Polycyclic propargylamine derivatives as multifunctional neuroprotective agents

Zindo, Frank T.

January 2018

Philosophiae Doctor - PhD / The abnormal death of neurons in the central nervous system of individuals suffering from neurodegenerative diseases such as Parkinson’s disease, Alzheimer’s disease, Huntington’s disease and amyotrophic lateral sclerosis, takes place by an intrinsic cell suicide programme known as apoptosis. This process is triggered by several stimuli, and consists of numerous pathways and cascades which lead to the death of neuronal cells. It is this multifactorial nature of neurodegenerative diseases that has over the years seen many researchers develop compounds that may serve as multi-target directed ligands (MTDLs) which could potentially confer neuroprotection by acting simultaneously on different receptors and target sites implicated in neurodegeneration. This study was aimed at developing MTDLs that may serve as neuroprotective agents by simultaneously (a) inhibiting N-methyl D-aspartate receptors (NMDAR) and blocking L-type voltage gated calcium channels (VGCC) thus regulating the Ca2+ influx mediated excitotoxic process; (b) inhibiting the monoamine oxidase enzymes A and -B (MAO-A/B) thus allowing increase in dopamine levels in the central nervous system and reducing the levels of the highly oxidative products produced by the activity of these enzymes; (c) possessing anti-apoptotic activity to halt the neuronal cell death process. In designing the compounds we focused on the structures of rasagiline and selegiline, two well-known MAO-B inhibitors and proposed neuroprotective agents, and of NGP1-01, a known VGCC blocker and NMDAR antagonist. The first series of compounds (reported in research article 1, Chapter 3), comprised polycyclic propargylamine and acetylene derivatives. Compounds 12, 15 and 16 from this series showed promising VGCC and NMDA receptor channel inhibitory activity ranging from 18 % to 59 % in micromolar concentrations, and compared favourably to the reference compounds. In the MAO-B assay, compound 10 exhibited weak MAO-B inhibition of 73.32 % at 300 μM. The rest of the series showed little to no activity on these target sites, despite showing significant anti-apoptotic activity. This suggested the compounds in this series to be exhibiting their neuroprotective action through some other mechanism(s) unexplored in this study.

Neurodegeneration

Polycyclic scaffold

Propargylamine derivatives

Neuroprotection

Apoptosis

Evaluating the neuroprotective effects of fermented rooibos herbal tea in Wistar rats exposed to bisphenol-A during gestation and lactation

Gamoudi, Bushra Khalifa

January 2019

Magister Scientiae (Medical Bioscience) - MSc(MBS) / Exposure to endocrine-disrupting chemicals as bisphenol A (BPA) during gestation and early postnatal life is known to disrupt normal developmental processes and alter the body’s endocrine system leading to deleterious effects in the developing central nervous system (CNS). BPA is an industrial synthetic chemical commonly used in the production of a range of polymers and consumer products, despite concerns about its safety. There is therefore the need to protect the developing CNS from potential damage through the administration of neuroprotective agents. Most medicinal plants are reported to possess significant protective potential against tissue damage through different mechanisms that prevent cell death, oxidative stress, inflammation, immunodeficiency, etc. In this study, the protective effects of fermented rooibos (Aspalathus linearis) tea against the deleterious effects of BPA were investigated. Rooibos is a herbal beverage indigenous to South Africa with widely acclaimed health benefits often linked to the bioactivity of its polyphenolic compounds, especially aspalathin. The anti-allergic, cardiovascular, antioxidant and neuroprotective effects of this herb have been previously reported hence, the present study aims to investigate if regular consumption of rooibos tea during pregnancy and lactation could protect the developing brain from the deleterious effects of BPA in a Wistar rat model. A total of 40 three-month old adult female pregnant dams, with an average weight of 250g, were divided into four groups (n=10). Group 1 control rats received 9% normal saline ad libitum; group 2 rats received 400μg/kg/day BPA only; group 3 rats received 20% fermented rooibos tea as well as 400μg/kg/day BPA, while group 4 rats received ad libitum 20% fermented rooibos tea only. Offspring rats were housed in the same cages as the dams and only separated after weaning on postnatal day (PND) 21. Neurobehavioural assessment using the open field test was done on postnatal day (PND) 42 after which the final body masses were taken before the rats were decapitated under deep anaesthesia, and the desired CNS parts carefully dissected out and processed for histological, biochemical and immunohistochemical studies. The results obtained showed that there was significant impairment of neurobehavioural activity, decreased cerebral and cerebellar antioxidant enzyme activity, reduced hippocampal CA1 length, significant loss of cerebellar Purkinje cells and significant astrocyte activation demonstrated by increased glial fibrillary acidic protein (GFAP) activity in experimental rats exposed to BPA only. However, co-administration of rooibos tea significantly attenuated the BPA-induced distortions. Taken together, these findings suggest that rooibos could be a potent neuroprotective agent against BPA-induced structural, functional and biochemical alterations in the developing CNS.

