Global ETD Search

31	Dlx homeobox genes and their role in interneuronal differentiation and migration in the developing forebrain. Le, Trung Ngoc 12 April 2010 (has links) Understanding the specificity of homeobox genes has been hampered by the lack of verified direct transcriptional targets. The Dlx family of homeobox genes is expressed in the ganglionic eminences of the developing forebrain. Dlx1/Dlx2 double knockout (DKO) mice die at birth. Phenotypic analyses demonstrate abnormal development of the basal telencephalon, including defects in neuronal differentiation in the basal ganglia, reduced expression of GABA in the basal telencephalon, and loss of migration of GABAergic inhibitory interneurons to the neocortex. The mechanisms underlying DLX protein regulation of differentiation and migration of GABAergic interneurons are poorly defined. We have successfully applied chromatin immunoprecipitation to identify potential direct transcriptional targets of DLX homeoproteins from embryonic tissues in vivo. Reporter gene assays demonstrated the transcriptional significance of the binding of DLX proteins to different downstream regulatory elements, which were confirmed in vitro by electrophoretic mobility shift assay and site-directed mutagenesis. The functional significance of DLX mediated transcriptional regulation of these targets was further elaborated through several series of loss-of-function assays including gene expression in Dlx1/2 knockout embryonic forebrain tissues, as well as siRNA or Lentiviral mediated shRNA knockdown experiments with primary forebrain cultures. Quantitative analysis of the regulatory effect of Dlx genes on various forebrain markers of differentiation and migration was performed using in situ hybridization, high-performance liquid chromatography coupled with cell counting. Neuronal migration was assessed by forebrain explants and diI labelling of migratory cells from ganglionic eminence to neocortex. We have demonstrated that DLX1 and DLX2 can transcriptionally activate (Gad1, Gad2) or repress (Nrp2) different downstream targets. In the Dlx1/2 DKO, reduction of GABA expression and failure of GABAergic interneurons to migrate to the neocortex is partly due to loss or aberrant expression of these DLX downstream targets. In the triple Dlx1/2; Nrp2KO, partial restoration of tangential migration of GABAergic interneurons from basal ganglia to the neocortex was successfully established signifying the importance of DLX regulation of Semaphorin-Neuropilin signalling during forebrain development. neurodevelopment homeobox genes differentiation migration dlx forebrain neuropilin ChIP Gad GABA interneuron tangential striatum ganglionic eminence
32	Dlx homeobox genes and their role in interneuronal differentiation and migration in the developing forebrain. Le, Trung Ngoc 12 April 2010 (has links) Understanding the specificity of homeobox genes has been hampered by the lack of verified direct transcriptional targets. The Dlx family of homeobox genes is expressed in the ganglionic eminences of the developing forebrain. Dlx1/Dlx2 double knockout (DKO) mice die at birth. Phenotypic analyses demonstrate abnormal development of the basal telencephalon, including defects in neuronal differentiation in the basal ganglia, reduced expression of GABA in the basal telencephalon, and loss of migration of GABAergic inhibitory interneurons to the neocortex. The mechanisms underlying DLX protein regulation of differentiation and migration of GABAergic interneurons are poorly defined. We have successfully applied chromatin immunoprecipitation to identify potential direct transcriptional targets of DLX homeoproteins from embryonic tissues in vivo. Reporter gene assays demonstrated the transcriptional significance of the binding of DLX proteins to different downstream regulatory elements, which were confirmed in vitro by electrophoretic mobility shift assay and site-directed mutagenesis. The functional significance of DLX mediated transcriptional regulation of these targets was further elaborated through several series of loss-of-function assays including gene expression in Dlx1/2 knockout embryonic forebrain tissues, as well as siRNA or Lentiviral mediated shRNA knockdown experiments with primary forebrain cultures. Quantitative analysis of the regulatory effect of Dlx genes on various forebrain markers of differentiation and migration was performed using in situ hybridization, high-performance liquid chromatography coupled with cell counting. Neuronal migration was assessed by forebrain explants and diI labelling of migratory cells from ganglionic eminence to neocortex. We have demonstrated that DLX1 and DLX2 can transcriptionally activate (Gad1, Gad2) or repress (Nrp2) different downstream targets. In the Dlx1/2 DKO, reduction of GABA expression and failure of GABAergic interneurons to migrate to the neocortex is partly due to loss or aberrant expression of these DLX downstream targets. In the triple Dlx1/2; Nrp2KO, partial restoration of tangential migration of GABAergic interneurons from basal ganglia to the neocortex was successfully established signifying the importance of DLX regulation of Semaphorin-Neuropilin signalling during forebrain development. neurodevelopment homeobox genes differentiation migration dlx forebrain neuropilin ChIP Gad GABA interneuron tangential striatum ganglionic eminence
