Pannexin 1 regulates spiny protrusion dynamics in cortical neurons

AbstractThe integration of neurons into networks relies on the formation of dendritic spines. These specialized structures arise from dynamic filopodia-like spiny protrusions. Recently, it was discovered that cortical neurons lacking the channel protein Pannexin 1 (Panx1) exhibited larger and more complicated neuronal networks, as well as, higher dendritic spine densities. Here, we expanded on those findings to investigate whether the increase in dendritic spine density associated with lack of Panx1 was due to differences in the rates of spine dynamics. Using a fluorescent membrane tag (mCherry-CD9-10) to visualize spiny protrusions in developing neurons (at 10 days-in-vitro, DIV10) we confirmed that lack of Panx1 leads to higher spiny protrusion density while transient transfection of Panx1 leads to decreased spiny protrusion density. To quantify the impact of Panx1 expression on spiny protrusion formation, elimination, and motility, we used live cell imaging in DIV10 neurons (1 frame every 5 seconds for 10 minutes). We discovered, that at DIV10, lack of Panx1 KO stabilized spiny protrusions. Notably, re-expression of Panx1 in Panx1 knockout neurons resulted in a significant increase in spiny protrusion motility and turnover. In summary, these new data revealed that Panx1 regulates the development of dendritic spines by controlling protrusion dynamics.Significance statementCells in the brain form intricate and specialized networks - neuronal networks - in charge of processing sensations, executing movement commands, and storing memories. To do this, brain cells extend microscopic protrusions - spiny protrusions - which are highly dynamic and survey the local environment to contact other cells. Those contact sites are known as synapses and undergo further stabilization and maturation establishing the function and efficiency of neuronal networks. Our work shows that removal of Panx1 increases the stability and decreases the turnover of spiny protrusion on young neurons.

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Cerebellar Culture Models of Dendritic Spine Proliferation After Transplantation of Glia

Journal of Neural Transplantation and Plasticity ◽

10.1155/np.1997.1 ◽

1997 ◽

Vol 6 (1) ◽

pp. 1-10 ◽

Cited By ~ 4

Author(s):

Fredrick J. Seil

Keyword(s):

Purkinje Cell ◽

Dendritic Spines ◽

Dendritic Spine ◽

Cortical Neurons ◽

Synapse Formation ◽

Granule Cells ◽

Axon Terminals ◽

Neuronal Membranes ◽

Culture Models

Studies of Purkinje cell dendritic spine proliferation after transplantation of cytosine arabinoside (Ara C) treated organotypic cerebellar cultures with glia and granule cells, either separately and in combination, were reviewed. Exposure of cerebellar explants to Ara C for the first 5 days in vitro results in the destruction of granule cells, the only excitatory cortical neurons, and oligodendroglia, and functionally compromises surviving astrocytes so that they do not appose neuronal membranes. In the absence of granule cells, there is a sprouting of Purkinje cell recurrent axon collaterals, the terminals of which project to and form heterotypical synapses with Purkinje cell dendritic spines, which are usually occupied by terminals of granule cell axons (parallel fibers). After this reorganization has been achieved, the explants can be transplanted with the missing elements to induce a second round of reorganization, with approximate restoration of the usual interneuronal relationships. Addition of both granule cells and glia resulted in a proliferation of clusters of Purkinje cell dendritic spines, which formed synapses with axon terminals of transplanted granule cells, and as synapse formation progressed, the spine clusters became reduced. Transplantation of Ara C-treated cultures with glia alone resulted in a proliferation of clusters of Purkinje cell dendritic spines, but in the absence of granule cells the spines remained unattached, and the clusters persisted throughout the period of observation. Purkinje cell dendritic spine proliferation was induced by exposure of Ara C-treated cultures to astrocyte-conditioned medium. When Ara C-treated cerebella cultures were transplanted with granule cells in the absence of functional glia, parallel fiber- Purkinje cell dendritic spine synapses formed, but no clusters of Purkinje cell dendritic spines were observed. These findings suggest that Purkinje cell dendritic spine proliferation is induced by an astrocyte-secreted factor, resulting in an expansion of postsynaptic sites available for synaptogenesis.

