Nogo-A Modulates the Synaptic Excitation of Hippocampal Neurons in a Ca2+-Dependent Manner

A tight regulation of the balance between inhibitory and excitatory synaptic transmission is a prerequisite for synaptic plasticity in neuronal networks. In this context, the neurite growth inhibitor membrane protein Nogo-A modulates synaptic plasticity, strength, and neurotransmitter receptor dynamics. However, the molecular mechanisms underlying these actions are unknown. We show that Nogo-A loss-of-function in primary mouse hippocampal cultures by application of a function-blocking antibody leads to higher excitation following a decrease in GABAARs at inhibitory and an increase in the GluA1, but not GluA2 AMPAR subunit at excitatory synapses. This unbalanced regulation of AMPAR subunits results in the incorporation of Ca2+-permeable GluA2-lacking AMPARs and increased intracellular Ca2+ levels due to a higher Ca2+ influx without affecting its release from the internal stores. Increased neuronal activation upon Nogo-A loss-of-function prompts the phosphorylation of the transcription factor CREB and the expression of c-Fos. These results contribute to the understanding of the molecular mechanisms underlying the regulation of the excitation/inhibition balance and thereby of plasticity in the brain.

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Localized recruitment and activation of RhoA underlies dendritic spine morphology in a glutamate receptor–dependent manner

The Journal of Cell Biology ◽

10.1083/jcb.200506136 ◽

2006 ◽

Vol 172 (3) ◽

pp. 453-467 ◽

Cited By ~ 64

Author(s):

Vanessa Schubert ◽

Jorge Santos Da Silva ◽

Carlos G. Dotti

Keyword(s):

Actin Cytoskeleton ◽

Dendritic Spine ◽

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Excitatory Synapses ◽

Dependent Manner ◽

Rhoa Activity ◽

Spine Shape ◽

Local Reduction ◽

Dendritic Spine Morphology

Actin is the major cytoskeletal source of dendritic spines, which are highly specialized protuberances on the neuronal surface where excitatory synaptic transmission occurs (Harris, K.M., and S.B. Kater. 1994. Annu. Rev. Neurosci. 17:341–371; Yuste, R., and D.W. Tank. 1996. Neuron. 16:701–716). Stimulation of excitatory synapses induces changes in spine shape via localized rearrangements of the actin cytoskeleton (Matus, A. 2000. Science. 290:754–758; Nagerl, U.V., N. Eberhorn, S.B. Cambridge, and T. Bonhoeffer. 2004. Neuron. 44:759–767). However, what remains elusive are the precise molecular mechanisms by which different neurotransmitter receptors forward information to the underlying actin cytoskeleton. We show that in cultured hippocampal neurons as well as in whole brain synaptosomal fractions, RhoA associates with glutamate receptors (GluRs) at the spine plasma membrane. Activation of ionotropic GluRs leads to the detachment of RhoA from these receptors and its recruitment to metabotropic GluRs. Concomitantly, this triggers a local reduction of RhoA activity, which, in turn, inactivates downstream kinase RhoA-specific kinase, resulting in restricted actin instability and dendritic spine collapse. These data provide a direct mechanistic link between neurotransmitter receptor activity and the changes in spine shape that are thought to play a crucial role in synaptic strength.

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c-Jun NH2-terminal Kinase (JNK)-interacting Protein-3 (JIP3) Regulates Neuronal Axon Elongation in a Kinesin- and JNK-dependent Manner

Journal of Biological Chemistry ◽

10.1074/jbc.m113.464453 ◽

2013 ◽

Vol 288 (20) ◽

pp. 14531-14543 ◽

Cited By ~ 36

Author(s):

Tao Sun ◽

Nuo Yu ◽

Lu-Kai Zhai ◽

Na Li ◽

Chao Zhang ◽

...

