Global ETD Search

751	Characterization of Williams-Beuren Syndrome Mouse Models: Linking Genes with Cognition and Behaviour Lam, Emily 26 July 2012 (has links) Deletion (Williams-Beuren syndrome (WBS)) and duplication (Dup7q11.23) of a common interval spanning 26 genes on chromosome 7q11.23 cause disorders with a spectrum of clinical, cognitive and behavioural symptoms. Studies of individuals with atypical deletions have implicated two genes, GTF2IRD1 and GTF2I. Here I describe the behavioural characterization of mice hemizygous for Gtf2i, or Gtf2ird1 and Gtf2i together, as well as mice with additional Gtf2i copies. Dosage changes in Gtf2i were associated with working memory impairment and separation anxiety, and possibly with general anxiety and repetitive behaviours. A potential cause of these phenotypes was found in brain tissue, where subcellular localization of the calcium channel TRPC3, which is regulated by GTF2I, was found to be altered. Collectively, these results provide a better understanding of the contributions of GTF2I to the cognitive and behavioural profile of WBS and Dup7q11.23 and identify a potential biological mechanism that may underlie some of the symptoms. Molecular biology Williams-Beuren syndrome Mouse models Behaviour Cognitive development Neurobiology 0317
752	Characterization of Williams-Beuren Syndrome Mouse Models: Linking Genes with Cognition and Behaviour Lam, Emily 26 July 2012 (has links) Deletion (Williams-Beuren syndrome (WBS)) and duplication (Dup7q11.23) of a common interval spanning 26 genes on chromosome 7q11.23 cause disorders with a spectrum of clinical, cognitive and behavioural symptoms. Studies of individuals with atypical deletions have implicated two genes, GTF2IRD1 and GTF2I. Here I describe the behavioural characterization of mice hemizygous for Gtf2i, or Gtf2ird1 and Gtf2i together, as well as mice with additional Gtf2i copies. Dosage changes in Gtf2i were associated with working memory impairment and separation anxiety, and possibly with general anxiety and repetitive behaviours. A potential cause of these phenotypes was found in brain tissue, where subcellular localization of the calcium channel TRPC3, which is regulated by GTF2I, was found to be altered. Collectively, these results provide a better understanding of the contributions of GTF2I to the cognitive and behavioural profile of WBS and Dup7q11.23 and identify a potential biological mechanism that may underlie some of the symptoms. Molecular biology Williams-Beuren syndrome Mouse models Behaviour Cognitive development Neurobiology 0317
753	Effects of Cannabidiol on MK-801-Induced Locomotor Sensitization in Mice Cronin, Sara K. 23 April 2012 (has links) Previous research has shown that cannabidiol (CBD), a non-psychoactive compound in the hemp plant Cannabis sativa, may be useful in treating drug craving, one of the hallmarks of drug addiction. However, the neural mechanism by which CBD attenuates craving is poorly understood. Studies from other laboratories have shown that neuroplastic changes associated with brain NMDA glutamate systems may at least partially serve as a neural mechanism for craving. In the current study, the noncompetitive NMDA receptor antagonist MK-801 maleate was used to induce locomotor sensitization, a form of NMDA glutamate-mediated neuroplasticity, in mice to test the sensitization-attenuating potential of CBD. Separate groups of mice (N=8) received either CBD (1.0 mg/kg, i.p.) or saline thirty minutes prior to an intraperitoneal injection of MK-801 (0.5 mg/kg, i.p.) or saline and tested for locomotor performance in an open field (Induction Trial). Seventy-two hours later all mice, regardless of drug pretreatment, were tested for locomotor activity following a second administration (0.5 mg/kg, i.p.) of MK-801 (Sensitization Trial). Results revealed a significant difference across groups for the Induction Trial, with groups receiving SAL-MK801 and CBD-MK801 significantly more active than SAL-SAL and CBD-SAL groups. Pretreatment with CBD had no effect on the locomotor activating effects of MK-801 during the Sensitization Trial with similar levels of locomotor performance across drug groups. Possibilities for the lack of CBD effects are discussed, as well as implications and future research directions. Behavioral Neurobiology Cognitive Neuroscience
754	LES CELLULES FOLLICULOSTELLAIRES : UNITES FONCTIONNELLES D'UNE VOIE DE COMMUNICATION A LONGUE DISTANCE DANS L'HYPOPHYSE ANTERIEURE. Fauquier, Teddy 17 December 2001 (has links) (PDF) L'hypophyse antérieure assure une interface endocrine entre le cerveau et les organes périphériques. En effet, cette glande sécrète de manière pulsatile ses différentes hormones dans la circulation générale sous l'influence de facteurs hypothalamiques déversés épisodiquement dans le système porte de l'éminence médiane. Toutefois, l'influence hypothalamique ne saurait à elle seule expliquer l'harmonisation des sécrétions des cellules d'un même type endocrine, qui sont distribuées de manière hétérogène au sein du parenchyme. Il existe sans doute des mécanismes permettant de coordonner l'activité des cellules endocrines à l'échelle de la glande entière. Au cours de cette thèse, nous avons montré