Surface Mobility of Postsynaptic AMPARs Tunes Synaptic Transmission

Heisenberg, Martin; Groc, Laurent; Frischknecht, Renato; Béïque, Jean Claude; Lounis, Brahim; Rumbaugh, Gavin; Huganir, Richard L.; Cognet, Laurent; Choquet, Daniel

doi:10.1126/science.1152089

Cited by 444 publications

(540 citation statements)

References 43 publications

(67 reference statements)

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“…Preparation of cultured neurons for single particle tracking has been done as previously described (31). Hippocampal neurons from 18 d old rat embryos were cultured on glass coverslips following the Banker protocol.…”

Section: Methodsmentioning

confidence: 99%

Heterogeneity of AMPA receptor trafficking and molecular interactions revealed by superresolution analysis of live cell imaging

Hozé

Nair

Hosy

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Simultaneous tracking of many thousands of individual particles in live cells is possible now with the advent of high-density superresolution imaging methods. We present an approach to extract local biophysical properties of cell-particle interaction from such newly acquired large collection of data. Because classical methods do not keep the spatial localization of individual trajectories, it is not possible to access localized biophysical parameters. In contrast, by combining the high-density superresolution imaging data with the present analysis, we determine the local properties of protein dynamics. We specifically focus on AMPA receptor (AMPAR) trafficking and estimate the strength of their molecular interaction at the subdiffraction level in hippocampal dendrites. These interactions correspond to attracting potential wells of large size, showing that the high density of AMPARs is generated by physical interactions with an ensemble of cooperative membrane surface binding sites, rather than molecular crowding or aggregation, which is the case for the membrane viral glycoprotein VSVG. We further show that AMPARs can either be pushed in or out of dendritic spines. Finally, we characterize the recurrent step of influenza trajectories. To conclude, the present analysis allows the identification of the molecular organization responsible for the heterogeneities of random trajectories in cells.stochastic analysis of trajectories | dendritic spines and synapses | single particle tracking | confined diffusion R egulation of cellular physiological processes such as synaptic transmission, signal transduction relies on molecular interactions (binding and unbinding) at specific places and involves trafficking in confined local microdomains. The efficiency of these regulations crucially depends on the underlying molecular spatial organization, the study of which remains a daunting hurdle in cellular biology. Interestingly, superresolution light optical microscopy techniques for in vivo data (1-3) have allowed monitoring a large number of molecular trajectories at the single molecule level and at nanometer resolution, that can potentially reveal unique cellular organizational features. In the recent years, various techniques based on empirical characterization have emerged to track receptors (4), and estimating the mean square displacement (MSD) along isolated trajectories allowed to differentiate between free and confined diffusion (5, 6). In addition, although a large effort was dedicated to developing single molecule tracking algorithms (5, 7, 8), a general method for the analysis of the massive collection of data and for the extraction of quantitative local information is still lacking.In this article, we derive from the classical stochastic description at a molecular level, a method to extract biophysical features from high throughput superresolution data, associated with AMPA receptor (AMPAR) trafficking on neuronal cells. Indeed, neurons are organized in local microdomains characterized by morphological and functiona...

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Section: Methodsmentioning

confidence: 99%

Heterogeneity of AMPA receptor trafficking and molecular interactions revealed by superresolution analysis of live cell imaging

Hozé

Nair

Hosy

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

135

253

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“…Local rises in intracellular calcium can significantly reduce AMPAR mobility (Borgdorff and Choquet, 2002;Heine et al, 2008) and ligand-induced activation of ␣7-nAChRs can elevate intracellular calcium (Séguéla et al, 1993;Dajas-Bailador and Wonnacott, 2004). To determine whether elevation of intracellular calcium is necessary for the nicotine effects on AMPAR trafficking, we treated cultures with BAPTA-AM, a calcium chelator that only buffers calcium intracellularly.…”