Keyword(s):

Cortical Neurons ◽

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Neuronal Development ◽

Dependent Manner ◽

Loss Of Function ◽

Anterograde Transport ◽

Interacting Protein ◽

Axon Elongation

The development of neuronal polarity is essential for the establishment of the accurate patterning of neuronal circuits in the brain. However, little is known about the underlying molecular mechanisms that control rapid axon elongation during neuronal development. Here, we report that c-Jun NH2-terminal kinase (JNK)-interacting protein-3 (JIP3) is highly expressed at axon tips during the critical period for axon development. Using gain- and loss-of-function approaches, immunofluorescence analysis, and in utero electroporation, we find that JIP3 can enhance axon elongation in primary hippocampal neurons and cortical neurons in vivo. We further demonstrate that JIP3 promotes axon elongation in a kinesin- and JNK-dependent manner using several deletion mutants of JIP3. Next, we demonstrate that the successful transportation of JIP3 to axon tips by kinesin is a prerequisite for enhancing JNK phosphorylation in this area and therefore promotes axon elongation, constituting a novel mechanism for coupling JIP3 anterograde transport with JNK signaling at the distal axons and axon elongation. Finally, our immunofluorescence data suggest that the activation of JNK at axon tips facilitates axon elongation by modulating cofilin activity and actin filament dynamics. These findings may have important implications for our understanding of neuronal axon elongation during development.

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Deletion of the Actin-Associated Tropomyosin Tpm3 Leads to Reduced Cell Complexity in Cultured Hippocampal Neurons—New Insights into the Role of the C-Terminal Region of Tpm3.1

Cells ◽

10.3390/cells10030715 ◽

2021 ◽

Vol 10 (3) ◽

pp. 715

Author(s):

Tamara Tomanić ◽

Claire Martin ◽

Holly Stefen ◽

Esmeralda Parić ◽

Peter Gunning ◽

...

Keyword(s):

Amino Acid ◽

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Growth Cones ◽

Amino Acid Residues ◽

Terminal Amino Acid ◽

C Terminus ◽

Primary Mouse ◽

Terminal Amino

Tropomyosins (Tpms) have been described as master regulators of actin, with Tpm3 products shown to be involved in early developmental processes, and the Tpm3 isoform Tpm3.1 controlling changes in the size of neuronal growth cones and neurite growth. Here, we used primary mouse hippocampal neurons of C57/Bl6 wild type and Bl6Tpm3flox transgenic mice to carry out morphometric analyses in response to the absence of Tpm3 products, as well as to investigate the effect of C-terminal truncation on the ability of Tpm3.1 to modulate neuronal morphogenesis. We found that the knock-out of Tpm3 leads to decreased neurite length and complexity, and that the deletion of two amino acid residues at the C-terminus of Tpm3.1 leads to more detrimental changes in neurite morphology than the deletion of six amino acid residues. We also found that Tpm3.1 that lacks the 6 C-terminal amino acid residues does not associate with stress fibres, does not segregate to the tips of neurites, and does not impact the amount of the filamentous actin pool at the axonal growth cones, as opposed to Tpm3.1, which lacks the two C-terminal amino acid residues. Our study provides further insight into the role of both Tpm3 products and the C-terminus of Tpm3.1, and it forms the basis for future studies that aim to identify the molecular mechanisms underlying Tpm3.1 targeting to different subcellular compartments.

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Neurite Growth and Polarization on Vitronectin Substrate after in Vitro Trauma is not Enhanced after IGF Treatment

Brain Sciences ◽

10.3390/brainsci8080151 ◽

2018 ◽

Vol 8 (8) ◽

pp. 151 ◽

Cited By ~ 2

Author(s):

K. Bergen ◽

M. Frödin ◽

C. von Gertten ◽

A. Sandberg-Nordqvist ◽

M. Sköld

Keyword(s):

