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Aging-related changes in connectivity of the primary motor cortexJanuary 2019 (has links)
archives@tulane.edu / As the average life expectancy continues to increase globally, the scientific community must meet the parallel challenge of extending the healthy life expectancy of the ever-growing aged population. Aging-related decline in motor control is a crucial aspect of this challenge because it diminishes independence and hinders daily living abilities, leading to greater disability burden on the remaining population. While peripheral nervous and motor systems are certainly involved in this impairment, attention to those structures has come at the expense of more complete understanding of motor control by the aged central nervous system. This dissertation expands our knowledge of this area with a specific focus on the cortex. First, this has been achieved by identifying differences in steady-state structural plasticity in the primary motor cortex (M1) of young and aged mice using chronic in vivo imaging of dendritic spines, the sites of excitatory input to pyramidal neurons that process the bulk of outgoing information from this brain area. These results indicate that at baseline conditions the dendritic spines of the aged M1 are subject to increased turnover, including formation and stabilization, while enduring decreased rates of long-term survival. Secondly, ensuing work combined in vivo imaging with motor skill training and revealed that, while unsuccessful at causing learning-induced structural plasticity of dendritic spines, motor training results in a muted learning-induced structural plasticity response by the en passant boutons (EPBs) of L2/3 parvalbumin-expressing interneurons in the aged M1. These experiments also uncovered a baseline decrease in EPB density and increase in EPB size on the aged axon. Lastly, mesoscale, awake imaging equipment was designed and built to enable future study of brain-wide engagement of various cortical areas during motor learning and performance. The product of this dissertation is a greater understanding of the impact of normal aging on the M1 at the cellular and synaptic level outside of and during motor skill practice, and it also provides an avenue for further study of larger scale changes in cortical connectivity with aging. / 1 / Andrew Davidson
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Regulation of filopodia dynamics is critical for proper synapse formationGauthier-Campbell, Catherine 05 1900 (has links)
Despite the importance of proper synaptogenesis in the CNS, the molecular mechanisms that regulate the formation and development of synapses remain poorly understood. Indeed, the mechanisms through which initial synaptic contacts are established and modified during synaptogenesis have not been fully determined and a precise understanding of these mechanisms may shed light on synaptic development, plasticity and many CNS developmental diseases. The development and formation of spiny synapses has been thought to occur via filopodia shortening followed by the recruitment of proper postsynaptic proteins, however the precise function of filopodia remains controversial. Thus the goal of this study was to investigate the dynamics of dendritic filopodia and determine their role in the development of synaptic contacts.
We initially define and characterize short lipidated motifs that are sufficient to induce process outgrowth. Indeed, the palmitoylated protein motifs of GAP-43 and paralemmin are sufficient to induce filopodial extensions in heterologous cells and to increase the number of filopodia and dendritic branches in neurons. We showed that the morphological changes induced by these FIMs (filopodia inducing motifs) require on-going protein palmitoylation and are modulated by a specific GTPase, Cdc42, that regulates actin dynamics. We also show that their function is palmitoylation dependent and is dynamically regulated by reversible protein palmitoylation. Significantly, our work suggests a general role for those palmitoylated motifs in the development of structures important for synapse formation and maturation.
We combined several approaches to monitor the formation and development of filopodia. We show that filopodia continuously explore the environment and probe for appropriate contacts with presynaptic partners. We find that shortly after establishing a contact with axons, filopodia induce the recruitment of presynaptic elements. Remarkably, we find that expression of acylated motifs or the constitutively active form of cdc-42 enhances filopodia number and motility, but reduces the recruitment of synaptophysin positive presynaptic elements and the probability of forming stable axo-dendritic contacts. We provide evidence for the rapid transformation of filopodia to spines within hours of imaging live neurons and reveal potential molecules that accelerate this process.
