Stefan Remy scite author profile

Before the onset of locomotion, the hippocampus undergoes a transition into an activity-state specialized for the processing of spatially related input. This brain-state transition is associated with increased firing rates of CA1 pyramidal neurons and the occurrence of theta oscillations, which both correlate with locomotion velocity. However, the neural circuit by which locomotor activity is linked to hippocampal oscillations and neuronal firing rates is unresolved. Here we reveal a septo-hippocampal circuit mediated by glutamatergic (VGluT2(+)) neurons that is activated before locomotion onset and that controls the initiation and velocity of locomotion as well as the entrainment of theta oscillations. Moreover, via septo-hippocampal projections onto alveus/oriens interneurons, this circuit regulates feedforward inhibition of Schaffer collateral and perforant path input to CA1 pyramidal neurons in a locomotion-dependent manner. With higher locomotion speed, the increased activity of medial septal VGluT2 neurons is translated into increased axo-somatic depolarization and higher firing rates of CA1 pyramidal neurons. VIDEO ABSTRACT.

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Dendritic Structural Degeneration Is Functionally Linked to Cellular Hyperexcitability in a Mouse Model of Alzheimer’s Disease

Šišková

Justus

Kaneko

et al. 2014

Neuron

267

236

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Dendritic structure critically determines the electrical properties of neurons and, thereby, defines the fundamental process of input-to-output conversion. The diversity of dendritic architectures enables neurons to fulfill their specialized circuit functions during cognitive processes. It is known that this dendritic integrity is impaired in patients with Alzheimer's disease and in relevant mouse models. It is unknown, however, whether this structural degeneration translates into aberrant neuronal function. Here we use in vivo whole-cell patch-clamp recordings, high-resolution STED imaging, and computational modeling of CA1 pyramidal neurons in a mouse model of Alzheimer's disease to show that structural degeneration and neuronal hyperexcitability are crucially linked. Our results demonstrate that a structure-dependent amplification of synaptic input to action potential output conversion might constitute a novel cellular pathomechanism underlying network dysfunction with potential relevance for other neurodegenerative diseases with abnormal changes of dendritic morphology.

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Proximal Persistent Na⁺Channels Drive Spike Afterdepolarizations and Associated Bursting in Adult CA1 Pyramidal Cells

Yue¹,

Remy²,

Su³

et al. 2005

J. Neurosci.

176

253

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In many principal brain neurons, the fast, all-or-none Na ϩ spike initiated at the proximal axon is followed by a slow, graded afterdepolarization (ADP). The spike ADP is critically important in determining the firing mode of many neurons; large ADPs cause neurons to fire bursts of spikes rather than solitary spikes. Nonetheless, not much is known about how and where spike ADPs are initiated. We addressed these questions in adult CA1 pyramidal cells, which manifest conspicuous somatic spike ADPs and an associated propensity for bursting, using sharp and patch microelectrode recordings in acutely isolated hippocampal slices and single neurons. Voltage-clamp commands mimicking spike waveforms evoked transient Na ϩ spike currents that declined quickly after the spike but were followed by substantial sustained Na ϩ spike aftercurrents. Drugs that blocked the persistent Na ϩ current (I NaP ), markedly suppressed the sustained Na ϩ spike aftercurrents, as well as spike ADPs and associated bursting. Ca 2ϩ spike aftercurrents were much smaller, and reducing them had no noticeable effect on the spike ADPs. Truncating the apical dendrites affected neither spike ADPs nor the firing modes of these neurons. Application of I NaP blockers to truncated neurons, or their focal application to the somatic region of intact neurons, suppressed spike ADPs and associated bursting, whereas their focal application to distal dendrites did not. We conclude that the somatic spike ADPs are generated predominantly by persistent Na ϩ channels located at or near the soma. Through this action, proximal I NaP critically determines the firing mode and spike output of adult CA1 pyramidal cells.

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Dendritic Integration in Hippocampal Dentate Granule Cells

Krueppel

Remy

Beck

2011

Neuron

197

227

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Hippocampal granule cells are important relay stations that transfer information from the entorhinal cortex into the hippocampus proper. This process is critically determined by the integrative properties of granule cell dendrites. However, their small diameter has so far hampered efforts to examine their properties directly. Using a combination of dual somatodendritic patch-clamp recordings and multiphoton glutamate uncaging, we now show that the integrative properties of granule cell dendrites differ substantially from other principal neurons. Due to a very strong dendritic voltage attenuation, the impact of individual synapses on granule cell output is low. At the same time, integration is linearized by voltage-dependent boosting mechanisms, only weakly affected by input synchrony, and independent of input location. These experiments establish that dentate granule cell dendritic properties are optimized for linear integration and strong attenuation of synaptic input from the entorhinal cortex, which may contribute to the sparse activity of granule cells in vivo.

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Stefan Remy

Locomotion, Theta Oscillations, and the Speed-Correlated Firing of Hippocampal Neurons Are Controlled by a Medial Septal Glutamatergic Circuit

Dendritic Structural Degeneration Is Functionally Linked to Cellular Hyperexcitability in a Mouse Model of Alzheimer’s Disease

Proximal Persistent Na⁺Channels Drive Spike Afterdepolarizations and Associated Bursting in Adult CA1 Pyramidal Cells

Dendritic Integration in Hippocampal Dentate Granule Cells

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Stefan Remy

Locomotion, Theta Oscillations, and the Speed-Correlated Firing of Hippocampal Neurons Are Controlled by a Medial Septal Glutamatergic Circuit

Dendritic Structural Degeneration Is Functionally Linked to Cellular Hyperexcitability in a Mouse Model of Alzheimer’s Disease

Proximal Persistent Na+Channels Drive Spike Afterdepolarizations and Associated Bursting in Adult CA1 Pyramidal Cells

Dendritic Integration in Hippocampal Dentate Granule Cells

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Product

Resources

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Proximal Persistent Na⁺Channels Drive Spike Afterdepolarizations and Associated Bursting in Adult CA1 Pyramidal Cells