la présence d'un mécanisme de communication intra-hypophysaire permettant un transfert rapide d'information au sein d'un réseau de cellules non-endocrines, les cellules folliculostellaires (FS). Ce travail réalisé sur des tranches épaisses d'hypophyse de rat, modèle qui maintient intacte l'architecture cordonale du tissu, a permis de mettre en évidence l'excitabilité membranaire des cellules FS, propriété jusqu'alors inconnue. Cette excitabilité sert de base à l'initiation de vagues calciques, qui peuvent se propager rapidement via des jonctions gap à des régions éloignées de la glande. Nous avons également étudié la libération d'interleukine-6 (IL-6) par les cellules FS. Cette cytokine est connue pour stimuler l'ensemble des sécrétions hormonales hypophysaires. La production d'IL-6 est stimulée par le PACAP. Ce neuropeptide semble agir directement au niveau du gène, et son effet dépend de l'état des communications intercellulaires au sein du réseau. Les cellules FS pouvant répondre à des stimuli d'origine centrale et périphérique, ainsi que dialoguer avec les cellules endocrines, l'ensemble de ces résultats montre que le réseau de cellules FS pourrait fournir un mécanisme efficace qui coordonnerait le fonctionnement de la glande en fonction des différents états physiologiques hypophyse antérieure vagues calciques communications intercellulaires excitabilité membranaire
755	Functional Substrates of Social Odor Processing within the Corticomedial Amygdala: Implications for Reproductive Behavior in Male Syrian Hamsters Maras, Pamela Mary 19 April 2010 (has links) Adaptive reproductive behavior requires the ability to recognize and approach possible mating partners in the environment. Syrian hamsters (Mesocricetus auratus) provide a useful animal model by which to study the neural processing of sexual signals, as mate recognition in this species relies almost exclusively on the perception of social odors. In the laboratory, male hamsters prefer to investigate female odors compared to male odors, and this opposite-sex odor preference provides a sensitive measure of the underlying neural processing of sexual stimuli. In addition to chemosensory cues, reproductive behavior in hamsters also requires sufficient levels of circulating gonadal steroid hormones, which reflect the reproductive state of the animal. These chemosensory and hormone signals are processed within an interconnected network of ventral forebrain nuclei, and within this network, the posteromedial cortical amygdala (PMCo) and medial amygdala (MA) are the only nuclei that both receive substantial chemosensory input and are also highly sensitive to steroid hormones. Although a large body of evidence suggests that the MA is critical for generating attraction to sexual odors, the specific role of the PMCo in regulating odor-guided aspects of male reproductive behavior has never been directly tested. Furthermore, detailed analyses of the MA suggest that separate, but interconnected sub-regions within this nucleus process odors differently. Specifically, the anterior MA (MeA) receives the majority of chemosensory input and responds to a variety of social odors, whereas the posterodorsal MA (MePD) receives less chemosensory input but contains the vast majority of steroid receptors. In order to further elucidate how the PMCo and/or MA process sexual odors, this dissertation addressed the following research questions: (1) Is the PMCo required for the expression of either opposite-sex odor preferences or male copulatory behavior? (2) Are functional interactions between MeA and MePD required for the expression of opposite-sex odor preferences? (3) How do MeA and MePD regulate odor responses within the MePD and MeA, respectively? (4) Are odor and/or hormone cues conveyed directly between MeA and MePD? Together, these experiments provide a comprehensive analysis of the functional and neuroanatomical substrates by which the brain processes sexual odors and generates appropriate behavioral responses to these stimuli. copulatory behavior odor preference olfaction hamster medial amygdala posteromedial cortical amygdala Neuroscience and Neurobiology
756	Dissociated Functional Pathways for Appetitive and Consummatory Reproductive Behaviors in Male Syrian Hamsters (Mesocricetus auratus) Been, Laura E 21 November 2011 (has links) In many species, including Syrian hamsters, male reproductive behavior depends on the perception of odor cues from conspecifics in the environment. Volatile odor cues are processed primarily by the main olfactory system, whereas non-volatile cues are processed primarily by the accessory olfactory system. Together, these two chemosensory systems mediate appetitive reproductive behaviors, such as attraction to female odors, and consummatory reproductive behaviors, such as copulation, in male Syrian hamsters. Main and accessory olfactory information are first integrated in the medial amygdala (MA), a limbic nucleus that is critical for the expression of reproductive behaviors. MA is densely interconnected with other ventral forebrain nuclei that receive chemosensory information and are sensitive to steroid hormones. Specifically, several lines of evidence suggest that MA may generate