Nanoscale Structural Plasticity of the Active Zone Matrix Modulates Presynaptic Function

Glebov, Oleg O.; Jackson, Rachel E.; Winterflood, Christian M.; Owen, Dylan M.; Barker, Ellen; Doherty, Patrick; Ewers, Helge; Burrone, Juan

doi:10.1016/j.celrep.2017.02.064

Cited by 73 publications

(116 citation statements)

References 54 publications

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“…Consistently, we uncovered elevated Ca 2+ -current density in the experimental conditions with increased pr, implying increased levels of presynaptic voltage-gated Ca 2+ channels. This observation is in line with previous light-microscopy based results from mammalian CNS synapses and the Drosophila NMJ (23,(66)(67)(68). 5…”

supporting

confidence: 92%

“…The expression of PHP depends on cell-culture age, with cultures older than two weeks compensating for prolonged activity deprivation through concomitant regulation of 20 presynaptic release, postsynaptic receptor abundance, and synapse number (19)(20)(21)(22). Despite evidence for compensatory changes in presynaptic structure and function (23)(24)(25)(26)(27), it is currently not well understood how these relate to the postsynaptic modifications during synaptic scaling. Moreover, it has remained largely elusive if PHP stabilizes the activity of native neural circuits (8,28,29).…”

Section: Introductionmentioning

confidence: 99%

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Rapid and Sustained Homeostatic Control of Presynaptic Exocytosis at a Central Synapse

Delvendahl

Kita

Mueller

2019

Preprint

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Animal behavior is remarkably robust despite constant changes in neural activity. Homeostatic plasticity stabilizes central nervous system (CNS) function on time scales of hours to days. If and how CNS function is stabilized on more rapid time 15 scales remains unknown. Here we discovered that mossy fiber synapses in the mouse cerebellum homeostatically control synaptic efficacy within minutes after pharmacological glutamate receptor impairment. This rapid form of homeostatic plasticity is expressed presynaptically. We show that modulations of readilyreleasable vesicle pool size and release probability normalize synaptic strength in a 20 hierarchical fashion upon acute pharmacological and prolonged genetic receptor perturbation. Presynaptic membrane capacitance measurements directly demonstrate regulation of vesicle pool size upon receptor impairment. Moreover, presynaptic voltage-clamp analysis revealed increased calcium-current density under specific experimental conditions. Thus, homeostatic modulation of presynaptic 25 exocytosis through specific mechanisms stabilizes synaptic transmission in a CNS circuit on time scales ranging from minutes to months. Rapid presynaptic homeostatic plasticity may ensure stable neural circuit function in light of rapid activity-dependent plasticity.30

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supporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Rapid and Sustained Homeostatic Control of Presynaptic Exocytosis at a Central Synapse

Delvendahl

Kita

Mueller

2019

Preprint

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“…AZ proteins can undergo vigorous reorganization on a time scale of minutes [45], which may consequently affect release site organization. For instance, following prolonged synaptic silencing, Bassoon was found to be less clustered while overall quantity remained unchanged [46]. This was associated with increased recruitment of presynaptic vesicle fusion machinery including Ca 2+ channels [46] and a decreased AZ-PSD distance [47], both presumably facilitating the known homeostatic increase of synaptic transmission.…”

Section: Alignment-mediated Plasticity Arising From Presynaptic Reorgmentioning

confidence: 99%

“…For instance, following prolonged synaptic silencing, Bassoon was found to be less clustered while overall quantity remained unchanged [46]. This was associated with increased recruitment of presynaptic vesicle fusion machinery including Ca 2+ channels [46] and a decreased AZ-PSD distance [47], both presumably facilitating the known homeostatic increase of synaptic transmission. These activity-dependent reorganizations could dynamically modulate the properties of release sites, including not only P r but also spatial distribution (Fig.…”

Section: Alignment-mediated Plasticity Arising From Presynaptic Reorgmentioning

confidence: 99%

Subsynaptic spatial organization as a regulator of synaptic strength and plasticity

Chen

Tang

Blanpied

2018

Current Opinion in Neurobiology

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Synapses differ markedly in their performance, even amongst those on a single neuron. The mechanisms that drive this functional diversification are of great interest because they enable adaptive behaviors and are targets of pathology. Considerable effort has focused on elucidating mechanisms of plasticity that involve changes to presynaptic release probability and the number of postsynaptic receptors. However, recent work is clarifying that nanoscale organization of the proteins within glutamatergic synapses impacts synapse function. Specifically, active zone scaffold proteins form nanoclusters that define sites of neurotransmitter release, and these sites align transsynaptically with clustered postsynaptic receptors. These nanostructural characteristics raise numerous possibilities for how synaptic plasticity could be expressed.