33	Neuronal Networks of Movement : Slc10a4 as a Modulator & Dmrt3 as a Gait-keeper Larhammar, Martin January 2014 (has links) Nerve cells are organized into complex networks that comprise the building blocks of our nervous system. Neurons communicate by transmitting messenger molecules released from synaptic vesicles. Alterations in neuronal circuitry and synaptic signaling contribute to a wide range of neurological conditions, often with consequences for movement. Intrinsic neuronal networks in the spinal cord serve to coordinate vital rhythmic motor functions. In spite of extensive efforts to address the organization of these neural circuits, much remains to be revealed regarding the identity and function of specific interneuron cell types and how neuromodulation tune network activity. In this thesis, two novel genes initially identified as markers for spinal neuronal populations were investigated: Slc10a4 and Dmrt3. The orphan transporter SLC10A4 was found to be expressed on synaptic vesicles of the cholinergic system, including motor neurons, as well as in the monoaminergic system, including dopaminergic, serotonergic and noradrenergic nuclei. Thus, it constitutes a novel molecular denominator shared by these classic neuromodulatory systems. SLC10A4 was found to influence vesicular transport of dopamine and affect neuronal release and reuptake efficiency in the striatum. Mice lacking Slc10a4 displayed impaired monoamine homeostasis and were hypersensitive to the drugs amphetamine and tranylcypromine. These findings demonstrate that SLC10A4 is capable of modulating the modulatory systems of the brain with potential clinical relevance for neurological and mental disorders. The transcription factor encoded by Dmrt3 was found to be expressed in a population of inhibitory commissural interneurons originating from the dorsal interneuron 6 (dI6) domain in the spinal cord. In parallel, a genome-wide association study revealed that a non-sense mutation in horse DMRT3 is permissive for the ability to perform pace among other alternate gaits. Further analysis of Dmrt3 null mutant mice showed that Dmrt3 has a central role for spinal neuronal network development with consequences for locomotor behavior. The dI6 class has been suggested to take part in motor circuits but remains one of the least studied classes due to lack of molecular markers. To further investigate the Dmrt3-derived neurons, and the dI6 population in general, a Dmrt3Cre mouse line was generated which allowed for characterization on the molecular, cellular and behavioral level. It was found that Dmrt3 neurons synapse onto motor neurons, receive extensive synaptic inputs from various neuronal sources and are rhythmically active during fictive locomotion. Furthermore, silencing of Dmrt3 neurons in Dmrt3Cre;Viaatlx/lx mice led to impaired motor coordination and alterations in gait, together demonstrating the importance of this neuronal population in the control of movement. Synaptic vesicle transporter Neuromodulation Dopamine Central Pattern Generator Locomotion Gait Horse Mouse Commissural Inhibitory Interneuron
34	Caracterização morfológica e celular da zona subventricular e da corrente rostral migratória em encéfalos de fetos caninos / Morphological and cellular characterization of subventricular zone and rostral migratory stream in brains of canine fetuses Dailiany Orechio 03 June 2016 (has links) Precursores neurais originados na zona subventricular (ZSV) de algumas espécies animais possuem uma rota de migração neuronal destinada ao bulbo olfatório principal (BOP), onde os neuroblastos migrantes se diferenciam em interneurônios. Esta corrente migratória é mantida na idade adulta. A compreensão de como se organiza na idade fetal é essencial para a compreensão geral e estabelecimento de novas terapias celulares. O objetivo deste estudo é caracterizar a composição celular e organização morfológica da ZSV e da corrente rostral migratória (CRM) em encéfalos de fetos caninos. A ZSV, CRM e BOP foram obtidos de fetos caninos de aproximadamente 57 dias de idade gestacional. O tecido foi analisado através de coloração de Nissl, método de imunohistoquímica de dupla marcação com duplacortina (DCX), fator de transcrição SOX2, proteína glial fibrilar ácida (GFAP), calbindina (CALB), calretinina (CALR) e tirosina-hidroxilase (TH). Foram