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Regulation of filopodia dynamics is critical for proper synapse formationGauthier-Campbell, Catherine 05 1900 (has links)
Despite the importance of proper synaptogenesis in the CNS, the molecular mechanisms that regulate the formation and development of synapses remain poorly understood. Indeed, the mechanisms through which initial synaptic contacts are established and modified during synaptogenesis have not been fully determined and a precise understanding of these mechanisms may shed light on synaptic development, plasticity and many CNS developmental diseases. The development and formation of spiny synapses has been thought to occur via filopodia shortening followed by the recruitment of proper postsynaptic proteins, however the precise function of filopodia remains controversial. Thus the goal of this study was to investigate the dynamics of dendritic filopodia and determine their role in the development of synaptic contacts.
We initially define and characterize short lipidated motifs that are sufficient to induce process outgrowth. Indeed, the palmitoylated protein motifs of GAP-43 and paralemmin are sufficient to induce filopodial extensions in heterologous cells and to increase the number of filopodia and dendritic branches in neurons. We showed that the morphological changes induced by these FIMs (filopodia inducing motifs) require on-going protein palmitoylation and are modulated by a specific GTPase, Cdc42, that regulates actin dynamics. We also show that their function is palmitoylation dependent and is dynamically regulated by reversible protein palmitoylation. Significantly, our work suggests a general role for those palmitoylated motifs in the development of structures important for synapse formation and maturation.
We combined several approaches to monitor the formation and development of filopodia. We show that filopodia continuously explore the environment and probe for appropriate contacts with presynaptic partners. We find that shortly after establishing a contact with axons, filopodia induce the recruitment of presynaptic elements. Remarkably, we find that expression of acylated motifs or the constitutively active form of cdc-42 enhances filopodia number and motility, but reduces the recruitment of synaptophysin positive presynaptic elements and the probability of forming stable axo-dendritic contacts. We provide evidence for the rapid transformation of filopodia to spines within hours of imaging live neurons and reveal potential molecules that accelerate this process.
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Regulation of filopodia dynamics is critical for proper synapse formationGauthier-Campbell, Catherine 05 1900 (has links)
Despite the importance of proper synaptogenesis in the CNS, the molecular mechanisms that regulate the formation and development of synapses remain poorly understood. Indeed, the mechanisms through which initial synaptic contacts are established and modified during synaptogenesis have not been fully determined and a precise understanding of these mechanisms may shed light on synaptic development, plasticity and many CNS developmental diseases. The development and formation of spiny synapses has been thought to occur via filopodia shortening followed by the recruitment of proper postsynaptic proteins, however the precise function of filopodia remains controversial. Thus the goal of this study was to investigate the dynamics of dendritic filopodia and determine their role in the development of synaptic contacts.
We initially define and characterize short lipidated motifs that are sufficient to induce process outgrowth. Indeed, the palmitoylated protein motifs of GAP-43 and paralemmin are sufficient to induce filopodial extensions in heterologous cells and to increase the number of filopodia and dendritic branches in neurons. We showed that the morphological changes induced by these FIMs (filopodia inducing motifs) require on-going protein palmitoylation and are modulated by a specific GTPase, Cdc42, that regulates actin dynamics. We also show that their function is palmitoylation dependent and is dynamically regulated by reversible protein palmitoylation. Significantly, our work suggests a general role for those palmitoylated motifs in the development of structures important for synapse formation and maturation.
