentally important for nervous system function. A major family of non-neuronal cells are the astrocytes, with a surge of recent work suggesting the relationship between neurons and astrocytes is bidirectional and highly complex. In my thesis I seek to further uncover the nature of this intimate relationship between neurons and astrocytes of the cortex. One well-established role of astrocytes is the collection of neuronal glutamate via their high affinity excitatory amino acid transporters, with dysfunctions in this system being linked to numerous neurological diseases. Previous reports suggest that neurons may regulate the expression of these astrocytic glutamate transporters, through an as yet unknown pathway. In my thesis I first investigate the nature of this non-cell-autonomous neuronal control of astrocytes. I begin by using results from the lab’s novel mixed-species RNA-sequencing dataset to explore how neurons regulate astrocytic gene expression, finding that they upregulated the astrocytic glutamate transporters. By electrophysiological recording I show a corresponding functional increase in the astrocytes’ ability to collect glutamate, before demonstrating that neurons upregulate the astrocytic transporters through Notch signalling. I then investigate whether continuous Notch signalling is required to maintain these transporters’ expression and function, finding that removal of Notch signalling after the establishment of transporter expression significantly reduces the transporters’ activity. For the remainder of my thesis I explore how cortical astrocytes may in turn control cortical neuronal function. Using RNA-seq data generated in the lab I discover a host of neuronal genes that are regulated by astrocytes. Amongst these genes were the functionally important K+ inward rectifying channel family, which were strongly downregulated in neurons by astrocytes, an observation hitherto unseen. I hypothesise that this downregulation will result in alterations to neuronal membrane properties which will enhance neuronal excitability, and that this may in turn have down-stream consequences on neuronal activity and synaptogenesis. I find that cortical neurons are rendered more excitable by astrocytes, leading to an enhancement of neuronal activity, driven by the astrocyte-induced decrease in K+ inward rectifiers. Although I do not see an increase in baseline synaptogenesis, I show a range of homeostatic neuronal responses emerge in the presence of astrocytes. This work suggests that astrocytes play a central role in regulating neuronal activity

    Contribution of the centriolar protein Trichoplein to endothelial cell function in brain vasculature

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    Age-related cerebrovascular dysfunction plays a critical role in the pathogenesis of cerebrovascular disease, vascular dementia and Alzheimer’s disease, but therapeutic development has been largely unsuccessful until now. Endothelial cells (ECs) are a fundamental component of the neurovascular unit. Their dysfunction has been established as an early event in the pathogenesis of cerebrovascular disease and vascular dementia, leading to dysregulation of cerebral blood flow and blood-brain barrier damage. In this context, identifying novel genes associated with endothelial dysfunction will help understand the role of ECs in blood-brain barrier integrity and address new therapeutic targets. Trichoplein (TCHP) was initially characterised as a ubiquitously expressed keratin filament-binding protein associated with cell division and cilia formation. Moreover, TCHP has been reported to regulate ER-mitochondria tethering and promote mitophagy, a specialised form of autophagy necessary for the turnover/remodelling of mitochondria. In the lab, we previously demonstrated a pivotal role for the centriolar protein TCHP in linking endothelial cell function with the control of autophagy, showing that the depletion of TCHP in ECs impairs migration and sprouting and triggers cellular inflammation. In line with this, the endothelial-specific deletion of Tchp (TchpEC) in mice decreased the blood flow recovery and vascularisation following hind-limb ischaemia. Protein aggregates were detected in ECs from TchpEC mice and ECs from patients with coronary artery disease. However, the presented preliminary data regarding the role of TCHP in brain vasculature has not been explored yet. My PhD project aims to characterise the role of TCHP in brain microvascular ECs in vitro and in vivo and to reveal its role in blood-brain barrier integrity. For this study, I generated mice with endothelial selective Tchp knock-out (TchpEC ) by breeding the conditional knock-out mice with mice carrying Cre recombinase under the VE-cadherin promoter. RNA sequencing demonstrated the up-regulation of matrix-metalloproteinases and chemokine signalling pathways in the brain ECs isolated from TchpEC mice. The analysis of the in vitro permeability by Electric Cell-substrate Impedance Sensing (ECIS®) revealed an impaired barrier function in ECs lacking TCHP. Furthermore, TchpEC mice administered with the fluorescently labelled tracer dextran presented a higher tracer accumulation in the brain than WT mice, showing a loss of blood-brain barrier integrity. In addition, the presence of protein aggregates was confirmed in the cytoplasm of brain microvascular ECs lacking TCHP. The proteomic characterisation of the insoluble- protein fraction revealed RNA-binding and proteasome-associated proteins, suggesting the toxicity of these aggregates for the cells. Finally, a pharmacological screening identified an FDA-approved compound activating autophagy and, thus, restoring EC function and reducing expression of inflammatory genes in EC lacking TCHP. Collectively, this study presents the novel role played by TCHP in the cerebrovascular endothelium and identifies a new mechanism by which the silencing of TCHP could link endothelial dysfunction to impaired blood-brain barrier integrity

    Molecular detection and significance of circulating colorectal cancer cells / Jennifer E. Hardingham.

