Short-term synaptic plasticity is modulated by long-term synaptic

changes. There is, however, no general agreement on the computational

role of this interaction. Here, we derive a learning rule for the release

probability and the maximal synaptic conductance in a circuit model

with combined recurrent and feedforward connections that allows learning

to discriminate among natural inputs. Short-term synaptic plasticity

thereby provides a nonlinear expansion of the input space of a linear

classifier, whereas the random recurrent network serves to decorrelate

the expanded input space. Computer simulations reveal that the twofold

increase in the number of input dimensions through short-term synaptic

plasticity improves the performance of a standard perceptron up to 100%.

The distributions of release probabilities and maximal synaptic conductances

at the capacity limit strongly depend on the balance between excitation

and inhibition. The model also suggests a new computational

interpretation of spikes evoked by stimuli outside the classical receptive

field. These neuronal activitiesmay reflect decorrelation of the expanded

stimulus space by intracortical synaptic connections

Gundlfinger, Anja

Kempter, Richard

Leibold, Christian

Schmitz, Dietmar

Thurley, Kay

English

Phase precession is a relational code that is thought to be important for episodic-like memory, for instance, the learning of a sequence of places. In the hippocampus, places are encoded through bursting activity of so-called place cells. The spikes in such a burst exhibit a precession of their firing phases relative to field potential theta oscillations (4–12 Hz); the theta phase of action potentials in successive theta cycles progressively decreases toward earlier phases. The mechanisms underlying the generation of phase precession are, however, unknown. In this letter, we show through mathematical analysis and numerical simulations that synaptic facilitation in combination with membrane potential oscillations of a neuron gives rise to phase precession. This biologically plausible model reproduces experimentally observed features of phase precession, such as (1) the progressive decrease of spike phases, (2) the nonlinear and often also bimodal relation between spike phases and the animal's place, (3) the range of phase precession being smaller than one theta cycle, and (4) the dependence of phase jitter on the animal's location within the place field. The model suggests that the peculiar features of the hippocampal mossy fiber synapse, such as its large efficacy, long-lasting and strong facilitation, and its phase-locked activation, are essential for phase precession in the CA3 region of the hippocampus

Open Access LMU ( Ludwig-Maximilians-Univ. München)

A learning rule for place ﬁelds in a cortical model: Theta phase precession as a network effect.

A theory of hippocampal memory based on theta phase precession.

A uniﬁed view of theta-phase coding in the entorhinal-hippocampal system.

Coding and learning of behavioural sequences.

Computational constraints suggest the need for two distinct input systems to the hippocampal CA3 network.

Computational theories on the function of theta oscillations.

Conditional dendritic spike propagation following distal synaptic activation of hippocampal CA1 pyramidal neurons.

Contrasting properties of two forms of longterm potentiation in the hippocampus.

Critical role of the hippocampus in memory for sequences of events.

Dendritic mechanisms of phase precession in hippocampal CA1 pyramidal neurons.

Differential mechanisms of transmission at three types of mossy ﬁber synapse.

Differential modulation of short-term synaptic dynamics by long-term potentiation at mouse hippocampal mossy ﬁbre synapse.

Distinct short-term plasticity at two excitatory synapses in the hippocampus.

Dynamic ﬁltering of recognition memory codes in the hippocampus.

Dynamically detuned oscillations account for the coupled rate and temporal code of place cell ﬁring.

EPSP ampliﬁcation and the precision of spike timing in hippocampal neurons.

Experience-dependent dynamics of spatiotemporal precision and synchrony in place cells.

Experience-dependent, asymmetric shape of hippocampal receptive ﬁelds.

G e i s l e r ,C . ,R o b b e ,D . ,Z u g a r o ,M . ,S i r o t a ,A . ,&B u z s ´

Heterogeneity among hippocampal pyramidal neurons revealed by their relation to theta-band oscillation and synchrony.

Hippocampal CA3 region predicts memory sequences: Accounting for the phase precession of place cells.

Hippocampal granule cells are necessary for normal spatial learning but not for spatiallyselective pyramidal cell discharge.

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Impaired learning in mice with abnormal short-lived plasticity.

Independent rate and temporal coding in hippocampal pyramidal cells.

Infrapyramidal mossy ﬁbers and two-way avoidance learning: Developmental modiﬁcation of hippocampal circuitry and adult behavior of rats and mice.

Intracellular correlates of hippocampal theta rhythm in identiﬁed pyramidal cells, granule cells and basket cells.

Intrinsic cellular currents and the temporal precision of EPSP-action potential coupling in CA1 pyramidal cells.

