Structural plasticity upon learning: regulation and functions

Caroni, Pico; Donato, Flavio; Michelet, Dominique

doi:10.1038/nrn3258

Cited by 400 publications

(295 citation statements)

References 117 publications

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“…It is logical to think that use‐dependent remodeling of synaptic connections should involve alterations in the entire synaptic microenvironment (Caroni et al, 2012), which in many cases contains PAPs. Notwithstanding the aforementioned concerns about microscopic monitoring of nanostructures, candidate molecular mechanisms underlying this synapse‐astroglia relationship are beginning to emerge.…”

Section: Triggering Structural Plasticity Of Astroglia By Excitatory mentioning

confidence: 99%

Morphological plasticity of astroglia: Understanding synaptic microenvironment

Heller

Rusakov

2015

Glia

129

131

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Memory formation in the brain is thought to rely on the remodeling of synaptic connections which eventually results in neural network rewiring. This remodeling is likely to involve ultrathin astroglial protrusions which often occur in the immediate vicinity of excitatory synapses. The phenomenology, cellular mechanisms, and causal relationships of such astroglial restructuring remain, however, poorly understood. This is in large part because monitoring and probing of the underpinning molecular machinery on the scale of nanoscopic astroglial compartments remains a challenge. Here we briefly summarize the current knowledge regarding the cellular organisation of astroglia in the synaptic microenvironment and discuss molecular mechanisms potentially involved in use‐dependent astroglial morphogenesis. We also discuss recent observations concerning morphological astroglial plasticity, the respective monitoring methods, and some of the newly emerging techniques that might help with conceptual advances in the area. GLIA 2015;63:2133–2151

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Section: Triggering Structural Plasticity Of Astroglia By Excitatory mentioning

confidence: 99%

Morphological plasticity of astroglia: Understanding synaptic microenvironment

Heller

Rusakov

2015

Glia

129

131

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“…Beside synaptic plasticity, which adapts the synaptic strength between neurons, structural plasticity decides which synapse is created and which is deleted (Holtmaat and Svoboda 2009;Caroni et al 2012). Thus, by this mechanism the topology changes and the dynamics of the neuronal network can be modulated (Butz et al 2009).…”

Section: Structural Plasticitymentioning

confidence: 99%

Time scales of memory, learning, and plasticity

et al. 2012

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If we stored every bit of input, the storage capacity of our nervous system would be reached after only about 10 days. The nervous system relies on at least two mechanisms that counteract this capacity limit: compression and forgetting. But the latter mechanism needs to know how long an entity should be stored: some memories are relevant only for the next few minutes, some are important even after the passage of several years. Psychology and physiology have found and described many different memory mechanisms, and these mechanisms indeed use different time scales. In this prospect we review these mechanisms with respect to their time scale and propose relations between mechanisms in learning and memory and their underlying physiological basis.

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“…Long‐term potentiation (LTP) is an increase in synaptic strength caused by up‐regulating synaptic AMPA receptors (AMPARs) and involves an increase in spine size, whereas long‐term depression (LTD) is a decrease in synaptic strength caused by the internalisation of synaptic AMPARs and associated spine shrinkage (Hanley, 2008; Anggono & Huganir, 2012; Fortin et al , 2012). Long‐term plasticity of dendritic spines is thought to be an important cellular mechanism for information storage in the brain and therefore to play an essential role in learning and memory and the fine‐tuning of neural circuitry during development (Kasai et al , 2010; Caroni et al , 2012). …”

Section: Introductionmentioning

confidence: 99%

NMDAR ‐dependent Argonaute 2 phosphorylation regulates mi RNA activity and dendritic spine plasticity

et al. 2018

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MicroRNAs (miRNAs) repress translation of target mRNAs by associating with Argonaute (Ago) proteins to form the RNA‐induced silencing complex (RISC), underpinning a powerful mechanism for fine‐tuning protein expression. Specific miRNAs are required for NMDA receptor (NMDAR)‐dependent synaptic plasticity by modulating the translation of proteins involved in dendritic spine morphogenesis or synaptic transmission. However, it is unknown how NMDAR stimulation stimulates RISC activity to rapidly repress translation of synaptic proteins. We show that NMDAR stimulation transiently increases Akt‐dependent phosphorylation of Ago2 at S387, which causes an increase in binding to GW182 and a rapid increase in translational repression of LIMK1 via miR‐134. Furthermore, NMDAR‐dependent down‐regulation of endogenous LIMK1 translation in dendrites and dendritic spine shrinkage requires phospho‐regulation of Ago2 at S387. AMPAR trafficking and hippocampal LTD do not involve S387 phosphorylation, defining this mechanism as a specific pathway for structural plasticity. This work defines a novel mechanism for the rapid transduction of NMDAR stimulation into miRNA‐mediated translational repression to control dendritic spine morphology.

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Structural plasticity upon learning: regulation and functions

Cited by 400 publications

References 117 publications

Morphological plasticity of astroglia: Understanding synaptic microenvironment

Morphological plasticity of astroglia: Understanding synaptic microenvironment

Time scales of memory, learning, and plasticity

NMDAR ‐dependent Argonaute 2 phosphorylation regulates mi RNA activity and dendritic spine plasticity

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