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“…L'exposition au THC in utero ou en périnatal chez les rongeurs a été directement associée à de nombreux déficits cognitifs et émotionnels à long terme [15,16]. Les perturbations structurelles et fonctionnelles des systèmes dopaminergique et GABAergique observées [17][18][19] sont cohérentes avec celles observées chez l'homme, montrant que l'exposition au cannabis in utero entraîne une expression anormale des récepteurs dopaminergique D2 dans l'amygdale [4]. Des altérations de l'excitabilité des neurones et de la plasticité synaptique au niveau cortex préfrontal et de l'hippocampe ont aussi été rapportées [20].…”

Section: Exposition Au Cours Du Développement Précoceunclassified

Cannabis et neurodéveloppement

Krebs¹,

Demars²,

Frajerman³

et al. 2020

Bulletin de l'Académie Nationale de Médecine

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Le développement cérébral est un phénomène complexe, qui s'étend de la vie foetale à l'adolescence, pendant laquelle la maturation cérébrale suit une série d'événements ordonnés incluant des périodes critiques de plasticité. Le cerveau est particulièrement sensible à l'environnement pendant ces remaniements. Le système endocannabinoïde participe directement et indirectement à ces processus de plasticité et de maturation. Le delta-9tetrahydrocanabinol, principal composant psychoactif du cannabis, diffuse dans le placenta, le lait maternel et le cerveau. Il interagit avec le système endocannabinoïde, notamment par l'activation des récepteurs aux cannabinoïdes 1 CB1R, ce qui peut entraîner des altérations du neurodéveloppement et du fonctionnement des circuits neuronaux. Par conséquent, l'exposition au cannabis in utero, en période périnatale ainsi qu'à l'adolescence est susceptible d'entraîner des perturbations de la maturation cérébrale dont les conséquences, sur le plan cognitif, psychotique et addictif, persistent bien au-delà de la période d'exposition. Plusieurs facteurs modulent le risque de telles complications mais les études réalisées sur des modèles animaux ainsi que chez l'homme ont montré qu'une exposition durant les phases critiques, en particulier durant la phase de développement périnatal et à l'adolescence, constitue en soi un facteur de risque. Les données actuelles incitent à diffuser une information objective aux jeunes, pour prévenir et limiter les consommations précoces. © 2020 Publié par Elsevier Masson SAS au nom de l'Académie nationale de médecine. ଝ Étant donné le contexte sanitaire épidémique lié au Covid-19 du mois de mars 2020, la présentation orale de cette communication en séance à l'Académie a été reportée.Summary. -Brain development is a complex phenomenon, stretching from fetal life to adolescence, during which brain maturation proceeds through a series of ordered events including critical periods of plasticity. The brain is particularly sensitive to the environment during these changes. The endocannabinoid system participates directly and indirectly in these plasticity and maturation processes. The main psychoactive component of cannabis, the delta-9-tetrahydrocanabinol, can cross the placental barrier, is present in breastmilk and diffuses in the brain. It interacts with the endocannabinoid signaling, especially through the activation of cannabinoid receptors 1 CB1R, which can lead to abnormal neurodevelopmental processes and neuronal circuits functions. Therefore, exposure to cannabis in utero, in perinatal phase, as well as during the adolescence disrupts the brain maturation and can cause disturbances on the cognitive, psychotic and addictive levels that persist far beyond the period of exposure. Several factors modulate the risk of such complications, but studies performed in animal models as well as in human cohorts have shown that exposure during both the critical perinatal and adolescence phases is a risk factor per se. Current knowledge encourages the dissemination of obje...

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Nanoscale Structural Plasticity of the Active Zone Matrix Modulates Presynaptic Function

Cited by 73 publications

References 54 publications

Rapid and Sustained Homeostatic Control of Presynaptic Exocytosis at a Central Synapse

Rapid and Sustained Homeostatic Control of Presynaptic Exocytosis at a Central Synapse

Subsynaptic spatial organization as a regulator of synaptic strength and plasticity

Cannabis et neurodéveloppement

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