We combined several approaches to monitor the formation and development of filopodia. We show that filopodia continuously explore the environment and probe for appropriate contacts with presynaptic partners. We find that shortly after establishing a contact with axons, filopodia induce the recruitment of presynaptic elements. Remarkably, we find that expression of acylated motifs or the constitutively active form of cdc-42 enhances filopodia number and motility, but reduces the recruitment of synaptophysin positive presynaptic elements and the probability of forming stable axo-dendritic contacts. We provide evidence for the rapid transformation of filopodia to spines within hours of imaging live neurons and reveal potential molecules that accelerate this process. / Medicine, Faculty of / Graduate
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Phosphorylation State Modulates the Interaction between Spinophilin and Neurofilament MediumHiday, Andrew C. 07 April 2015 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / A histological marker of Parkinson’s disease (PD) is the loss of synapses located on striatal medium spiny neurons (MSNs) as a result of dopaminergic nigral cell depletion. The dendritic spines that give MSNs their name have a well-characterized structure and are the main regions of post-synaptic input. It has been shown that spines have altered functionality and morphology in many neurodegenerative diseases. Spine morphology, and potentially function, is dictated by an array of structural proteins and their associations with other proteins in a region dubbed the post-synaptic density (PSD). Spinophilin and neurofilament medium (NF-M) are two proteins that are enriched in the PSD and have potential implications in PD. Interestingly, preliminary data show that there is a decrease in the NF-M-spinophilin interaction in animal models of PD. Here it is shown that these two proteins interact in brain tissue and when overexpressed in a mammalian cell system. Moreover, we have begun to determine mechanisms that regulate this interaction.
It is known that there is a misregulation of protein phosphatases and kinases in many neurodegenerative diseases. Moreover, the phosphorylation state of a protein can
regulate its association with other proteins. Therefore, we hypothesize that the phosphorylation state of either protein affects the interaction between spinophilin and NF-M. Furthermore, we have conducted experiments utilizing protein phosphatases and kinases that are known to modulate the phosphorylation state of NF-M and/or spinophilin. Data show that both kinase and phosphatase activity and/or expression modulates the NF-M-spinophilin interaction in heterologous cell lines. Through the use of MS/MS analysis, we have begun to map specific phosphorylation sites that may play a role in regulating this interaction. Currently, we are elucidating the specific effects of these post-translational modifications on regulating the spinophilin-NF-M interaction. These data will enhance our knowledge of spinophilin’s interactions and how these interactions are altered in neurological disorders such as PD.
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Dendritic Spine Density Varies Between Unisensory and Multisensory Cortical RegionsBajwa, Moazzum 07 May 2010 (has links)
In the brain, the dendritic spine is a point of information exchange that extends the neuronal surface on which synapses occur, as well as facilitates and stabilizes those contacts. Furthermore, dendritic spines dynamically change in shape and number in response to a variety of factors. Dendritic spine numbers are reduced in mental retardation, enhanced during development, sensory enrichment or physical exercise, or fluctuate during the reproductive cycle. Thus, for a given neuron type, it might be expected that dendritic spine number might achieve a dynamic optimum. Indeed, many studies of spine density of pyramidal neurons in sensory cortex indicate that an average of ~1.4 spines/micron occurs is present (Briner et al., 2010). Most such studies examined dendritic spines from primary sensory areas which are dominated by inputs from a single sensory modality. However, there are a large number of neural regions that receive inputs from more than one sensory modality and it is hypothesized that spine density should increase to accommodate these additional inputs. To test this hypothesis, the present experiments used Golgi-Cox stained layer 2-3 pyramidal neurons from ferret primary somatosensory (S1) and auditory (A1) cortical regions, as well as from the higher-level rostral posterior parietal (PPr) and lateral rostral suprasylvian (LRSS) multisensory areas. Spine densities in S1 (avg 1.309 ± 0.247 spines/micron) and A1 (avg 1.343 ± 0.273 spines/micron) were measured to be significantly greater (p<0.05, t-test) than those observed in multisensory regions PPr (avg 1.242 ± 0.205 spines/micron) or LRSS (avg 1.099 ± 0.217 spines/micron). These results also indicate that spine densities are greater in primary (S1, A1) than in higher-level (PPr, LRSS) sensory areas. The functional consequences of such unexpected findings are discussed in light of potential biophysical differences between unisensory and multisensory neurons.
