Studying Molecular Interactions under Flow with Fluorescence Fluctuation Spectroscopy

Perego, Eleonora

16 January 2019

No description available.

571.4

Fluorescence spectroscopy

Microfluidics

Dynamics of protein assembly

Vimentin

Micro-patterning

Synaptic protein dynamics

Biologie (PPN619462639)

The Role of Astrocytes in Fragile X Neurobiology

Jacobs, Shelley

09 1900

<p> Fragile X Syndrome (FXS) is the most common inherited disease of mental impairment, typically caused by a mutation in the Fragile X mental retardation 1 (FMRJ) gene. The clinical features are thought to result from abnormal neurobiology due to a lack of the Fragile X mental retardation protein (FMRP). Previously, it was thought that FMRP was confined exclusively to neurons; however, our laboratory recently discovered that astrocytes also express FMRP. Consequently, it is possible that astrocytes also suffer abnormalities as a result of a lack of FMRP. Astrocytes play integral roles in the development and maintenance of communication in the central nervous system. Therefore, it is now important to determine the contribution of astrocytes to the abnormal neuronal phenotype seen in FXS. In these experiments, neurons and astrocytes were independently isolated from wild type (WT) or FMRJ null mice and grown in a coculture. Neurons were evaluated using immunocytochemistry in combination with computer-aided morphometric and synaptic protein analyses. The findings presented here provide convincing evidence that Fragile X astrocytes contribute to the abnormal neurobiology seen in FXS . Fragile X astrocytes alter the dendrite morphology and excitatory synaptic protein expression of WT neurons in culture; and, importantly, when Fragile X neurons are grown with WT astrocytes these changes are prevented. Interestingly, the Fragile X astrocytes appear to act by causing a delay in development; even WT neurons grown in the presence of Fragile X astrocytes, that displayed an abnormal phenotype at 7 days in culture, exhibited nearly normal dendrite morphology and expression of excitatory synapses at 21 days. Furthermore, the results suggest that the dendritic abnormalities induced by the Fragile X astrocytes specifically target neurons with a spiny stellate morphology. This research establishes a role for astrocytes in the development of the abnormal neurobiology seen in FXS, and as such, the results presented here have significant implications for Fragile X research. The novel prospect that astrocytes are key contributing components in the development of FXS provides an exciting new direction for investigations into the mechanisms underlying FXS, with many unexplored avenues for potential treatment strategies. </p> / Thesis / Doctor of Philosophy (PhD)

Molecular dissection of ionotropic glutamate receptor delta-family interactions with trans-synaptic proteins

Clay, Jordan Elliott

January 2013

Correct functioning of the brain relies upon the precise connectivity between the billions of neurons that make up this crucial organ. Aberrations in the formation of these elaborate neural networks lead to neurodegenerative and neuropsychiatric disorders. A synapse-spanning molecular triad, involving members of the Neurexin, Cbln and ionotropic glutamate receptor delta families of proteins, is crucial for the accurate formation and proper function of synapses in the cerebellum. This trans-synaptic complex has been implicated in the molecular mechanisms behind motor control and motor learning, and furthermore individual members have been linked to diseases such as Alzheimer’s, autism spectrum disorders and schizophrenia. The major findings presented in this thesis include: crystal structures of the amino-terminal domains (ATD) of the two members of the ionotropic glutamate receptor delta (iGluR-Delta) family, functional characterisation of the effects of disrupting the ATD interface in one member of the iGluR-Delta family, a crystal structure of the C1q domain of Cbln1, biophysical analysis of the molecular interactions within the Neurexin-Cbln1-GluD2 trans-synaptic complex, as well as evidence for the domain arrangement of the ecto-domain of the iGluR-Delta proteins. Together, these data enhance our knowledge of the molecular details of this macro-molecular complex and provide evidence to support models for the mechanisms of their involvement in synapse formation and function, thereby making a contribution to the vast and medically relevant field of molecular neurobiology.