Bisphenol A (BPA)

Rooibos

Antioxidants

Neurodegeneration

Neuroprotection

Physiological role of the cannabinoid receptor 1 (CB1) in the murine central nervous system

Marsicano, Giovanni

January 2001

The cannabinoid system is involved in many functions of mammalian brain, such as learning and memory, pain perception and 'locomotion. The "brain type" cannabinoid receptor CB 1 is one of the key elements of the cannabinoid system. In this Thesis, some aspects of the neurobiology of mouse CB 1 are described. CB 1 mRNA distribution was analysed by single and double in situ hybridization (ISH), revealing the expression of the receptor in specific neuronal subpopulations. This expression pattern suggests many putative functional cross-talks between the cannabinoid system and other signalling molecules in the brain, such as glutamate, GABA, cholecystokinin and nitric oxide (NO). The putative functional interactions of the cannabinoid system with the NO pathway was studied by pharmacological treatment of neuronal NO synthase (nNOS) mutant mice with the CBI agonist A9-tetrahydrocannabinol (A9-THC). The results showed that nNOS is necessary for some central effects of A9-THC. Moreover, ISH analysis revealed. that nNOS-deficient mice contain levels of CBI lower than normal in selected brain regions. A "conditional" targeting approach was developed to gain insights into the specific functions of CB 1 in mouse brain. By gene targeting experiments, two mutant lines were obtained. The "Flox CB 1" mouse line, containing the whole open reading frame of CB I flanked by two loxP sites will be the key tool for the generation of mouse mutants with a spatiotemporal-restricted deletion of CB I. The "CBN" mice, carrying a "null" mutation of CB 1, were used for a study aimed to clarify some aspects of the in vitro neuroprotective activity of cannabinoids and, in particular, the involvement of CB 1. In vitro oxidative stress assays were performed on cell lines and on primary neuronal cultures derived from homozygous CBN/CBN mice and wild type littermates. The results indicate a differential protective activity of cannabinoids on cell lines and primary cultures. However, CBI does not appear to be involved in the in vitro leuroprotective effects of cannabinoids.

572.8

In vivo and in vitro studies on docosahexaenoic acid in traumatic brain injury

Angus, Ruth

January 2017

Traumatic brain injury (TBI) is a devastating disease causing disability and death, and currently there are no effective treatments available. Therefore, there is an utmost need to improve our understanding of the pathophysiology of TBI and to identify potential therapies that can provide neuroprotection after injury. The aims of this thesis were to develop an in vivo and in vitro model of TBI, in which to assess the potential neuroprotective effects of an omega-3 polyunsaturated fatty acid (PUFAs), docosahexaenoic acid (DHA). Method The controlled cortical impact (CCI) in vivo model of TBI was optimized and performed in mice. Both a behavioural (Morris water maze (MWM) for cognitive deficits) and histological endpoints (astrogliosis, lesion size and activated microglia) were used to assess severity and neuroprotective effects of DHA. An in vitro model of mechanical TBI was also set up and optimized. This model employed 3D astrocyte cultures obtained from GFP positive rat pups. The CCI impactor from the in vivo studies was used to damage the cultures, and at 24 hours, 5 days and 10 days the astrogliosis and cell number was measured. Results The optimization of the in vivo studies demonstrated that at impaction depth of 2.2 mm produced an injury that was significantly different to the sham injury, in MWM performance and increased astrogliosis. Interestingly, there was an increase in the amount of astrogliosis on the contralateral side of the brain. A second study performed using the 2.2 mm injury parameters was performed, where an injection of DHA was administered via the tail vein 30 min after injury. The DHA-treated group did not demonstrate any neuroprotection compared to the injury-only group. However, there was an increase in the amount of astrogliosis in the contralateral hippocampus of the DHA-treat group. In the fat-1 studies it was shown that older male mice performed worse in the MWM, that the fat-1 gene did not confer neuroprotection but did lead to increased astrogliosis. The in vitro study revealed that astrocytes in the lesioned gels demonstrated an increase in astrogliosis, there was also an increase in the number of cell in the cultures following the lesion. Conclusion In conclusion, the in vivo model of CCI replicated components of the human TBI including a behavioural deficit and pathophysiological changes. Omega-3 PUFAs failed to demonstrate functional neuroprotection in this model, but histologically, promoted an increase in reactive astrogliosis. The development of a novel in vitro model of focal injury in a 3D culture system, that elicits reactive astrogliosis, could be used to support further studies of the astrocytic responses to mechanical injury.