feitas a análise relativa da expressão da imunorreatividade e análise quantitativa de colocalização celular, além do método de microscopia eletrônica de transmissão. Os resultados mostram que a ZSV dorsal possui células imunorreativas (ir) para o DCX ao longo da parede ventricular, dispostas tangencialmente e fileiras de células SOX2-ir foram encontradas na mesma orientação. A imunorreatividade de GFAP foi mais forte na ZSV dorsal e as células possuem fibras dirigidas tangencialmente adjacentes ao ventrículo lateral e fibras orientadas radialmente em direção ao córtex. A CRM de feto de cão tem início na ZSV anterior e segue caudalmente ao redor da cabeça do núcleo caudado e desce na vertical até se curvar rostralmente em direção ao BOP onde termina na camada de células granulares (CCG). A CRM tem aparência homogênea e densa e possui células positivas para o DCX nas porções iniciais e para SOX2 e GFAP por toda a extensão. Não houve células positivas para CALB, CALR e TH em nenhuma região da ZSV e CRM. No BOP, os resultados mostraram que a camada glomerular (CG) possui células imunorreativas a CALR, TH, SOX2 e GFAP. Na camada plexiforme externa (CPE) houve células imunorreativas a CALB, CALR, SOX2 e GFAP e na CCG, houve células imunorreativas a CALR, SOX2 e GFAP. Na análise de colocalização, foram encontrados na CG neurônios CALR que colocalizam com células SOX2 e uma baixa colocalização de neurônios TH e células SOX2. Na CPE, foi observado um baixo número de colocalização de neurônios CALR e CALB e na CCG, as células SOX2 colocalizam com os neurônios CALR. As conclusões mostram que o feto de cão possui uma CRM em direção BOP, com imunorreatividade celular para DCX, SOX2 e GFAP na ZSV e CRM e para CALB, CALR, TH, SOX2 e GFAP nas principais camadas do BOP / Neural precursors originated in the subventricular zone (SVZ) of some animal species have a migration route destined for main olfactory bulb (MOB), where migrants neuroblasts differentiate into olfactory interneurons. This migratory stream is maintained in adulthood. Understanding how it is organized in fetal age is essential for general understanding and establishment of new cell therapies. The aim of this study is characterize the cellular composition and morphological organization of the SVZ and rostral migratory stream (RMS) of brains of canine fetuses. The SVZ, RMS and MOB was obtained from canine fetuses of the approximately 57 gestacional days-old. The tissue was analyzed by Nissl staining and by immunohistochemical methods for double labelling with doublecortin (DCX), transcription factor SOX2, glial fibrillary acid protein (GFAP), calbindin (CALB), calretinin (CALR) and tyrosinehydroxylase (TH). Semiquantitative analysis of immunoreactivity and quantitative analysis of colocalization were realized, besides ultrastructural analysis by electron microscopy. The results show that in dorsal SVZ, DCX immunoreactive cells were found along the ventricular wall, arranged tangentially and lines of SOX2 cells were also found in the same orientation. The GFAP immunostaining is stronger in dorsal SVZ with tangentially directed fibers near the lateral ventricle and radially oriented fibers toward the cortex. The RMS of dog fetus begins at anterior SVZ and follows caudally around the head of the caudate nucleus and vertically descends to bend rostrally into the MOB, where it ends in the granular cell layer (GCL).The RMS have SOX2 positive cells on entire length, showing a homogeneous appearance and high cell density. There is no positive CALB cells or CALR in any region of the SVZ and RMS. The results of the MOB show that the glomerular layer (GL) there were cells immunoreactive to CALR, TH, SOX2 and GFAP. In the external plexiforme layer (EPL) there were immunoreactive cells for CALR, CALB, SOX2 and GFAP and, the GCL, the prevalence is higher for CALR neurons, SOX2-ir and GFAP-ir cells. In colocalization analysis, they were found a some CALR positive neurons in GL that colabeled with SOX2 cells and a low colocalization of TH neurons and SOX2 cells. In EPL, was observed a low colocalization number of CALR and CALB neurons and in GCL, SOX2 cells colabeled with CALR neurons. The conclusions show that the dog fetus has a RMS directed to the MOB, with cellular immunoreactivity for DCX, SOX2 and GFAP in the ZSV and RMS and cellular immunoreactivity for SOX2 CALB, CALR, TH and GFAP in main olfactory bulb layers Bulbo olfatório Célula-tronco Interneurônio Neurogênese Interneuron Neurogenesis Olfactory bulb Stem cell
35	Role of chromatin remodelling BAF complex in fate regulation of ventral neural stem cells in the developing telencephalon Abbas, Eman Ahmed Ahmed Mohamed 14 September 2021 (has links) No description available. 570 Chromatin remodelling BAF complex Brain development Developing telencephalon Oligodendrocyte Interneuron Biologie (PPN619462639)