behavioral responses to socio-sexual odors via functional connections with the posterior bed nucleus of the stria terminalis (BNST) and medial preoptic area (MPOA). It is unknown, however, how these three nuclei act as functional circuit to adaptively regulate appetitive and consummatory reproductive behaviors. Therefore, the overarching goal of this dissertation was to determine how BNST and MPOA function, both uniquely and as a circuit with MA, to generate attraction to female odors and copulatory behaviors in male Syrian hamsters. We found that BNST is required for attraction to female odors, but not for copulation, in sexually-naïve males. In contrast, MPOA is required for both attraction to female odors and for copulation in sexually-naïve males. Surprisingly, prior sexual experience mitigated the requirement of BNST and MPOA for these behaviors. Next, we found that MA preferentially transmits female odor information to BNST and to MPOA, whereas BNST relays female and male odor information equivalently to MPOA. Finally, we found that the functional connections between MA and BNST are required for attraction to female odors but not for copulation, whereas the functional connections between MA and MPOA are required for copulation but not for attraction to female odors. Ultimately, these data may uncover a fundamental mechanism by which this ventral forebrain circuit regulates appetitive and consummatory reproductive behaviors across many species and modalities. Medial amygdala Bed nucleus of the stria terminalis Medial preoptic area Odor preference Copulation Pheromone Neuroscience and Neurobiology
757	Automated microfluidic screening and patterned illumination for investigations in Caenorhabditis elegans neuroscience Stirman, Jeffrey Neil 16 December 2011 (has links) The field of neuroscience has recently seen optogenetics emerge as a highly utilized and powerful method of non-invasive neural activation and inhibition. This thesis seeks to enhance the optogenetic toolbox through the design, construction, and evaluation of a number of hardware and software modules for research in Caenorhabditis elegans neuroscience. In the first aim, we combine optogenetics, microfluidics, and automated image processing, to create a system capable of high-throughput analysis of synaptic function. In the second aim, we develop a multi-modal illumination system for the manipulation of optogenetic reagents. The system is capable of multi-spectral illumination in definable patterns, with the ability to dynamically alter the intensity, color, and shape of the illumination. The illumination system is controlled by a set of software programs introduced in aim three, and is demonstrated through a set of experiments in aim four where we selectively activate and inhibit specific neural nodes expressing optogenetic reagents in freely moving C. elegans. With the ability to target specific nodes in a freely moving animal, we can correlate specific neural states to behaviors allowing for the dissection of neural circuits. Taken together, the developed technologies for optogenetic researchers will allow for experimentation with previously unattainable speed, precision and flexibility. Microfluidics Neuroscience Illumination Channelrhodopsin-2 Optogenetics C. elegans Caenorhabditis elegans Neurosciences Neural circuitry Neural networks (Neurobiology)
758	Quantification of Alzheimer DiseaseAmyloid β Peptide 43 in Human BrainWith a Newly Developed Enzyme-LinkedImmunosorbent Assay (ELISA) Nicklagård, Erik January 2011 (has links) A 20 weeks project at Karolinska Institutet (KI), Huddinge, Sweden is in this master thesis summarized. Alzheimer’s disease is the most common form of dementia in the world. One of the pathological hallmarks seen in AD patients consists of amyloid plaques assembled of beta amyloid (Aβ) peptide aggregates. A lot of research has been done on Aβ40 and Aβ42 but not on the longer variant with 43 residues. An earlier study by Welander et al, quantified the Aβ43 peptide from amyloid plaque cores with high-performance liquid chromatography coupled to mass-spectrometry (HPLC-MS/MS)1. Here, I present the initial development of an enzyme-linked immunosorbent assay (ELISA) with the goal to quantify Aβ43 peptides in soluble fractions of human brain tissue. An ELISA method with the possibility to quantify Aβ43 peptides from cerebral spinal fluid might have the prospect to serve as a diagnostic tool for AD in the future. Commercial ELISA kits coated with antibodies against all Aβ species was not suitable for detecting Aβ43 in soluble brain tissue from human AD patients. This is due to the high amount of Aβ40 (and in some extent Aβ42) in the samples, which will bind to the same epitope as Aβ43 on the capturing antibody. These shorter Aβ species will be in excess and bind to the capturing antibody thereby ousting Aβ43 from binding in. A better way for quantifying Aβ43 with ELISA might instead be to coat a polystyrene plate with α-Aβ43 antibodies, which are c-terminal specific to Aβ43. This will abolish the competition between the different Aβ species and function as an immunoprecipitation of unwanted species. This yielded adequate quantification of Aβ43 (2.64 pM) from tris-buffer saline (TBS) fractions from a human brain sample from AD. Alzheimer amyloid beta 43 Alzheimer's disease ELISA Erik Nicklagård Neurobiology Neurobiologi Biochemistry Biokemi