Rapid neuronal responses during spreading neurotoxic and neuroprotective network activity

Samson, Andrew James

January 2016

Glutamate is the major excitatory neurotransmitter in the mammalian central nervous system, playing critical roles in basal synaptic transmission and the molecular correlates of learning and memory, long-term potentiation and long-term depression. However, glutamate is also neurotoxic during prolonged exposure and the dysfunction of the glutamatergic system has been implicated in most neurological disorders, including stroke and epilepsy, and in certain neurodegenerative diseases, including Alzheimer’s disease. In these conditions, an increased concentration of extracellular glutamate causes an over-activation of local ionotropic glutamate receptors that trigger neuronal cell death (excitotoxicity). In this study, we have used dissociated hippocampal neurons cultured on coverslips and within novel microfluidic devices to study neuronal responses, both functional and morphological, to prolonged exposure to glutamate. We find that high glutamate concentrations evoke a rapid retraction of dendritic spines, the collapse of microtubules, the formation of dendritic beads and the inhibition of basal neurotransmitter release. These responses have been identified in many neurological disorders where excitotoxicity is reported, suggesting they may be a sign of imminent cell death. However, the development of dendritic beads and the inhibition of network activity also occurs at subtoxic concentrations of glutamate and neuronal morphological changes recover rapidly post-insult. We therefore hypothesised that beading and the inhibition of neurotransmitter release may be a protective mechanism and render neurons resistant to subsequent glutamatergic insults. However, a subtoxic stimulation is not protective against a subsequent excitotoxic insult delivered immediately afterwards. However, given that neurotransmitter release can confer protection to neurons, it is possible that protection is realised, not on the neurons exposed to the subtoxic insult, but on those neurons with which they communicate, as a ‘warning’ signal. To assess the impact of a localised insult to a wider neuronal network, hippocampal neurons were cultured in novel microfluidic devices, to environmentally isolate neuronal populations, whilst preserving synaptic contacts between them. We observe that bystander naïve neurons downstream of a localised excitotoxic insult succumb to a secondary, activity-dependent, spreading toxicity. In addition, we reveal a novel mechanism by which neuronal networks also transmit a rapid and robust (albeit transient) protection from excitotoxicity. The protective phenotype acquired by neurons during this protective process requires neuronal inhibitory activity to quench overexcitation, along with the retraction of dendritic spines and/or dendritic beading. Therefore, we highlight a dichotomous role that dendritic beading plays following a direct glutamatergic insult (large beads) and as a result of GABAergic recruitment in downstream neurons (small beads). We determine that a network neuroprotective capacity exists that limits spreading toxicity, which may be recruited from a distal site even after an excitotoxic insult has occurred. Together, we may have identified a new therapeutic opportunity to limit on-going brain damage in conditions of acute neuronal injury.

612.8

Effects of Chronic Nicotine Exposure and Lack of High Affinity Nicotinic Receptors on Cortico-Hippocampal Areas in the Aging Mouse Brain