573.8536

The Role of Cytoskeletal Morphology in the Nanoorganization of Synapse

Kaliyamoorthy, Venkatapathy

January 2016

Synapse is the fundamental unit of synaptic transmission. Learning, memory and neurodegenerative diseases of the brain are attributed to the maintenance and alteration in synaptic connections. The efficiency for synaptic transmission depends on how well the post synapse receives the signals from the presynapse; this in turn depends on the receptors present in the post synaptic density (PSD). PSD is present in the post synapse right opposite to the neurotransmitter release site in presynapse (active zone) is an indispensable part of the synapse. The PSD is comprised of receptors and scaffold proteins, which is ultimately supported by the actin cytoskeleton of the dendritic spines. Cytoskeletal dynamics is shown to influence the structural plasticity of spine and also PSD, but how it regulates the dynamicity of the synaptic transmission is not completely understood. Here we studied the influence of actin depolymerisation on sub synaptic organization of an excitatory synapse. In order to study the organization of the synapse at molecular resolution, the conventional microscopy cannot be employed due to the limit of diffraction. Super resolution microscopy circumvents this diffraction limitation. In this study we have used custom built fluorescence microscope with Total Internal Reflection Fluorescence (TIRF) modality to observe the nanometre sized structures inside spines of mouse hippocampal primary neurons. The setup was integrated with Metamorph imaging software for both operating the microscope and imaging acquisition purpose with a separate appropriate laser system. This setup was successful in achieving the lateral resolution of ~30nm and axial resolution of ~51nm. Over all we were able to observe the loss of spines and significant reduction in area of nanometer sized protein clusters in postsynaptic density with in the spines of latrunculin A treated mouse hippocampal primary neurons compared to the native neurons. Along with the morphological alterations in neurons we also observed the changes in nanoscale organization of few key molecules in the postsynaptic density.

Synapse

Cytoskeletal Morphology

Postsynaptic Density

Synapse Nanoorganization

Synaptic Protein Clusters

Super Resolution Microscopy (dSTORM)

Synaptic Morphology

Synapse Molecular Organization

Post Synaptic Density (PSD)

Neuroscience

Der Einfluss von 5-HT 1A Rezeptoren auf die embryonale und postnatale Entwicklung des serotonergen Systems im Gehirn der Maus