Memory encoding by theta phase precession in the hippocampal network.

Network and intrinsic cellular mechanisms underlying theta phase precession of hippocampal neurons.

Neural mechanisms for generating rate and temporal codes in model CA3 pyramidal cells.

NMDA receptor antagonism blocks experience-dependent expansion of hippocampal “place ﬁelds”.

Organization of hippocampal cell assemblies based on theta phase precession.

Oscillatory coupling of hippocampal pyramidal cells and interneurons in the behaving rat.

Path integration and the neural basis of the “cognitive map.”

Pattern recognition computation using action potential timing for stimulus representation.

Phase precession and phase-locking of hippocampal pyramidal cells.

Phase precession as an experience independent process:Phase Precession Through Synaptic Facilitation 1323 Hippocampal pyramidal cell phase precession in a novel environment and under NMDA-receptor blockade.

Phase precession in hippocampal interneurons showing strong functional coupling to individual pyramidal cells.

Phase relationship between hippocampal place units and EEG theta rhythm.

Physiological gain leads to high ISI variability in a simple model of a cortical regular spiking cell.

Place cells and place recognition maintained by direct entorhinalhippocampal circuitry.

Population dynamics and theta phase precession of hippocampal place cell ﬁring: A spiking neuron model.

Quantal components of unitary EPSCs at the mossy ﬁber synapse on CA3 pyramidal cells of rat hippocampus.

Reading neuronal synchrony with depressing synapses.

Real-time computing without stable states: A new framework for neural computation based on perturbations.

Recall of memory sequences by interaction of the dentate and CA3: A revised model of the phase precession.

Revisiting the role of the hippocampal mossy ﬁber synapse.

Role of experience and oscillations in transforming a rate code into a temporal code.

Short-term synaptic plasticity.

Spatial selectivity of unit activity in the hippocampal granular layer.

Spike phase precession persists after transient intrahippocampal perturbation.

Spike-based synaptic plasticity and the emergence of direction selective simple cells: Simulation results.

Synaptic computation.

Synaptic plasticity at hippocampal mossy ﬁbre synapses.

Temporal encoding of place sequences by hippocampal cell assemblies.

Temporal information transformed into a spatial code by a neural network with realistic properties.

The effect of dynamic synapses on spatiotemporal receptive ﬁelds in visual cortex.

The hippocampus as a spatial map: Preliminary evidence from unit activity in the freely-moving rat.

The neural code between neocortical pyramidal neurons depends on neurotransmitter release probability.

The role of the hippocampus in memory for the temporal order of a sequence of odors.

Theta modulation and phase precession in grid cells in the medial entorhinal cortex.

Theta oscillation-coupled dendritic spiking integrates input on a long time scale.

Theta oscillations in somataanddendritesofhippocampalpyramidalcellsinvivo:Activity-dependent phase-precession of action potentials.

Theta oscillations in the hippocampus.

Theta phase precession in hippocampal neuronal populations and the compression of temporal sequences.

Theta-frequency dependence and phase-place correlations in models of hippocampal phase precession.

Whole-cell recordings in freely moving rats.

Phase Precession Through Synaptic Facilitation

Phase precession is a relational code that is thought to be important for episodic-like memory, for instance, the learning of a sequence of places. In the hippocampus, places are encoded through bursting activity of so-called place cells. The spikes in such a burst exhibit a precession of their firing phases relative to field potential theta oscillations (4-12 Hz); the theta phase of action potentials in successive theta cycles progressively decreases toward earlier phases. The mechanisms underlying the generation of phase precession are, however, unknown. In this letter, we show through mathematical analysis and numerical simulations that synaptic facilitation in combination with membrane potential oscillations of a neuron gives rise to phase precession. This biologically plausible model reproduces experimentally observed features of phase precession, such as (1) the progressive decrease of spike phases, (2) the nonlinear and often also bimodal relation between spike phases and the animal's place, (3) the range of phase precession being smaller than one theta cycle, and (4) the dependence of phase jitter on the animal's location within the place field. The model suggests that the peculiar features of the hippocampal mossy fiber synapse, such as its large efficacy, long-lasting and strong facilitation, and its phase-locked activation, are essential for phase precession in the CA3 region of the hippocampus

Thurley, K.

Leibold, C.

Gundlfinger, A.

Schmitz, D.

Kempter, R.

MDC Repository

Phase precession through synaptic facilitation

Universität München: Elektronischen Publikationen

Christian Leibold

Michael H. K. Bendels

Hertz J.

Vapnik V.

Crossref