Huang, Pei-San

2012 May 1900

Nicotine, the major psychoactive ingredient of tobacco smoke, underlies numerous effects by activating neuronal nicotinic acetylcholine receptors. Both in vitro and in vivo studies suggest that nicotine is neuroprotective and improves cognitive performance. Epidemiology studies show that smoking is negatively correlated with the incidence of Parkinson's disease and Alzheimer's disease. Postmortem research and neuroimaging studies show that loss of nicotinic binding sites in the brain is the major feature of neurodegenerative diseases related to dementia and cognitive impairment. Caloric restriction, a regimen that extends the lifespan in all mammalian species studied so far including rodents and primates, is a highly regulated response to food deprivation. It is believed that the longevity effect of caloric restriction is mediated by SIRT1, a NAD-dependent deacetylase, and its related genes. Nicotine's effect on body weight could also lead to weight loss by decreasing caloric absorption consumption. The goal of this study was to find the possible correlation between nicotine's effects and the activation of SIRT1 and its related genes. Using beta2-/- mice that lack high affinity beta2 nicotinic acetylcholine receptors (nAChRs), we first demonstrated that beta2* nAChRs do not directly regulate expression of survival genes. However, we found that loss of beta2* nAChRs could result in augmented cellular stress, which indirectly increased expression of SIRT1, Nampt, and Ku70, possibly as an adaptive response to provide protection against neurodegeneration. We also found that loss of endogenous activation of beta2* nAChRs had less effect on synaptic connections but strongly impaired survival of hippocampal GABAergic neurons. To activate beta2* nAChRs in normal mice, we administered nicotine through drinking water. In a short-term exposure study, we determined the dose of nicotine to be used in young adult mice, and found that chronic nicotine treatment was anxiolytic, decreased caloric consumption, increased nAChR binding sites, and most importantly, increased expression of SIRT1 and its related genes. Finally, we compared long-term nicotine treatment with caloric restriction in middle-aged mice to examine their effects to brain aging, and our results indicated that in mice long term caloric restriction and nicotine treatment both tend to improve memory in aging mice, but appear to act through different mechanisms.

nicotine

neuroprotection

aging

nAChRs

neurodegeneration

caloric restriction

Cannabinoids as neuroprotective agents : a mechanistic study

Nilsson, Olov

January 2006

Glucose and oxygen supply to the brain is critical for its proper function and when it is restricted as during a stroke, neurons and glial cells quickly become necrotic leading to structural damage as well as functional impairment and even death. To date there are few effective therapies that inhibit the neurodegenerative process and improves the outcome for the affected individual. One possible target is the cannabinoid system. Cannabinoid receptor agonists reduce ischemic volume, endogenous cannabinoid levels are elevated during neurodegenerative insults and mice devoid of the central cannabinoid receptor are more seriously affected by experimental stroke than wild type mice. The cannabinoids are also ascribed anti-inflammatory properties and post ischemic inflammation has been proposed to contribute to the evolution of the ischemic damage. In this thesis mechanisms that can contribute to cannabinoid neuroprotection have been studied. In papers I and II the chick was used as a model species, since preparation of embryonic primary neuronal cultures from chick is relatively simple and time efficient compared to rodent primary cultures. Both adult and embryonic chick brain membranes contain functional CB1 receptors and in the cultures they are coupled to inhibition of cAMP production. In embryonic primary cultures, neurons were not protected from glutamate toxicity by preincubation with CB receptor agonists suggesting that postsynaptic cannabinoid mediated neuroprotection is not effective in this system. The effect of cannabinoid agonists on neutrophil chemotaxis and transmigration was investigated in paper III. The CB1/CB2 agonist WIN 55,212-2 inhibited TNF-α-induced transmigration across ECV304 cell monolayers. The effect of WIN 55,212-2 on this process which was mediated by a reduction of IL-8 release from the ECV304 cells rather than a direct effect upon the migratory response to IL-8 was not possible to abolish with CB1 or CB2 agonists suggesting a mechanism distinct from the cannabinoid receptors is operative. In paper IV the photothrombotic ring stroke model was evaluated to determine if it is suitable in intervention studies targeting the cannabinoid system. Three major endpoints were of interest, ischemic volume, neutrophil infiltration and CB1 receptor function. Consistent with previous studies the ischemic volume peaked at 48 hours after irradiation. Neutrophil infiltration was quantified using a myeloperoxidase activity assay. The assay revealed an increase in myeloperoxidase activity 48 hours after irradiation, albeit at a modest level. The function of the CB1 receptor was assessed by radioligand binding and there was no change in either total binding or functional G-protein coupling following photothrombosis. Taken together these results indicate that it is feasible to undertake cannabinoid intervention studies in this model.

cannabinoid

neuroprotection

inflammation

cytokine

neutrophil

Pharmacology

Farmakologi

Inhibition of Beta2 Integrin-mediated Leukocyte Adhesion Attenuates the Inflammatory Response and is Neuroprotective Following Global Cerebral Ischemia