Deng, Dongrui

23 September 2003

In the present study 5-hydroxytryptamine (5-HT) 1A receptor knockout mice (KO), mice overexpressing the 5-HT1A receptor (OE), and wild-type (WT) mice were used to investigate the influence of 5-HT1A receptor on the development of the serotonergic system in the brain, from the embryonic day 12.5 to the postnatal day 15.5. Neither the absence nor the overexpression of 5-HT1A receptor influenced the development and differentiation of serotonergic neurons in the raphe area of the mouse brain. However, a delay in the initial development of the serotonergic projections to the mesencephalic tegmentum, cerebral cortex and hypothalamus was observed in both transgenic mice lines. The brain levels of 5-HT and 5-hydroxyindoleacetic acid were significantly higher in both transgenic mice lines during the late embryonic and early postnatal periods as compared to WT mice. An increase in the turnover of 5-HT was not observed before the early postnatal period. Both the absence and the overexpression of 5-HT1A receptor delayed the development of the dopaminergic system of the mesencephalic tegmentum in the early embryonic period. In OE mice the postnatal development of the noradrenergic system appeared to be exaggerated. The immunoreactivity for the neurotrophic protein S100ß was higher in the cerebral cortex, striatum and hippocampus of OE mice as compare to WT and KO mice. The expression of synaptic proteins, such as synapatobrevin and synaptotagmin was reduced in KO and OE mice during the early embryonic period. This reduction may be linked to the delayed development of the serotonergic projections and the dopaminergic system. In addition, no influence of 5-HT1A receptor mutations on the myelination of the brain was observed. Zusammenfassung In der vorliegenden Arbeit wurden die 5-Hydroxytryptamin (5-HT)1A Rezeptor Knockout (KO), überexprimierenden (ÜE) Mäuse und die Wild-Typ (WT) Mäuse, in den Entwicklungsperioden vom embryonalen Tag 12,5 bis postnatalen Tag 15,5 untersucht, um weitere Informationen über den Einfluss vom 5-HT1A Rezeptor auf die Entwicklung des serotonergen Systems im Gehirn zu erhalten. Sowohl das Fehlen des 5-HT1A Rezeptors als auch dessen Überexpression hatten zwar keinen Einfluss auf die Entwicklung und Differenzierung der serotonergen Neurone in den Raphe Regionen, verzögerte aber die erste Entwicklung der serotonergen Innervierungen im mesencephalen Tegmentum, Hypothalamus und cerebralen Cortex. In den späten embryonalen und insbesondere frühpostnatalen Perioden waren die 5-HT- und 5-HIAA-Spiegel bei KO und ÜE Mäusen im Vergleich zu WT Mäusen signifikant erhöht. Eine Erhöhung des 5-HT Turnovers wurde erst in der frühpostnatalen Periode beobachtet. Auch die Entwicklung des dopaminergen Systems im Mesencephalon war in der frühen embryonalen Periode sowohl bei KO als auch bei ÜE Mäusen verlangsamt. Die Überexpression des 5-HT1A Rezeptors begünstigte möglicherweise die postnatale Entwicklung des noradrenergen Systems. Bei ÜE Mäusen war die Immunreaktivität des neurotrophen Proteins S100? im cerebralen Cortex, Hippocampus und Striatum stärker als bei WT und KO Mäusen. Die Expression der synaptischen Proteine wie Synaptobrevin und Synaptotagmin war sowohl bei KO als auch bei ÜE Mäusen in der frühen embryonalen Periode verzögert. Dies könnte mit der verzögerten Entwicklung der serotonergen Projektionen und des dopaminergen Systems in Zusammenhang stehen. Darüber hinaus hatten transgene Veränderungen am 5-HT1A Rezeptor keinen Einfluss auf die Myelinisierung im Gehirn der Maus. Schlagwörter: serotonerges System, Entwicklung des Gehirns, 5-HT1A Rezeptor, transgene Mäuse, dopaminerges System, noradrenerges System, S100ß, Synaptisches Protein, Myelinisierung / In the present study 5-hydroxytryptamine (5-HT) 1A receptor knockout mice (KO), mice overexpressing the 5-HT1A receptor (OE), and wild-type (WT) mice were used to investigate the influence of 5-HT1A receptor on the development of the serotonergic system in the brain, from the embryonic day 12.5 to the postnatal day 15.5. Neither the absence nor the overexpression of 5-HT1A receptor influenced the development and differentiation of serotonergic neurons in the raphe area of the mouse brain. However, a delay in the initial development of the serotonergic projections to the mesencephalic tegmentum, cerebral cortex and hypothalamus was observed in both transgenic mice lines. The brain levels of 5-HT and 5-hydroxyindoleacetic acid were significantly higher in both transgenic mice lines during the late embryonic and early postnatal periods as compared to WT mice. An increase in the turnover of 5-HT was not observed before the early postnatal period. Both the absence and the overexpression of 5-HT1A receptor delayed the development of the dopaminergic system of the mesencephalic tegmentum in the early embryonic period. In OE mice the postnatal development of the noradrenergic system appeared to be exaggerated. The immunoreactivity for the neurotrophic protein S100ß was higher in the cerebral cortex, striatum and hippocampus of OE mice as compare to WT and KO mice. The expression of synaptic proteins, such as synapatobrevin and synaptotagmin was reduced in KO and OE mice during the early embryonic period. This reduction may be linked to the delayed development of the serotonergic projections and the dopaminergic system. In addition, no influence of 5-HT1A receptor mutations on the myelination of the brain was observed.

serotonerges System

Entwicklung des Gehirns

5-HT1A Rezeptor

transgene Mäuse

dopaminerges System

noradrenerges System

S100ß

Synaptisches Protein

Myelinisierung

transgenic mice

serotonergic system

brain development

5-HT1A receptor

dopaminergic system

noradrenergic System

S100ß

synaptic protein

myelination.

610 Medizin

33 Medizin

ddc:610