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Brain Injuries ◽

Neurite Growth ◽

Cellular Growth ◽

Neurotrophic Activity ◽

Igf Binding ◽

And Migration ◽

Igf Binding Protein

Following traumatic brain injuries (TBI), insulin-like growth factor (IGF) is cortically widely upregulated. This upregulation has a potential role in the recovery of neuronal tissue, plasticity, and neurotrophic activity, though the molecular mechanisms involved in IGF regulation and the exact role of IGF after TBI remain unclear. Vitronectin (VN), an extracellular matrix (ECM) molecule, has recently been shown to be of importance for IGF-mediated cellular growth and migration. Since VN is downregulated after TBI, we hypothesized that insufficient VN levels after TBI impairs the potential beneficial activity of IGF. To test if vitronectin and IGF-1/IGFBP-2 could contribute to neurite growth, we cultured hippocampal neurons on ± vitronectin-coated coverslips and them treated with ± IGF-1/IGF binding protein 2 (IGFBP-2). Under same conditions, cell cultures were also subjected to in vitro trauma to investigate differences in the posttraumatic regenerative capacity with ± vitronectin-coated coverslips and with ± IGF-1/IGFBP-2 treatment. In both the control and trauma situations, hippocampal neurons showed a stronger growth pattern on vitronectin than on the control substrate. Surprisingly, the addition of IGF-1/IGFBP-2 showed a decrease in neurite growth. Since neurite growth was measured as the number of neurites per area, we hypothesized that IGF-1/IGFBP-2 contributes to the polarization of neurons and thus induced a less dense neurite network after IGF-1/IGFBP-2 treatment. This hypothesis could not be confirmed and we therefore conclude that vitronectin has a positive effect on neurite growth in vitro both under normal conditions and after trauma, but that addition of IGF-1/IGFBP-2 does not have a positive additive effect.

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Chemical LTD, but not LTP, induces transient accumulation of gelsolin in dendritic spines

Biological Chemistry ◽

10.1515/hsz-2019-0110 ◽

2019 ◽

Vol 400 (9) ◽

pp. 1129-1139 ◽

Cited By ~ 2

Author(s):

Iryna Hlushchenko ◽

Pirta Hotulainen

Keyword(s):

Synaptic Plasticity ◽

Dendritic Spines ◽

Hippocampal Neurons ◽

Long Term Potentiation ◽

Excitatory Synapses ◽

Signal Molecule ◽

Brain Functions ◽

Dendritic Shaft ◽

Term Potentiation

Abstract Synaptic plasticity underlies central brain functions, such as learning. Ca2+ signaling is involved in both strengthening and weakening of synapses, but it is still unclear how one signal molecule can induce two opposite outcomes. By identifying molecules, which can distinguish between signaling leading to weakening or strengthening, we can improve our understanding of how synaptic plasticity is regulated. Here, we tested gelsolin’s response to the induction of chemical long-term potentiation (cLTP) or long-term depression (cLTD) in cultured rat hippocampal neurons. We show that gelsolin relocates from the dendritic shaft to dendritic spines upon cLTD induction while it did not show any relocalization upon cLTP induction. Dendritic spines are small actin-rich protrusions on dendrites, where LTD/LTP-responsive excitatory synapses are located. We propose that the LTD-induced modest – but relatively long-lasting – elevation of Ca2+ concentration increases the affinity of gelsolin to F-actin. As F-actin is enriched in dendritic spines, it is probable that increased affinity to F-actin induces the relocalization of gelsolin.

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Distinct stages of synapse elimination are induced by burst firing of CA1 neurons and differentially require MEF2A/D

eLife ◽

10.7554/elife.26278 ◽

2017 ◽

Vol 6 ◽

Cited By ~ 5

Author(s):

Chia-Wei Chang ◽

Julia R Wilkerson ◽

Carly F Hale ◽

Jay R Gibson ◽

Kimberly M Huber

Keyword(s):

