Sensory-evoked LTP driven by dendritic plateau potentials in vivo

Gambino, Frédéric; Pagès, Stéphane; Kehayas, Vassilis; Baptista, Daniela; Tatti, Roberta; Carleton, Alan; Holtmaat, Anthony

doi:10.1038/nature13664

Cited by 237 publications

(319 citation statements)

References 40 publications

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“…Given that dendritic spikes are normally suppressed by strong feedforward inhibition(9), the ability of the LRIPs to enhance dendritic spiking during a precise temporal window may contribute to the dendritic spike firing in vivo observed during behaviorally relevant cooperative activity(39). The LRIP-dependent dendritic spikes are likely to participate in the induction of ITDP and the fine-tuning of learning and memory, based on the role of such spikes in both other forms of Ca 2+ -dependent synaptic plasticity(35, 36, 40) and non-linear gain modulation during associative learning(35) and sensory tuning(41). …”

Section: Discussionmentioning

confidence: 99%

Gating of hippocampal activity, plasticity, and memory by entorhinal cortex long-range inhibition

Basu

Zaremba

Cheung

et al. 2016

Science

236

288

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The cortico-hippocampal circuit is critical for storage of associational memories. Most studies have focused on the role in memory storage of the excitatory projections from entorhinal cortex to hippocampus. However, entorhinal cortex also sends inhibitory projections, whose role in memory storage and cortico-hippocampal activity remains largely unexplored. We found that these long-range inhibitory projections enhance the specificity of contextual and object memory encoding. At the circuit level, the GABAergic projections act as a disinhibitory gate that transiently promotes the excitation of hippocampal CA1 pyramidal neurons by suppressing feedforward inhibition. This enhances the ability of CA1 neurons to fire synaptically-evoked dendritic spikes and generate a temporally precise form of heterosynaptic plasticity. Long-range inhibition from entorhinal cortex may thus increase the precision of hippocampal-based longterm memory associations by assessing the salience of mnemonic information to the immediate sensory input.

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Section: Discussionmentioning

confidence: 99%

Gating of hippocampal activity, plasticity, and memory by entorhinal cortex long-range inhibition

Basu

Zaremba

Cheung

et al. 2016

Science

236

288

View full text Add to dashboard Cite

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“…The increased sensitivity to touch in M1P neurons persisted post-training and could be a result of a strengthening or disinhibition of feedforward responses in S1 (refs. [25][26][27][28][29]. During this period the session-to-session response variability of M1P neurons was reduced compared to baseline conditions, suggesting that sensory representation in these neurons was stabilized.…”

Section: Discussionmentioning

confidence: 79%

Pathway-specific reorganization of projection neurons in somatosensory cortex during learning

et al. 2015

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In the mammalian brain, sensory cortices exhibit plasticity during task learning, but how this alters information transferred between connected cortical areas remains unknown. We found that divergent subpopulations of cortico-cortical neurons in mouse whisker primary somatosensory cortex (S1) undergo functional changes reflecting learned behavior. We chronically imaged activity of S1 neurons projecting to secondary somatosensory (S2) or primary motor (M1) cortex in mice learning a texture discrimination task. Mice adopted an active whisking strategy that enhanced texture-related whisker kinematics, correlating with task performance. M1-projecting neurons reliably encoded basic kinematics features, and an additional subset of touch-related neurons was recruited that persisted past training. The number of S2-projecting touch neurons remained constant, but improved their discrimination of trial types through reorganization while developing activity patterns capable of discriminating the animal's decision. We propose that learning-related changes in S1 enhance sensory representations in a pathway-specific manner, providing downstream areas with task-relevant information for behavior.

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“…This fine-scale organization of synaptic inputs had been previously predicted by theoretical studies proposing that synaptic clustering can boost the computational power of a neuron, because it would allow parallel information processing by supra-linear integration of synchronized synaptic inputs in individual dendritic units (Poirazi and Mel, 2001). Since these early predictions, it has been found that supra-linear integration is required for high-level sensory processing (Lavzin et al, 2012;Palmer et al, 2014;Smith et al, 2013) and synaptic plasticity in vivo (Cichon and Gan, 2015;Gambino et al, 2014). Therefore, the clustering of co-active inputs by spontaneous activity could provide the basis for future sensory processing by enabling supra-linear integration.…”

Section: Introductionmentioning

confidence: 86%

Spontaneous Activity Drives Local Synaptic Plasticity In Vivo

Winnubst

Cheyne

Niculescu

et al. 2015

Neuron

169

206

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Spontaneous activity fine-tunes neuronal connections in the developing brain. To explore the underlying synaptic plasticity mechanisms, we monitored naturally occurring changes in spontaneous activity at individual synapses with whole-cell patch-clamp recordings and simultaneous calcium imaging in the mouse visual cortex in vivo. Analyzing activity changes across large populations of synapses revealed a simple and efficient local plasticity rule: synapses that exhibit low synchronicity with nearby neighbors (<12 μm) become depressed in their transmission frequency. Asynchronous electrical stimulation of individual synapses in hippocampal slices showed that this is due to a decrease in synaptic transmission efficiency. Accordingly, experimentally increasing local synchronicity, by stimulating synapses in response to spontaneous activity at neighboring synapses, stabilized synaptic transmission. Finally, blockade of the high-affinity proBDNF receptor p75(NTR) prevented the depression of asynchronously stimulated synapses. Thus, spontaneous activity drives local synaptic plasticity at individual synapses in an "out-of-sync, lose-your-link" fashion through proBDNF/p75(NTR) signaling to refine neuronal connectivity. VIDEO ABSTRACT.

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Sensory-evoked LTP driven by dendritic plateau potentials in vivo

Cited by 237 publications

References 40 publications

Gating of hippocampal activity, plasticity, and memory by entorhinal cortex long-range inhibition

Gating of hippocampal activity, plasticity, and memory by entorhinal cortex long-range inhibition

Pathway-specific reorganization of projection neurons in somatosensory cortex during learning

Spontaneous Activity Drives Local Synaptic Plasticity In Vivo

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