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Fluoxetine Protects against Dendritic Spine Loss in Middle-aged APPswe/PSEN1dE9 Double Transgenic Alzheimer’s Disease Mice

Current Alzheimer Research ◽

10.2174/1567205017666200213095419 ◽

2020 ◽

Vol 17 (1) ◽

pp. 93-103 ◽

Cited By ~ 1

Author(s):

Jing Ma ◽

Yuan Gao ◽

Wei Tang ◽

Wei Huang ◽

Yong Tang

Keyword(s):

Alzheimer’S Disease ◽

Alzheimer's Disease ◽

Dendritic Spines ◽

Dendritic Spine ◽

Early Stage ◽

Learning Ability ◽

Middle Aged ◽

Protein Levels ◽

Spine Pathology ◽

The Impact

Background: Studies have suggested that cognitive impairment in Alzheimer’s disease (AD) is associated with dendritic spine loss, especially in the hippocampus. Fluoxetine (FLX) has been shown to improve cognition in the early stage of AD and to be associated with diminishing synapse degeneration in the hippocampus. However, little is known about whether FLX affects the pathogenesis of AD in the middle-tolate stage and whether its effects are correlated with the amelioration of hippocampal dendritic dysfunction. Previously, it has been observed that FLX improves the spatial learning ability of middleaged APP/PS1 mice. Objective: In the present study, we further characterized the impact of FLX on dendritic spines in the hippocampus of middle-aged APP/PS1 mice. Results: It has been found that the numbers of dendritic spines in dentate gyrus (DG), CA1 and CA2/3 of hippocampus were significantly increased by FLX. Meanwhile, FLX effectively attenuated hyperphosphorylation of tau at Ser396 and elevated protein levels of postsynaptic density 95 (PSD-95) and synapsin-1 (SYN-1) in the hippocampus. Conclusion: These results indicated that the enhanced learning ability observed in FLX-treated middle-aged APP/PS1 mice might be associated with remarkable mitigation of hippocampal dendritic spine pathology by FLX and suggested that FLX might be explored as a new strategy for therapy of AD in the middle-to-late stage.

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Cell–cell coupling and DNA methylation abnormal phenotypes in the after-hours mice

Epigenetics & Chromatin ◽

10.1186/s13072-020-00373-5 ◽

2021 ◽

Vol 14 (1) ◽

Author(s):

Federico Tinarelli ◽

Elena Ivanova ◽

Ilaria Colombi ◽

Erica Barini ◽

Edoardo Balzani ◽

...

Keyword(s):

Gene Expression ◽

Dna Methylation ◽

Neuronal Networks ◽

Molecular Mechanisms ◽

Ex Vivo ◽

Neuronal Cultures ◽

Functional Impairments ◽

After Hours ◽

The Impact

Abstract Background DNA methylation has emerged as an important epigenetic regulator of brain processes, including circadian rhythms. However, how DNA methylation intervenes between environmental signals, such as light entrainment, and the transcriptional and translational molecular mechanisms of the cellular clock is currently unknown. Here, we studied the after-hours mice, which have a point mutation in the Fbxl3 gene and a lengthened circadian period. Methods In this study, we used a combination of in vivo, ex vivo and in vitro approaches. We measured retinal responses in Afh animals and we have run reduced representation bisulphite sequencing (RRBS), pyrosequencing and gene expression analysis in a variety of brain tissues ex vivo. In vitro, we used primary neuronal cultures combined to micro electrode array (MEA) technology and gene expression. Results We observed functional impairments in mutant neuronal networks, and a reduction in the retinal responses to light-dependent stimuli. We detected abnormalities in the expression of photoreceptive melanopsin (OPN4). Furthermore, we identified alterations in the DNA methylation pathways throughout the retinohypothalamic tract terminals and links between the transcription factor Rev-Erbα and Fbxl3. Conclusions The results of this study, primarily represent a contribution towards an understanding of electrophysiological and molecular phenotypic responses to external stimuli in the Afh model. Moreover, as DNA methylation has recently emerged as a new regulator of neuronal networks with important consequences for circadian behaviour, we discuss the impact of the Afh mutation on the epigenetic landscape of circadian biology.