Hippocampal Neurons ◽

Molecular Mechanisms ◽

De Novo ◽

Activity Patterns ◽

Burst Firing ◽

Excitatory Synapses ◽

Synapse Elimination ◽

Ca1 Neurons ◽

Theta Frequency ◽

Individual Mouse

Experience and activity refine cortical circuits through synapse elimination, but little is known about the activity patterns and downstream molecular mechanisms that mediate this process. We used optogenetics to drive individual mouse CA1 hippocampal neurons to fire in theta frequency bursts to understand how cell autonomous, postsynaptic activity leads to synapse elimination. Brief (1 hr) periods of postsynaptic bursting selectively depressed AMPA receptor (R) synaptic transmission, or silenced excitatory synapses, whereas more prolonged (24 hr) firing depressed both AMPAR and NMDAR EPSCs and eliminated spines, indicative of a synapse elimination. Both synapse silencing and elimination required de novo transcription, but only silencing required the activity-dependent transcription factors MEF2A/D. Burst firing induced MEF2A/D-dependent induction of the target gene Arc which contributed to synapse silencing and elimination. This work reveals new and distinct forms of activity and transcription-dependent synapse depression and suggests that these processes can occur independently.

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Molecular Bases of Human Malformation Syndromes Involving the SHH Pathway: GLIA/R Balance and Cardinal Phenotypes

International Journal of Molecular Sciences ◽

10.3390/ijms222313060 ◽

2021 ◽

Vol 22 (23) ◽

pp. 13060

Author(s):

Yo Niida ◽

Sumihito Togi ◽

Hiroki Ura

Keyword(s):

Molecular Mechanisms ◽

Brain Size ◽

Balance Model ◽

Dependent Manner ◽

Loss Of Function ◽

Concentration Dependent Manner ◽

Shh Pathway ◽

Embryonic Morphogenesis ◽

Malformation Syndromes ◽

Molecular Bases

Human hereditary malformation syndromes are caused by mutations in the genes of the signal transduction molecules involved in fetal development. Among them, the Sonic hedgehog (SHH) signaling pathway is the most important, and many syndromes result from its disruption. In this review, we summarize the molecular mechanisms and role in embryonic morphogenesis of the SHH pathway, then classify the phenotype of each malformation syndrome associated with mutations of major molecules in the pathway. The output of the SHH pathway is shown as GLI activity, which is generated by SHH in a concentration-dependent manner, i.e., the sum of activating form of GLI (GLIA) and repressive form of GLI (GLIR). Which gene is mutated and whether the mutation is loss-of-function or gain-of-function determine in which concentration range of SHH the imbalance occurs. In human malformation syndromes, too much or too little GLI activity produces symmetric phenotypes affecting brain size, craniofacial (midface) dysmorphism, and orientation of polydactyly with respect to the axis of the limb. The symptoms of each syndrome can be explained by the GLIA/R balance model.

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Rapid Effects of Estradiol on Dendritic Spines and Synaptic Plasticity in the Male and Female Hippocampus

Estrogens and Memory ◽

10.1093/oso/9780190645908.003.0004 ◽

2020 ◽

pp. 38-47

Author(s):

Asami Kato ◽

Gen Murakami ◽

Yasushi Hojo ◽

Sigeo Horie ◽

Suguru Kawato

Keyword(s):

Synaptic Plasticity ◽

Dendritic Spine ◽

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Hippocampal Slices ◽

Spine Density ◽

Male And Female ◽

Dendritic Spine Density ◽

Male And Female Rats ◽

Rapid Modulation

Although the potent estrogen, 17β‎-estradiol (E2), has long been known to regulate the hippocampal dendritic spine density and synaptic plasticity, the molecular mechanisms through which it does so are less well understood. This chapter discusses the rapid modulation of hippocampal dendritic spine density and synaptic plasticity in male and female rats, with particular attention to studies in hippocampal slices from male rats. Among the mechanisms described are the roles of specific cell-signaling kinases and estrogen receptors in mediating the effects of E2 and progesterone on hippocampal neurons. In addition, dynamic changes of spine structures over time and sex differences in spine regulation are also considered. Finally, the chapter ends by discussing the importance of local hippocampal synthesis of E2 and androgens to hippocampal spine morphology and plasticity.