Section: Nicotine-induced Effects On Glua1 Trafficking Depend On Calcmentioning

confidence: 99%

A Novel Mechanism for Nicotinic Potentiation of Glutamatergic Synapses

et al. 2014

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Selective strengthening of specific glutamatergic synapses in the mammalian hippocampus is critical for encoding new memories. This is most commonly achieved by input-specific Hebbian-type plasticity involving glutamate-dependent coincident presynaptic and postsynaptic depolarization. Our results demonstrate a novel mechanism by which nicotinic signaling, independently of coincident fast glutamatergic transmission, increases synaptic strength in the hippocampus. Electrophysiological recordings from rat hippocampal neurons in culture revealed that 1-3 h of exposure to 1 m nicotine, even with action potentials being blocked, produced increases in both the frequency and amplitude of miniature EPSCs. Possible mechanisms were analyzed both in mouse organotypic slice culture and in rat cell

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“…However, even though structural stability of networks acquired during developmental phases is essential for neuronal efficiency, mechanisms allowing synaptic remodeling are key events during learning and memory formation throughout life (13). We recently demonstrated that endogenous proteases moderately digesting specific components of the ECM are regulated in an activity-dependent manner (2,14) and ECM removal modulates synaptic short-term plasticity by synaptic exchange of postsynaptic glutamate receptors (10,15). Further, ECM modulation enhances synaptic short-term plasticity by affecting voltage-dependent calcium channels (9).…”

mentioning

confidence: 99%

Enhanced cognitive flexibility in reversal learning induced by removal of the extracellular matrix in auditory cortex

Happel

Niekisch²,

Rivera³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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During brain maturation, the occurrence of the extracellular matrix (ECM) terminates juvenile plasticity by mediating structural stability. Interestingly, enzymatic removal of the ECM restores juvenile forms of plasticity, as for instance demonstrated by topographical reconnectivity in sensory pathways. However, to which degree the mature ECM is a compromise between stability and flexibility in the adult brain impacting synaptic plasticity as a fundamental basis for learning, lifelong memory formation, and higher cognitive functions is largely unknown. In this study, we removed the ECM in the auditory cortex of adult Mongolian gerbils during specific phases of cortex-dependent auditory relearning, which was induced by the contingency reversal of a frequency-modulated tone discrimination, a task requiring high behavioral flexibility. We found that ECM removal promoted a significant increase in relearning performance, without erasing already establishedthat is, learned-capacities when continuing discrimination training. The cognitive flexibility required for reversal learning of previously acquired behavioral habits, commonly understood to mainly rely on frontostriatal circuits, was enhanced by promoting synaptic plasticity via ECM removal within the sensory cortex. Our findings further suggest experimental modulation of the cortical ECM as a tool to open short-term windows of enhanced activitydependent reorganization allowing for guided neuroplasticity.chondroitin sulfate proteoglycan | hyaluronidase | perineuronal net | intracortical microinjection | strategy change S tructural remodeling and stabilization of synaptic networks are key mechanisms underlying learning in the adult brain. During early life, high structural and functional plasticity is required for the experience-shaped development of basic neuronal circuits (1). With brain maturation, juvenile plasticity of so-called critical or sensitive periods is decreased and is accompanied by the appearance of the brain's extracellular matrix (ECM) and its specialized compact form named "perineuronal net" (PNN) enwrappping cell bodies and synaptic contacts (2, 3). Enzymatic degradation of the ECM in adult animals has been demonstrated to restore such forms of developmental (juvenile) plasticity with respect to topographical map plasticity in the visual cortex (4), fearresponse-mediating circuits in the amygdala (5), spinal cord injuries (6, 7), and song learning circuits of zebra finches (8). In addition, enzymatic ECM removal altered several forms of synaptic plasticity in vitro and in vivo (9-12). However, even though structural stability of networks acquired during developmental phases is essential for neuronal efficiency, mechanisms allowing synaptic remodeling are key events during learning and memory formation throughout life (13). We recently demonstrated that endogenous proteases moderately digesting specific components of the ECM are regulated in an activity-dependent manner (2, 14) and ECM removal modulates synaptic short-term plasticity by synaptic e...

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Surface Mobility of Postsynaptic AMPARs Tunes Synaptic Transmission

Cited by 444 publications

References 43 publications

Heterogeneity of AMPA receptor trafficking and molecular interactions revealed by superresolution analysis of live cell imaging

Heterogeneity of AMPA receptor trafficking and molecular interactions revealed by superresolution analysis of live cell imaging

A Novel Mechanism for Nicotinic Potentiation of Glutamatergic Synapses

Enhanced cognitive flexibility in reversal learning induced by removal of the extracellular matrix in auditory cortex

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