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Detailed morphological study of layer 2 and layer 3 pyramidal neurons in the anterior cingulate cortex of the rhesus monkeyWang, Jingyi 22 January 2016 (has links)
The anterior cingulate cortex (ACC) can influence emotional and motivational states in primates by its dense connections with many neocortical and subcortical regions. Pyramidal neurons serve as the basic building blocks of these neocortical circuits, which have been extensively studied in other brain regions, but their morphological and electrophysiological properties in the primate ACC are not well understood. In this study, we used whole-cell patch clamp and high-resolution laser scanning confocal microscopy to reveal the general electrophysiological properties and detailed morphological features of layer 2 and 3 pyramidal neurons in ACC (area 24/32) of the rhesus monkey. Neurons from both layers had similar passive membrane properties and action potential properties. Morphologically, dendrites of layer 3 ACC neurons were more complex than those of layer 2 neurons, by having dendrites with longer total dendritic lengths, more branch points and dendritic segments, spanning larger convex hull volumes. This difference in total dendritic morphology was mainly due to the apical dendrites. In contrast, the basal dendrites displayed mostly similar features between the two groups of neurons. However, while apical dendrites extend to the same layer (layer 1), the basal dendrites of layer 3 extended into deeper layers than layer 2 because of the difference in soma-pia distance. Thus, basal dendrites of the two groups of neurons receive different laminar inputs. Analysis of spines showed that more spines were found in neurons of layer 3 apical dendritic arbors than layer 2 neurons. However, the apical spine densities were similar between neurons in the two layers. Thus, while higher spine number suggests that layer 3 neurons receive more excitatory input than layer 2 neurons, the similar spine density suggests similar spatial and temporal summation of these inputs. The combined effects of increased number of excitatory input and higher dendritic complexity in layer 3 than in layer 2 ACC neurons suggest the additional information received by layer 3 neurons, especially in the apical dendrites, might undergo more complex integration.
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Cortical development & plasticity in the FMRP KO mouseChiang, Chih-Yuan January 2016 (has links)
Autism is one of the leading causes of human intellectual disability (ID). More than 1% of the human population has autism spectrum disorders (ASDs), and it has been estimated that over 50% of those with ASDs also have ID. Fragile X syndrome (FXS) is the most common inherited form of mental retardation and is the leading known genetic cause of autism, affecting approximately 1 in 4000 males and 1 in 8000 females. Approximately 30% of boys with FXS will be diagnosed with autism in their later lives. The cause of FXS is through an over-expansion of the CGG trinucleotide repeat located at the 5’ untranslated region of the FMR1 gene, leading to hypermethylation of the surrounding sequence and eventually partially or fully silencing of the gene. Therefore, the protein product of the gene, fragile X mental retardation protein (FMRP), is reduced or missing. As a single-gene disorder, FXS offers a scientifically tractable way to examine the underlying mechanism of the disease and also shed some light on understanding ASD and ID. The mouse model of FXS (Fmr1−/y mice) is widely accepted and used as a good model, offering good structural and face validity. Since a primary deficit of FXS is believed to be altered neuronal communication, in this thesis I examined white matter tract and dendritic spine abnormalities in the mouse model of FXS. Loss of FMRP does not alter the gross morphology of the white matter. However, recent brain imaging studies indicated that loss of FMRP could lead to some minute abnormalities in different major white matter tracts in the human brain. The gross white matter morphology and myelination was unaltered in the Fmr1−/y mice, however, a small but significant increase of axon diameter in the corpus callosum (CC) was found compared to wild-type (WT) controls. Our computation model suggested that the increase of axon diameter in the Fmr1−/y mice could lead to an increase of conduction velocity in these animals. One of the key phenotypes reported previously in the loss of FMRP is the increase of “immature” dendritic spines. The increase of long and thin spines was reported in several brain regions including the somatosensory cortex and visual cortex in both FXS patients and the mouse model of FXS. Although recent studies which employed state-of-the-art microscopy techniques suggested that only minute differences were noticed between