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Neuronal megalin mediates synaptic plasticity—a novel mechanism underlying intellectual disabilities in megalin gene pathologies

Brain Communications ◽

10.1093/braincomms/fcaa135 ◽

2020 ◽

Vol 2 (2) ◽

Author(s):

João R Gomes ◽

Andrea Lobo ◽

Renata Nogueira ◽

Ana F Terceiro ◽

Susete Costelha ◽

...

Keyword(s):

Synaptic Plasticity ◽

Intellectual Disabilities ◽

Learning And Memory ◽

Neuronal Activity ◽

Hippocampal Neurons ◽

Molecular Mechanisms ◽

Genetic Disorder ◽

Cell Surface Receptor ◽

Neuronal Cultures

Abstract Donnai-Barrow syndrome, a genetic disorder associated to LRP2 (low-density lipoprotein receptor 2/megalin) mutations, is characterized by unexplained neurological symptoms and intellectual deficits. Megalin is a multifunctional endocytic clearance cell-surface receptor, mostly described in epithelial cells. This receptor is also expressed in the CNS, mainly in neurons, being involved in neurite outgrowth and neuroprotective mechanisms. Yet, the mechanisms involved in the regulation of megalin in the CNS are poorly understood. Using transthyretin knockout mice, a megalin ligand, we found that transthyretin positively regulates neuronal megalin levels in different CNS areas, particularly in the hippocampus. Transthyretin is even able to rescue megalin downregulation in transthyretin knockout hippocampal neuronal cultures, in a positive feedback mechanism via megalin. Importantly, transthyretin activates a regulated intracellular proteolysis mechanism of neuronal megalin, producing an intracellular domain, which is translocated to the nucleus, unveiling megalin C-terminal as a potential transcription factor, able to regulate gene expression. We unveil that neuronal megalin reduction affects physiological neuronal activity, leading to decreased neurite number, length and branching, and increasing neuronal susceptibility to a toxic insult. Finally, we unravel a new unexpected role of megalin in synaptic plasticity, by promoting the formation and maturation of dendritic spines, and contributing for the establishment of active synapses, both in in vitro and in vivo hippocampal neurons. Moreover, these structural and synaptic roles of megalin impact on learning and memory mechanisms, since megalin heterozygous mice show hippocampal-related memory and learning deficits in several behaviour tests. Altogether, we unveil a complete novel role of megalin in the physiological neuronal activity, mainly in synaptic plasticity with impact in learning and memory. Importantly, we contribute to disclose the molecular mechanisms underlying the cognitive and intellectual disabilities related to megalin gene pathologies.

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N-cadherin mediates plasticity-induced long-term spine stabilization

The Journal of Cell Biology ◽

10.1083/jcb.201003007 ◽

2010 ◽

Vol 189 (3) ◽

pp. 589-600 ◽

Cited By ~ 97

Author(s):

Pablo Mendez ◽

Mathias De Roo ◽

Lorenzo Poglia ◽

Paul Klauser ◽

Dominique Muller

Keyword(s):

Molecular Mechanisms ◽

Stable State ◽

Long Term Potentiation ◽

Excitatory Synapses ◽

Loss Of Function ◽

Long Term Stability ◽

Spine Stabilization ◽

Term Potentiation ◽

Dynamic Structures

Excitatory synapses on dendritic spines are dynamic structures whose stability can vary from hours to years. However, the molecular mechanisms regulating spine persistence remain essentially unknown. In this study, we combined repetitive imaging and a gain and loss of function approach to test the role of N-cadherin (NCad) on spine stability. Expression of mutant but not wild-type NCad promotes spine turnover and formation of immature spines and interferes with the stabilization of new spines. Similarly, the long-term stability of preexisting spines is reduced when mutant NCad is expressed but enhanced in spines expressing NCad-EGFP clusters. Activity and long-term potentiation (LTP) induction selectively promote formation of NCad clusters in stimulated spines. Although activity-mediated expression of NCad-EGFP switches synapses to a highly stable state, expression of mutant NCad or short hairpin RNA–mediated knockdown of NCad prevents LTP-induced long-term stabilization of synapses. These results identify NCad as a key molecular component regulating long-term synapse persistence.

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