Rebound spiking in layer II medial entorhinal cortex stellate cells: Possible mechanism of grid cell function

Shay, Christopher F.; Ferrante, Mauro; Chapman, G. William; Hasselmo, Michael E.

doi:10.1016/j.nlm.2015.09.004

Cited by 30 publications

(31 citation statements)

References 72 publications

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“…This model is also supported by some aspects of intracellular physiological data, including the difference in the frequency of resonance and subthreshold membrane potential oscillations for entorhinal neurons at different anatomical positions that has been extensively replicated (Boehlen et al, 2010;Dodson et al, 2011;Giocomo and Hasselmo, 2008a;Giocomo and Hasselmo, 2008b;Giocomo and Hasselmo, 2009;Heys et al, 2010;Pastoll et al, 2012;Shay et al, 2012). Resonance correlates with the time course of rebound from hyperpolarization, and rebound spiking might contribute to grid cell firing Shay et al, 2016).…”

Section: Theta Rhythm and The Coding Of Running Speedmentioning

confidence: 53%

Reconciling the different faces of hippocampal theta: The role of theta oscillations in cognitive, emotional and innate behaviors

Korotkova

Ponomarenko

Monaghan

et al. 2018

Neuroscience & Biobehavioral Reviews

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115

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The theta oscillation (5-10Hz) is a prominent behavior-specific brain rhythm. This review summarizes studies showing the multifaceted role of theta rhythm in cognitive functions, including spatial coding, time coding and memory, exploratory locomotion and anxiety-related behaviors. We describe how activity of hippocampal theta rhythm generators - medial septum, nucleus incertus and entorhinal cortex, links theta with specific behaviors. We review evidence for functions of the theta-rhythmic signaling to subcortical targets, including lateral septum. Further, we describe functional associations of theta oscillation properties - phase, frequency and amplitude - with memory, locomotion and anxiety, and outline how manipulations of these features, using optogenetics or pharmacology, affect associative and innate behaviors. We discuss work linking cognition to the slope of the theta frequency to running speed regression, and emotion-sensitivity (anxiolysis) to its y-intercept. Finally, we describe parallel emergence of theta oscillations, theta-mediated neuronal activity and behaviors during development. This review highlights a complex interplay of neuronal circuits and synchronization features, which enables an adaptive regulation of multiple behaviors by theta-rhythmic signaling.

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Section: Theta Rhythm and The Coding Of Running Speedmentioning

confidence: 53%

Reconciling the different faces of hippocampal theta: The role of theta oscillations in cognitive, emotional and innate behaviors

Korotkova

Ponomarenko

Monaghan

et al. 2018

Neuroscience & Biobehavioral Reviews

Self Cite

115

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“…Stellate cells show subthreshold membrane potential oscillations and generate rebound spikes when released from inhibition 21 (Figure 1a). We modeled these properties using a hyperpolarization activated depolarizing current (Ih) 22,23 and an amplifying persistent sodium current (I NaP ) 24 in addition to leak and spiking currents (I L , I Na and I K ). We modeled interneurons using modified sodium and potassium currents that allowed it to spike at high frequency 20 .…”

Section: Resultsmentioning

confidence: 99%

Theta oscillations gate the transmission of reliable sequences in the medial entorhinal cortex

Neru

Assisi

2019

Preprint

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Reliable sequential activity of neurons in the entorhinal cortex is necessary to encode spatially guided behavior and memory. In a realistic computational model of a medial entorhinal cortex (MEC) microcircuit, with stellate cells coupled via a network of inhibitory interneurons, we show how intrinsic and network mechanisms interact with theta oscillations to generate reliable outputs. Sensory inputs activate interneurons near their most excitable phase during each theta cycle. As the inputs change, different groups of interneurons are recruited and postsynaptic stellate cells are released from inhibition causing a sequence of rebound spikes. Since the rebound time scale of stellate cells matches theta oscillations, its spikes get relegated to the least excitable phase of theta ensuring that the network encodes only the external drive and ignores recurrent excitation by rebound spikes. In the absence of theta, rebound spikes compete with external inputs and disrupt the sequence that follows.Our simulations concur with experimental data that show, subduing theta oscillations disrupts the spatial periodicity of grid cell receptive fields. Further, the same mechanism where theta modulates the gain of incoming inputs may be used to select between competing sources of input and create transient functionally connected networks. * collins@iiserpune.ac.in

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“…Because of the predominance of inhibitory network interactions within layer II of the MEC (Dhillon & Jones, ; Couey et al ., ) and the h‐current present in stellate cells (Dickson et al ., ; Heys et al ., ; Heys & Hasselmo, ; Tsuno et al ., ), it was proposed that inhibition enhances the excitation and firing of entorhinal neurons in a timely manner via rebound spikes (Hasselmo, ; Shay et al ., ). This possibility is supported by the current study of hyperpolarizing current stimulation with sinusoidal input in vivo .…”

Section: Discussionmentioning

confidence: 97%

“…The relationship between the amplitude or duration of hyperpolarizing current stimulation and the temporal delay of rebound spikes after stimulation has been described in in vitro recordings of MEC neurons (Ferrante et al ., ), suggesting a possible mechanism for regulating rebound spike timing by running speed. Recent studies also suggest that there is a relationship between the oscillation phase of hyperpolarizing current stimulation and subsequent spike probabilities at the peak of the oscillation in MEC layer II stellate cells in in vitro slice preparations (Shay et al ., ), suggesting a mechanism for phase precession and for maintaining select subpopulations of neurons active due to inhibition occurring at a specific phase of theta rhythm oscillations.…”

Section: Introductionmentioning

confidence: 99%

Rebound spiking properties of mouse medial entorhinal cortex neurons in vivo

Tsuno

Chapman

Hasselmo

2015

Eur J of Neuroscience

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Medial entorhinal cortex is the gateway between cortex and hippocampus, and plays a critical role for spatial coding as represented by grid cell activity. In the medial entorhinal cortex, inhibitory circuits are robust, and the presence of h-current leads to rebound potentials and rebound spiking in in vitro experiments. It has been hypothesized that these properties, combined with local field potential oscillations, may contribute to grid cell formation. To examine the properties of in vivo rebound spikes, we performed whole cell patch clamp recordings in medial entorhinal cortex neurons in anesthetized mice. We injected hyperpolarizing inputs representing inhibitory synaptic inputs with sinusoidal oscillations and found that hyperpolarizing inputs injected at specific phases of oscillation had higher probability of inducing subsequent spikes at the peak of the oscillation in some neurons. Also, this effect was prominent in the cells with large sag potential which is a marker of h-current. In addition, larger and longer hyperpolarizing current square pulse stimulation resulted in a larger probability of eliciting rebound spikes. We did not observe a relationship between amplitude or duration of hyperpolarizing current pulse stimulation and the delay of rebound spikes. These results suggest that rebound spikes are observed in vivo and may play a role in generating grid cell activity in medial entorhinal cortex neurons.

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Rebound spiking in layer II medial entorhinal cortex stellate cells: Possible mechanism of grid cell function

Cited by 30 publications

References 72 publications

Reconciling the different faces of hippocampal theta: The role of theta oscillations in cognitive, emotional and innate behaviors

Reconciling the different faces of hippocampal theta: The role of theta oscillations in cognitive, emotional and innate behaviors

Theta oscillations gate the transmission of reliable sequences in the medial entorhinal cortex

Rebound spiking properties of mouse medial entorhinal cortex neurons in vivo

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