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Ephrin-B3 controls excitatory synapse density through cell-cell competition for EphBs

eLife ◽

10.7554/elife.41563 ◽

2019 ◽

Vol 8 ◽

Cited By ~ 3

Author(s):

Nathan T Henderson ◽

Sylvain J Le Marchand ◽

Martin Hruska ◽

Simon Hippenmeyer ◽

Liqun Luo ◽

...

Keyword(s):

Cortical Neurons ◽

Spine Density ◽

Cell Competition ◽

Intrinsic Factors ◽

Genetic Mouse Model ◽

Synapse Density ◽

A Cell ◽

Cell Cell

Cortical networks are characterized by sparse connectivity, with synapses found at only a subset of axo-dendritic contacts. Yet within these networks, neurons can exhibit high connection probabilities, suggesting that cell-intrinsic factors, not proximity, determine connectivity. Here, we identify ephrin-B3 (eB3) as a factor that determines synapse density by mediating a cell-cell competition that requires ephrin-B-EphB signaling. In a microisland culture system designed to isolate cell-cell competition, we find that eB3 determines winning and losing neurons in a contest for synapses. In a Mosaic Analysis with Double Markers (MADM) genetic mouse model system in vivo the relative levels of eB3 control spine density in layer 5 and 6 neurons. MADM cortical neurons in vitro reveal that eB3 controls synapse density independently of action potential-driven activity. Our findings illustrate a new class of competitive mechanism mediated by trans-synaptic organizing proteins which control the number of synapses neurons receive relative to neighboring neurons.

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Distal axotomy enhances retrograde presynaptic excitability onto injured pyramidal neurons via trans-synaptic signaling

10.1101/065391 ◽

2016 ◽

Author(s):

Tharkika Nagendran ◽

Rylan S. Larsen ◽

Rebecca L. Bigler ◽

Shawn B. Frost ◽

Benjamin D. Philpot ◽

...

Keyword(s):

Dendritic Spines ◽

Dendritic Spine ◽

Pyramidal Neurons ◽

Spine Density ◽

Axon Injury ◽

Synaptic Remodeling ◽

Nerve Tracts ◽

Specific Increase ◽

Microfluidic Chambers

AbstractInjury of CNS nerve tracts remodels circuitry through dendritic spine loss and hyper-excitability, thus influencing recovery. Due to the complexity of the CNS, a mechanistic understanding of injury-induced synaptic remodeling remains unclear. Using microfluidic chambers to separate and injure distal axons, we show that axotomy causes retrograde dendritic spine loss at directly injured pyramidal neurons followed by retrograde presynaptic hyper-excitability. These remodeling events require activity at the site of injury, axon-to-soma signaling, and transcription. Similarly, directly injured corticospinal neurons in vivo also exhibit a specific increase in spiking following axon injury. Axotomy-induced hyper-excitability of cultured neurons coincides with elimination of inhibitory inputs onto injured neurons, including those formed onto dendritic spines. Netrin-1 downregulation occurs following axon injury and exogenous netrin-1 applied after injury normalizes spine density, presynaptic excitability, and inhibitory inputs at injured neurons. Our findings show that intrinsic signaling within damaged neurons regulates synaptic remodeling and involves netrin-1 signaling.