36	Aerobic Exercise Alters Opioid Receptors Following Chronic Alcohol Exposure Brundage, James N. 03 August 2020 (has links) Opioid receptors have been a target of pharmacological manipulation in alcohol use disorder (AUD) recovery protocols for many years. Aerobic exercise, a common adjunct in AUD recovery, is known to modulate opioid receptors (ORs) both during both acute and long term exposure. The three subtypes of ORs: mu (MOR), delta (DOR), and kappa (KOR) are all expressed on neurons in the mesocorticolimbic circuitry. Kappa-opioid receptors are expressed directly on dopamine (DA) neuron terminals in the nucleus accumbens (NAc). Mu and Delta ORs are expressed on cholinergic interneurons (CINs) and GABA neurons in the NAc. In alcohol dependent rodents, KORs are hypersensitized. It is theorized that this hypersensitization contributes to EtOH seeking behavior. In contrast, aerobic exercise desensitizes the KORs. Given the high degree of pharmacological overlap between opioid receptors, it is also hypothesized that EtOH and aerobic exercise may have effects on MORs and DORs as well. Here, it is investigated whether a routine of voluntary aerobic exercise decreases EtOH induced changes to KOR modulation of dopamine (DA) release in the nucleus accumbens (NAc) along with possible mechanisms through which this might occur. The responsiveness of MORs and DORs in EtOH dependence, and how aerobic exercise modulates those effects is also investigated. Exercise attenuated EtOH induced hypersensitization of KORs in the NAc. Exercise decreases expression of KORs, which may account for the changes in KOR sensitization. The MOR agonist DAMGO decreased DA reuptake ex vivo, but not signal amplitude while DOR agonist DPDPE had no effect on either reuptake or signal amplitude. Overall, dependent animals that were allowed to exercise, consumed less EtOH in a drinking in the dark model. These data suggest that exercise is a useful adjunct to AUD recovery protocols, and that its effects are likely mediated by KORs. The findings related to MORs and DORs suggest that MORs, but not DORs, may act through acetyl choline receptors to modulate DA reuptake in the NAc, however much more work is needed to characterize this effect. alcohol aerobic exercise opioid receptor cholinergic interneuron nucleus accumbens Family, Life Course, and Society
37	Identified Interneurons of Dorsal Hippocampal Area CA1 Show Different Theta-Contingent Response Profiles During Classical Eyeblink Conditioning Cicchese, Joseph J. 08 May 2013 (has links) No description available. Psychobiology Neurobiology eyeblink classical conditioning hippocampus theta electrophysiology single-unit interneuron brain-computer interface
38	The Role of Pax3 in Neuronal Differentiation of the Ophthalmic (OpV) Trigeminal Placode and Neural Tube during Chicken Embryonic Development Bradshaw, James R. 16 March 2006 (has links) (PDF) Pax3 has been used as a valuable marker in research aimed at understanding tissue interactions involved in trigeminal ophthalmic (opV) placode development. While Pax3 expression coincides with opV neuron specification, the function of Pax3 in these cells has not previously been investigated. Splotch mutant mice (which lack Pax3) have a reduced trigeminal ganglion; however it is not clear whether this reduction is due to neural crest or placode cells. We have used electroporation in the chick model system to block or ectopically express Pax3 at key times in opV placode development. Using several markers of placode cell differentiation, we have determined the experimental effects manipulating Pax3. Blocking placodal Pax3 with gene specific morpholinos resulted in a loss of migratory placode cells, and a downregulation of all opV placode markers in targeted cells. Ectopic expression of Pax3, either within the placode domain or in adjacent cranial ectoderm, resulted in the upregulation of some but not all placode markers. We conclude that opV placodal Pax3 expression is required for normal placode cell development, and hypothesize that its expression must be tightly regulated in order for placode cells to fully differentiate. The precise role of Pax3 and Pax7 in the restriction and differentiation of dorsal interneuron progenitors has been difficult to assess due to the many additional factors involved in specification and patterning of the neural tube. We have used electroporation in the chick model system to ectopically express Pax3 and Pax7 unilaterally in the neural tube. Using several markers for differentiation of ventral and dorsal neuronal progenitors, we have experimentally determined the effects of Pax3 and Pax7 ventrally and dorsally. Ectopic expression of these transcription factors in the ventral neural tube resulted in the loss of motorneurons. Though mis-expression did not qualitatively affect commissural neurons as assayed by neurofilament staining, ectopic expression of Pax3 and Pax7 in the dorsal neural tube stopped dorsal interneuron progenitors from differentiating. We conclude that Pax3 and Pax7 expression is sufficient to restrict ventral neuron identity. We also hypothesize that downregulation of these transcription factors in the dorsal neural tube is required for normal dorsal interneuron differentiation. Ophthalmic Placode Neural Tube Pax3 Sensory Neuron Dorsal Interneuron Cell and Developmental Biology Physiology