Salewski, Ryan Paul Francis

22 September 2009

Leukocyte adhesion to cerebral endothelial cells plays a critical role in the inflammatory response following transient global cerebral ischemia but its contribution to delayed neuronal cell death is not completely understood. We compared ischemic mice treated with a monoclonal antibody to β2-integrin adhesion receptors (anti-CD18) or a non-binding control antibody following ischemia. Inflammation was characterized by increased CD18 expression on leukocytes and inflammatory mediators in the peripheral blood and brain tissue. Notably, interleukin-1β, which has been shown to mediate cell death in neurons, was elevated in the blood and brain. Anti-CD18 blocked leukocyte adhesion as well as the inflammatory responses, including interleukin-1β expression in neurons. Blocking leukocyte adhesion protected the structural integrity of the hippocampus, cerebral cortex and thalamus, and preserved spatial. Leukocytes adhesion to endothelial cells plays an important role in the evolution of neurological deficit in global cerebral ischemia despite the lack of transmigration of leukocytes across blood-brain-barrier.

Global Cerebral Ischemia

Integrins

Cytokines

Neuroprotection

0317

Inhibition of Beta2 Integrin-mediated Leukocyte Adhesion Attenuates the Inflammatory Response and is Neuroprotective Following Global Cerebral Ischemia

Salewski, Ryan Paul Francis

22 September 2009

Leukocyte adhesion to cerebral endothelial cells plays a critical role in the inflammatory response following transient global cerebral ischemia but its contribution to delayed neuronal cell death is not completely understood. We compared ischemic mice treated with a monoclonal antibody to β2-integrin adhesion receptors (anti-CD18) or a non-binding control antibody following ischemia. Inflammation was characterized by increased CD18 expression on leukocytes and inflammatory mediators in the peripheral blood and brain tissue. Notably, interleukin-1β, which has been shown to mediate cell death in neurons, was elevated in the blood and brain. Anti-CD18 blocked leukocyte adhesion as well as the inflammatory responses, including interleukin-1β expression in neurons. Blocking leukocyte adhesion protected the structural integrity of the hippocampus, cerebral cortex and thalamus, and preserved spatial. Leukocytes adhesion to endothelial cells plays an important role in the evolution of neurological deficit in global cerebral ischemia despite the lack of transmigration of leukocytes across blood-brain-barrier.

Global Cerebral Ischemia

Integrins

Cytokines

Neuroprotection

0317

Synthèses de brassinostéroïdes et étude de leur potentiel neuroprotecteur

Boisvert, Martin

January 2009

Les brassinostéroïdes sont des phytostérols découverts relativement récemment. Les études de plusieurs chercheurs ont déjà montré que ces molécules sont de véritable hormones de croissance pour les plantes. Ces stéroïdes possèdent donc un potentiel important en agriculture. Cependant, à notre connaissance, peu d'études sur les brassinostéroïdes n'a été réalisée chez les mammifères. Sachant que plusieurs phytostérols possèdent un potentiel antioxydant, nous avons porté notre attention sur le potentiel neuroprotecteur des brassinostéroïdes. Dans ce travail de recherche, nous avons tenté de déterminer si les brassinostéroïdes sont aptes à contrer le stress oxydatif, un suspect potentiel dans le déclenchement de la maladie de Parkinson. Cependant, ces molécules ne sont pas facilement accessibles dans la nature ou dans le commerce. Peu de brassinostéroïdes sont commerciaux, leur concentration effective dans les plantes est faible et leur extraction à partir de végétaux est laborieuse. C'est ainsi que nous avons opté pour la synthèse de ces molécules. Dans le présent travail, nous présentons la synthèse de la 28-Homocastastérone et de plusieurs précurseurs de brassinostéroïdes. Nous présentons aussi une étude de la réactivité particulière du lien alcénique en position C-22,C-23 de ces molécules. Finalement, nous présentons nos résultats préliminaires sur le potentiel neuroprotecteur des molécules préparées face au MPP+, une toxine reproduisant la neurodégénérescence de la maladie de Parkinson. ______________________________________________________________________________ MOTS-CLÉS DE L’AUTEUR : Brassinostéroïdes, Neuroprotection, Synthèse asymétrique, Maladie de Parkinson, Chimie des stéroïdes.

Brassinostéroïde

Neuroprotecteur

Synthèse asymétrique

Neuroprotection

Maladie de Parkinson