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Bergmann glial ensheathment of dendritic spines regulates synapse number without affecting spine motility

Neuron Glia Biology ◽

10.1017/s1740925x10000165 ◽

2010 ◽

Vol 6 (3) ◽

pp. 193-200 ◽

Cited By ~ 22

Author(s):

Jocelyn J. Lippman Bell ◽

Tamar Lordkipanidze ◽

Natalie Cobb ◽

Anna Dunaevsky

Keyword(s):

Purkinje Cell ◽

Dendritic Spines ◽

Dendritic Spine ◽

Adenoviral Vector ◽

Spine Density ◽

Dendritic Spine Density ◽

Spine Dynamics

In the cerebellum, lamellar Bergmann glial (BG) appendages wrap tightly around almost every Purkinje cell dendritic spine. The function of this glial ensheathment of spines is not entirely understood. The development of ensheathment begins near the onset of synaptogenesis, when motility of both BG processes and dendritic spines are high. By the end of the synaptogenic period, ensheathment is complete and motility of the BG processes decreases, correlating with the decreased motility of dendritic spines. We therefore have hypothesized that ensheathment is intimately involved in capping synaptogenesis, possibly by stabilizing synapses. To test this hypothesis, we misexpressed GluR2 in an adenoviral vector in BG towards the end of the synaptogenic period, rendering the BG α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (AMPARs) Ca2+-impermeable and causing glial sheath retraction. We then measured the resulting spine motility, spine density and synapse number. Although we found that decreasing ensheathment at this time does not alter spine motility, we did find a significant increase in both synaptic pucta and dendritic spine density. These results indicate that consistent spine coverage by BG in the cerebellum is not necessary for stabilization of spine dynamics, but is very important in the regulation of synapse number.

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Hippocampal CA1 Pyramidal Neurons ofMecp2Mutant Mice Show a Dendritic Spine Phenotype Only in the Presymptomatic Stage

Neural Plasticity ◽

10.1155/2012/976164 ◽

2012 ◽

Vol 2012 ◽

pp. 1-9 ◽

Cited By ~ 19

Author(s):

Christopher A. Chapleau ◽

Elena Maria Boggio ◽

Gaston Calfa ◽

Alan K. Percy ◽

Maurizio Giustetto ◽

...

Keyword(s):

Dendritic Spines ◽

Dendritic Spine ◽

Pyramidal Neurons ◽

Mutant Mice ◽

Spine Density ◽

Ca1 Pyramidal Neurons ◽

Dendritic Spine Density ◽

Presymptomatic Stage ◽

Deficient Mice

Alterations in dendritic spines have been documented in numerous neurodevelopmental disorders, including Rett Syndrome (RTT). RTT, an X chromosome-linked disorder associated with mutations inMECP2, is the leading cause of intellectual disabilities in women. Neurons inMecp2-deficient mice show lower dendritic spine density in several brain regions. To better understand the role of MeCP2 on excitatory spine synapses, we analyzed dendritic spines of CA1 pyramidal neurons in the hippocampus ofMecp2tm1.1Jaemale mutant mice by either confocal microscopy or electron microscopy (EM). At postnatal-day 7 (P7), well before the onset of RTT-like symptoms, CA1 pyramidal neurons from mutant mice showed lower dendritic spine density than those from wildtype littermates. On the other hand, at P15 or later showing characteristic RTT-like symptoms, dendritic spine density did not differ between mutant and wildtype neurons. Consistently, stereological analyses at the EM level revealed similar densities of asymmetric spine synapses in CA1stratum radiatumof symptomatic mutant and wildtype littermates. These results raise caution regarding the use of dendritic spine density in hippocampal neurons as a phenotypic endpoint for the evaluation of therapeutic interventions in symptomaticMecp2-deficient mice. However, they underscore the potential role of MeCP2 in the maintenance of excitatory spine synapses.

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The Polyadenosine RNA Binding Protein ZC3H14 is Required in Mice for Proper Dendritic Spine Density

10.1101/2020.10.08.331827 ◽

2020 ◽

Cited By ~ 1

Author(s):

Stephanie K. Jones ◽

Jennifer Rha ◽

Sarah Kim ◽

Kevin J. Morris ◽

Omotola F. Omotade ◽

...