39	Information processing in the Striatum : a computational study Hjorth, Johannes January 2006 (has links) The basal ganglia form an important structure centrally placed in the brain. They receive input from motor, associative and limbic areas, and produce output mainly to the thalamus and the brain stem. The basal ganglia have been implied in cognitive and motor functions. One way to understand the basal ganglia is to take a look at the diseases that affect them. Both Parkinson's disease and Huntington's disease with their motor problems are results of malfunctioning basal ganglia. There are also indications that these diseases affect cognitive functions. Drug addiction is another example that involves this structure, which is also important for motivation and selection of behaviour. In this licentiate thesis I am laying the groundwork for a detailed model of the striatum, which is the input stage of the basal ganglia. The striatum receives glutamatergic input from the cortex and thalamus, as well as dopaminergic input from substantia nigra. The majority of the neurons in the striatum are medium spiny (MS) projection neurons that project mainly to globus pallidus but also to other neurons in the striatum and to both dopamine producing and GABAergic neurons in substantia nigra. In addition to the MS neurons there are fast spiking (FS) interneurons that are in a position to regulate the firing of the MS neurons. These FS neurons are few, but connected into large networks through electrical synapses that could synchronise their effect. By forming strong inhibitory synapses on the MS neurons the FS neurons have a powerful influence on the striatal output. The inhibitory output of the basal ganglia on the thalamus is believed to keep prepared motor commands on hold, but once one of them is disinhibited, then the selected motor command is executed. This disinhibition is initiated in the striatum by the MS neurons. Both MS and FS neurons are active during so called up-states, which are periods of elevated cortical input to striatum. Here I have studied the FS neurons and their ability to detect such up-states. This is important because FS neurons can delay spikes in MS neurons and the time between up-state onset and the first spike in the MS neurons is correlated with the amount of calcium entering the MS neuron, which in turn might have implications for plasticity and learning of new behaviours. The effect of different combinations of electrical couplings between two FS neurons has been tested, where the location, number and strength of these gap junctions have been varied. I studied both the ability of the FS neurons to fire action potentials during the up-state, and the synchronisation between neighbouring FS neurons due to electrical coupling. I found that both proximal and distal gap junctions synchronised the firing, but the distal gap junctions did not have the same temporal precision. The ability of the FS neurons to detect an up-state was affected by whether the neighbouring FS neuron also received up-state input or not. This effect was more pronounced for distal gap junctions than proximal ones, due to a stronger shunting effect of distal gap junctions when the dendrites were synaptically activated. We have also performed initial stochastic simulations of the Ca2+-calmodulin-dependent protein kinase II (CaMKII). The purpose here is to build the knowledge as well as the tools necessary for biochemical simulations of intracellular processes that are important for plasticity in the MS neurons. The simulated biochemical pathways will then be integrated into an existing model of a full MS neuron. Another venue to explore is to build striatal network models consisting of MS and FS neurons and using experimental data of the striatal microcircuitry. With these different approaches we will improve our understanding of striatal information processing. / QC 20101116 striatum fast spiking interneuron gap junctions synchronisation up-state detection CaMKII mathematical modelling Neurosciences Neurovetenskaper
40	An Optogenetic Approach to Induce Seizure Suppression Ladas, Thomas P. 21 February 2014 (has links) No description available. Biomedical Engineering Neurosciences optogenetics hippocampus epilepsy 4-AP LFS HFS seizure suppression GABA interneuron

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