the WT and Fmr1−/y mice. In agreement with previous findings, I found an increase of dendritic spine density in the visual cortex in the Fmr1−/y mice, and spine morphology was also different between the two genotypes. We found that the spine head diameter is significantly increased in the CA1 area of the apical dendrites of the Fmr1−/y mice compared to WT controls. Dendritic spine length is also significantly increased in the same region of the Fmr1−/y mice. However, apical spine head size does not alter between the two genotypes in the V1 region of the visual cortex, and spine length is significantly decreased in the Fmr1−/y mice compared to WT animals in this region. Lovastatin, a drug known as one of the 3-hydroxy-3-methyl-glutaryl-CoA (HMG-CoA) reductase inhibitors, functions as a modulator of the mitogen-activated protein kinases (MAPK) pathway through inhibiting Ras farnesylation, was used in an attempt to rescue the dendritic spine abnormalities in the Fmr1−/y mice. Mice lacking FMRP are susceptible to audiogenic seizure (AGS). Previous work has shown that 48 hr of lovastatin treatment reduced the incidence of AGS in the Fmr1−/y mice. However, chronic lovastatin treatment failed to rescue the spine density and morphology abnormalities in the Fmr1−/y mice. Mouse models are invaluable tools for modelling human diseases. However inter-strain differences have often confounded results between laboratories. In my final Chapter of this thesis, I compared two commonly used C57BL/6 substrains of mice by recording their electrophysiological responses to visual stimuli in vivo. I found a significant increase of high-frequency gamma power in adult C57BL/6JOla mice, and this phenomenon was reduced during the critical period. My results suggested that the C57BL/6JOla substrain has a significant stronger overall inhibitory network activity in the visual cortex than the C57BL/6J substrain. This is in good agreement with previous findings showing a lack of open-eye potentiation to monocular deprivation in the C57BL/6JOla substrain, and highlights the need for appropriate choice of mouse strain when studying neurodevelopmental models. They also give valuable insights into the genetic mechanisms that permit experience-dependent developmental plasticity. In summary, these findings give us a better understanding of the fine structure abnormalities of the Fmr1−/y mice, which in turn can benefit future discoveries of the underlying mechanisms of neurodevelopmental disorders such as ID and ASDs.
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Astrocytic roles in regulating dendritic spine maturation in UBe3A-dependent autism spectrum disorderGardner, Zachary V. 17 June 2023 (has links)
Autism spectrum disorders (ASDs) are a diverse class of neurodevelopmental disorders with various aberrant cellular phenotypes such as dysfunctional neurotransmission and irregular neuronal morphology. ASDs have a broad underlying genetic background with many genes linked to their etiology. UBE3A has been identified as a top gene candidate associated with ASD, and overexpression of UBE3A via copy-number variation confers hallmark ASD behaviors in humans and transgenic mice. Our previous work revealed that synapse formation was negatively affected in the Ube3A-ASD mouse model (Ube3A 2X Tg, or simply “2X Tg”). However, the cellular and molecular mechanisms underlying the synaptic dysregulation remain unknown. We sought to identify a cell-type specific mechanism by which these morphological changes were conferred. We found that selective overexpression of Ube3A in neurons failed to induce changes in dendritic spine maturation. In contrast, overexpression of Ube3A in astrocytes resulted in alterations in spines and synapses. Further, we
identified thrombospondin-2 (TSP2), a secreted astrocytic glycoprotein promoting synaptogenesis and spinogenesis, is involved in the defective spine maturation. Ube3A overexpression confers a loss of transcriptional down-regulation of TSP2 in astrocytes, and the medium of astrocyte cultures with Ube3A overexpression was sufficient to trigger spine changes similar to that observed in mixed cultures that globally overexpress Ube3A. Importantly, depletion of TSP2 promoted similar loss of dendritic spine maturation, whereas supplement of TSP2 to 2X Tg astrocyte media was able to rescue the spine defects. Furthermore, overexpression of Ube3A in an astrocyte-specific manner recapitulated aberrant dendritic spine maturation as well as autism-like behaviors displayed in 2X Tg mice. Collectively, these findings reveal an astrocytic dominance in initiating ASD pathobiology at the neuronal and behavior levels.
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Improving Therapeutics for Parkinson's DiseaseO'Malley, Jennifer A. January 2009 (has links)
No description available.
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