Keyword(s):

Dendritic Spine ◽

Hippocampal Neurons ◽

Rna Binding ◽

Rna Binding Proteins ◽

Binding Protein ◽

Rna Binding Protein ◽

Spine Density ◽

Dendritic Spine Density

AbstractZC3H14 (Zinc finger CysCysCysHis domain-containing protein 14), an evolutionarily conserved member of a class of tandem zinc finger (CCCH) polyadenosine (polyA) RNA binding proteins, is associated with a form of heritable, nonsyndromic autosomal recessive intellectual disability. Previous studies of a loss of function mouse model, Zc3h14Δex13/Δex13, provide evidence that ZC3H14 is essential for proper brain function, specifically for working memory. To expand on these findings, we analyzed the dendrites and dendritic spines of hippocampal neurons from Zc3h14Δex13/Δex13 mice, both in situ and in vitro. These studies reveal that loss of ZC3H14 is associated with a decrease in total spine density in hippocampal neurons in vitro as well as in the dentate gyrus of 5-month old mice analyzed in situ. This reduction in spine density in vitro results from a decrease in the number of mushroom-shaped spines, which is rescued by exogenous expression of ZC3H14. We next performed biochemical analyses of synaptosomes prepared from whole wild-type and Zc3h14Δex13/Δex13 mouse brains to determine if there are changes in steady state levels of postsynaptic proteins upon loss of ZC3H14. We found that ZC3H14 is present within synaptosomes and that a crucial postsynaptic protein, CaMKIIα, is significantly increased in these synaptosomal fractions upon loss of ZC3H14. Together, these results demonstrate that ZC3H14 is necessary for proper dendritic spine density in cultured hippocampal neurons and in some regions of the mouse brain. These findings provide insight into how a ubiquitously expressed RNA binding protein leads to neuronal-specific defects that result in brain dysfunction.

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Pannexin 1 Regulates Network Ensembles and Dendritic Spine Development in Cortical Neurons

eNeuro ◽

10.1523/eneuro.0503-18.2019 ◽

2019 ◽

Vol 6 (3) ◽

pp. ENEURO.0503-18.2019 ◽

Cited By ~ 6

Author(s):

Juan C. Sanchez-Arias ◽

Mei Liu ◽

Catherine S. W. Choi ◽

Sarah N. Ebert ◽

Craig E. Brown ◽

...

Keyword(s):

Dendritic Spine ◽

Cortical Neurons ◽

Pannexin 1 ◽

Spine Development ◽

Network Ensembles

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EPAC2 is required for corticotropin-releasing hormone-mediated spine loss

10.1101/607598 ◽

2019 ◽

Author(s):

Zhong Xie ◽

Peter Penzes ◽

Deepak P. Srivastava

Keyword(s):

Dendritic Spines ◽

Dendritic Spine ◽

Cortical Neurons ◽

Acute Stress ◽

Critical Role ◽

Small Gtpase ◽

Corticotropin Releasing Hormone ◽

Rapid Loss ◽

Primary Cortical Neurons ◽

Releasing Hormone

AbstractCorticotropin-releasing hormone (CRH) is produced in response to stress. This hormone plays a key role in mediating neuroendocrine, behavioral, and autonomic responses to stress. The CRH receptor 1 (CRHR1) is expressed in multiple brain regions including the cortex and hippocampus. Previous studies have shown that activation of CRHR1 by CRH results in the rapid loss of dendritic spines. Exchange protein directly activated by cAMP (EPAC2, also known as RapGEF4), a guanine nucleotide exchange factor (GEF) for the small GTPase Rap, has been linked with CRHR1 signaling. EPAC2 plays a critical role in regulating dendritic spine morphology and number in response to several extracellular signals. But whether EPAC2 links CRHR1 with dendritic spine remodeling is unknown. Here we show that CRHR1 is highly enriched in the dendritic spines of primary cortical neurons. Furthermore, we find that EPAC2 and CRHR1 co-localize in cortical neurons. Critically, short hairpin RNA-mediated knockdown of Epac2 abolished CRH-mediated spine loss in primary cortical neurons. Taken together, our data indicate that EPAC2 is required for the rapid loss of dendritic spines induced by CRH. These findings identify a novel pathway by which acute exposure to CRH may regulate synaptic structure and ultimately responses to acute stress.

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