759	Forebrain Acetylcholine in Action: Dynamic Activities and Modulation on Target Areas Zhang, Hao January 2009 (has links) <p>Forebrain cholinergic projection systems innervate the entire cortex and hippocampus. These cholinergic systems are involved in a wide range of cognitive and behavioral functions, including learning and memory, attention, and sleep-waking modulation. However, the <italic>in vivo</italic> physiological mechanisms of cholinergic functions, particularly their fast dynamics and the consequent modulation on the hippocampus and cortex, are not well understood. In this dissertation, I investigated these issues using a number of convergent approaches.</p><p> First, to study fast acetylcholine (ACh) dynamics and its interaction with field potential theta oscillations, I developed a novel technique to acquire second-by-second electrophysiological and neurochemical information simultaneously with amperometry. Using this technique on anesthetized rats, I discovered for the first time the tight <italic>in vivo</italic> coupling between phasic ACh release and theta oscillations on fine spatiotemporal scales. In addition, with electrophysiological recording, putative cholinergic neurons in medial setpal area (MS) were found with firing rate dynamics matching the phasic ACh release. </p><p> Second, to further elucidate the dynamic activities and physiological functions of cholinergic neurons, putative cholinergic MS neurons were identified in behaving rats. These neurons had much higher firing rates during rapid-eye-movement (REM) sleep, and brief responses to auditory stimuli. Interestingly, their firing promoted theta/gamma oscillations, or small-amplitude irregular activities (SIA) in a state-dependent manner. These results suggest that putative MS cholinergic neurons may be a generalized hippocampal activation/arousal network. </p><p> Third, I investigated the hypothesis that ACh enhances cortical and hippocampal immediate-early gene (IEG) expression induced by novel sensory experience. Cholinergic transmission was manipulated with pharmacology or lesion. The resultant cholinergic impairment suppressed the induction of <italic>arc</italic>, a representative IEG, suggesting that ACh promotes IEG induction. </p><p> In conclusion, my results have revealed that the firing of putative cholinergic neurons promotes hippocampal activation, and the consequent phasic ACh release is tightly coupled to theta oscillations. These fast cholinergic activities may provide exceptional opportunities to dynamically modulate neural activity and plasticity on much finer temporal scales than traditionally assumed. By the subsequent promotion of IEG induction, ACh may further substantiate its function in neural plasticity and memory consolidation.</p> / Dissertation Neurobiology acetylcholine amperometry hippocampus immediate early gene (IEG) medial septum (MS) theta oscillations
760	Putative Role of Connectivity in the Generation of Spontaneous Bursting Activity in an Excitatory Neuron Population Shao, Jie 12 July 2004 (has links) Population-wide synchronized rhythmic bursts of electrical activity are present in a variety of neural circuits. The proposed general mechanisms for rhythmogenesis are often attributed to intrinsic and synaptic properties. For example, the recurrent excitation through excitatory synaptic connections determines burst initiation, and the slower kinetics of ionic currents or synaptic depression results in burst termination. In such theories, a slow recovery process is essential for the slow dynamics associated with bursting. This thesis presents a new hypothesis that depends on the connectivity pattern among neurons rather than a slow kinetic process to achieve the network-wide bursting. The thesis begins with an introduction of bursts of electrical activity in a purely excitatory neural network and existing theories explaining this phenomenon. It then covers the small-world approach, which is applied to modify the network structure in the simulation, and the Morris-Lecar (ML) neuron model, which is used as the component cells in the network. Simulation results of the dependence of bursting activity on network connectivity, as well as the inherent network properties explaining this dependence are described. This work shows that the network-wide bursting activity emerges in the small-world network regime but not in the regular or random networks, and this small-world bursting primarily results from the uniform random distribution of long-range connections in the network, as well as the unique dynamics in the ML model. Both attributes foster progressive synchronization in firing activity throughout the network during a burst, and this synchronization may terminate a burst in the absence of an obvious slow recovery process. The thesis concludes with possible future work. Spontaneous bursting activity Small-world connectivity pattern Excitatory neural networks Neural networks (Neurobiology) Neural circuitry

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