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    Bibliography: leaves 214-236.xviii, 238 leaves : ill. (some col.) ; 30 cm.Thesis (Ph.D.)--University of Adelaide, Dept. of Physiology, 199

    ER-mitochondria interactions and neurodegeneration

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    Physical membrane contact sites between the ER and mitochondria play a critical role in regulating a variety of processes including calcium signalling, lipid exchange, controlling mitochondrial dynamics and cell death signalling. These contact sites are formed at specialised regions of membrane, termed mitochondrial associated membranes or MAMs, that are enriched for a group of proteins acting as tethers to hold the ER and mitochondria at appropriate distances from one another. The distance of these junctions is usually defined between 10-30 nm but can vary in response to certain cellular conditions and it is believed that heterogeneity in the distance of the contact sites may be reflective of different protein compositions or activities at these sites. Abnormal alterations to ER-mitochondria contacts are observed in numerous neurodegenerative disorders including Alzheimer’s, Parkinson’s and amyotrophic lateral sclerosis (ALS) and therefore, it is believed that a dysfunction to the MAMs may be a common pathogenic mechanism underlying neuronal cell death. Due to the associated dysfunction of organelle contact sites in neurodegenerative disorders, the ability to detect these structures could provide critical information on the pathogenic mechanisms of neuronal cell death. Existing techniques for detecting MAMs have numerous limitations or are restricted to fixed samples. The aim of this thesis was to develop a fluorescent-based method for the visualisation of contact sites that can also be applied to living systems to study organelle contact dynamics. Here, we have generated split fluorescent Venus fragments targeted to the ER and outer mitochondrial membrane respectively, as the basis for our bi-fluorescence complementation (BiFC) system for the detection and quantification of MAMs in living cells. The principle of this technique relies on close spatial proximity of the reporter probes for the restoration of the fluorescent protein and the emission of a detectable signal. Validation of this method highlighted several advantages over existing methods of detecting ER-mitochondria contacts and we were able to report on changes in agreement with previously published, high-resolution electron microscopy studies. Adaptations to the technique allow for the detection of other organelle contact sites by varying the targeting sequence of the complementary Venus fragments. As these reporter proteins detect junctions of a maximum distance of around 6-10 nm, we could use the BiFC system to correlate the Venus signal with specific functions of the MAMs to try and elucidate the functional significance of these particularly tight contact sites. Our results suggest that some of these contact sites may represent sites of actively dividing mitochondria. Furthermore, our results indicated that these tight ER-mitochondria contacts are formed on a sub-population of mitochondria of higher than average resting membrane potential and mitochondrial calcium levels, which may indicate differences in the bioenergetic state or the health of mitochondria with tight ER-mitochondria contact sites. Finally, this technique was used to investigate the role of a MAM-enriched protein, VAPB, of which a proline to serine missense mutation is associated with a dominantly inherited form of ALS termed ALS8. The data shows that expression of the mutant disease-linked VAPBP56S significantly increases the mean number of contact sites per cell whereas altering the levels of wild-type VAPB has no significant effect. This finding suggests that the expression of VAPBP56S induces abnormalities in ER-mitochondria tethering but it is still unclear whether this is through direct binding properties of mutant VAPB or through an indirect secondary mechanism. As the MAMs regulate many of the pathways that are commonly perturbed in neurodegenerative disorders, alterations in ER-mitochondria contact sites may represent a key early pathogenic event in ALS

    A randomized controlled trial assessing whether listening to music at time of embryo transfer effects anxiety levels

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    Background: Fertility treatment may have a negative emotional impact on women. Lower levels of anxiety have been associated with improved treatment success but there is no standardised method for addressing these needs. Music is a safe and beneficial non-pharmacological intervention in a number of medical fields. It may alter subjective and objective psychological anxiety as well as physiological functioning. However, little data exists surrounding the therapeutic use of music in fertility treatment but it may attenuate anxiety. Methods: An assessor-blinded parallel case control study in an IVF center, England UK. 42 women undergoing assisted reproductive treatment were recruited between February and December 2013. Women were randomised by random envelopes containing equal sized 'music' (listened to self-selected music during embryo transfer) or 'control' (no music) groups. Participants completed the Spielberger State-Trait Anxiety Inventory prior to, and immediately following a post-treatment observation period. Primary outcome was change in anxiety level. Results: 32 of 42 women (76.2%) were less anxious following treatment (mean change in anxiety score 6.9 95%CI 4.2-9.6, P&lt;0.01) without difference between the study group (7.1 95% CI 3.5-10.7) (P=0.46) and controls (6.7 95%CI 2.3-11.1). Clinical pregnancy rates (55.0%) did not differ between music and control groups (P=0.95). Conclusions: Listening to self-selected music 15 minutes before and after embryo transfer does not significantly impact on anxiety levels of women undergoing assisted conception treatment nor clinical pregnancy rates. Music therapy has not been shown to reduce anxiety at time of ET and the effects of interventions such as hypnosis, acupuncture, aromatherapy and other forms of relaxation therapy remain to be explored
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