Low-Probability Transmission of Neocortical and Entorhinal Impulses Through the Perirhinal Cortex

2004 ◽  
Vol 91 (5) ◽  
pp. 2079-2089 ◽  
Author(s):  
Joe Guillaume Pelletier ◽  
John Apergis ◽  
Denis Paré
Keyword(s):  
Hippocampal Neurons ◽  
Slow Wave Sleep ◽  
Time Window ◽  
Activity Patterns ◽  
Perirhinal Cortex ◽  
Sharp Waves ◽  
Low Probability ◽  
Unanesthetized Animals ◽  
Artificial Nature ◽  
Electrical Stimuli

One model of episodic memory posits that during slow-wave sleep (SWS), the synchronized discharges of hippocampal neurons in relation to sharp waves “replay” activity patterns that occurred during the waking state, facilitating synaptic plasticity in the neocortex. Although evidence of replay was found in the hippocampus in relation to sharp waves, it was never shown that this activity reached the neocortex. Instead, it was assumed that the rhinal cortices faithfully transmit information from the hippocampus to the neocortex and reciprocally. Here, we tested this idea using 3 different approaches. 1) Stimulating electrodes were inserted in the entorhinal cortex and temporal neocortex and evoked unit responses were recorded in between them, in the intervening rhinal cortices. In these conditions, impulse transfer occurred with an extremely low probability, in both directions. 2) To rule out the possibility that this unreliable transmission resulted from the artificial nature of electrical stimuli, crosscorrelation analyses of spontaneous neocortical, perirhinal, and entorhinal firing were performed in unanesthetized animals during the states of waking and SWS. Again, little evidence of propagation could be obtained in either state. 3) To test the idea that propagation occurs only when large groups of neurons are activated within a narrow time window, we computed perievent histograms of neocortical, perirhinal, and entorhinal neuronal discharges around large-amplitude sharp waves. However, these synchronized entorhinal discharges also failed to propagate across the perirhinal cortex. These findings suggest that the rhinal cortices are more than a relay between the neocortex and hippocampus, but rather a gate whose properties remain to be identified.

scholarly journals Sharp wave-associated activity patterns of olfactory cortical neurons in the mouse piriform cortex

2018 ◽  
Author(s):  
Kazuki Katori ◽  
Hiroyuki Manabe ◽  
Ai Nakashima ◽  
Eer Dunfu ◽  
Takuya Sasaki ◽  
...  
Keyword(s):  
Cortical Neurons ◽  
Slow Wave Sleep ◽  
Activity Patterns ◽  
Piriform Cortex ◽  
Associative Memories ◽  
Firing Rates ◽  
Anterior Piriform Cortex ◽  
Sharp Wave ◽  
Sharp Waves ◽  
Neural Activities

ABSTRACTThe olfactory piriform cortex is thought to participate in olfactory associative memory. Like the hippocampus, which is essential for episodic memory, it belongs to an evolutionally conserved paleocortex and comprises a three-layered cortical structure. During slow-wave sleep, the olfactory piriform cortex becomes less responsive to external odor stimuli and instead displays sharp wave (SPW) activity similar to that observed in the hippocampus. Neural activity patterns during hippocampal SPW have been intensively studied in terms of memory consolidation; however, little is known about the activity patterns of olfactory cortical neurons during olfactory cortex sharp waves (OC-SPWs). In this study, we recorded multi-unit neural activities in the anterior piriform cortex in urethane-anesthetized mice. We found that the activity patterns of olfactory cortical neurons during OC-SPWs were non-randomly organized. Individual olfactory cortical neurons varied in the timings of their peak firing rates during OC-SPW events. Moreover, specific pairs of olfactory cortical neurons were more frequently activated together than expected by chance. On the basis of these observations, we speculate that coordinated activation of specific subsets of olfactory cortical neurons repeats during OC-SPWs, thereby facilitating synaptic plasticity underlying the consolidation of olfactory associative memories.

scholarly journals Hippocampal neurons with stable excitatory connectivity become part of neuronal representations

PLoS Biology ◽  
2020 ◽  
Vol 18 (11) ◽  
pp. e3000928 ◽  
Author(s):  
Tim P. Castello-Waldow ◽  
Ghabiba Weston ◽  
Alessandro F. Ulivi ◽  
Alireza Chenani ◽  
Yonatan Loewenstein ◽  
...  
Keyword(s):  
Hippocampal Neurons ◽  
Pyramidal Neurons ◽  
Time Window ◽  
Structural Connectivity ◽  
Time Lapse ◽  
Early Gene ◽  
Synaptic Connectivity ◽  
Time Duration ◽  
Hippocampal Ca1 ◽  
Cornu Ammonis

Experiences are represented in the brain by patterns of neuronal activity. Ensembles of neurons representing experience undergo activity-dependent plasticity and are important for learning and recall. They are thus considered cellular engrams of memory. Yet, the cellular events that bias neurons to become part of a neuronal representation are largely unknown. In rodents, turnover of structural connectivity has been proposed to underlie the turnover of neuronal representations and also to be a cellular mechanism defining the time duration for which memories are stored in the hippocampus. If these hypotheses are true, structural dynamics of connectivity should be involved in the formation of neuronal representations and concurrently important for learning and recall. To tackle these questions, we used deep-brain 2-photon (2P) time-lapse imaging in transgenic mice in which neurons expressing the Immediate Early Gene (IEG) Arc (activity-regulated cytoskeleton-associated protein) could be permanently labeled during a specific time window. This enabled us to investigate the dynamics of excitatory synaptic connectivity—using dendritic spines as proxies—of hippocampal CA1 (cornu ammonis 1) pyramidal neurons (PNs) becoming part of neuronal representations exploiting Arc as an indicator of being part of neuronal representations. We discovered that neurons that will prospectively express Arc have slower turnover of synaptic connectivity, thus suggesting that synaptic stability prior to experience can bias neurons to become part of representations or possibly engrams. We also found a negative correlation between stability of structural synaptic connectivity and the ability to recall features of a hippocampal-dependent memory, which suggests that faster structural turnover in hippocampal CA1 might be functional for memory.

scholarly journals Operant Conditioning of Synaptic and Spiking Activity Patterns in Single Hippocampal Neurons

2014 ◽  
Vol 34 (14) ◽  
pp. 5044-5053 ◽  
Author(s):  
Daisuke Ishikawa ◽  
Nobuyoshi Matsumoto ◽  
Tetsuya Sakaguchi ◽  
Norio Matsuki ◽  
Yuji Ikegaya
Keyword(s):  
Operant Conditioning ◽  
Hippocampal Neurons ◽  
Activity Patterns ◽  
Spiking Activity

scholarly journals Similarity of fMRI Activity Patterns in Left Perirhinal Cortex Reflects Semantic Similarity between Words

2013 ◽  
Vol 33 (47) ◽  
pp. 18597-18607 ◽  
Author(s):  
R. Bruffaerts ◽  
P. Dupont ◽  
R. Peeters ◽  
S. De Deyne ◽  
G. Storms ◽  
...  
Keyword(s):  
Semantic Similarity ◽  
Activity Patterns ◽  
Perirhinal Cortex

scholarly journals An In Vitro Model of Hippocampal Sharp Waves: Regional Initiation and Intracellular Correlates

2005 ◽  
Vol 94 (1) ◽  
pp. 741-753 ◽  
Author(s):  
Chiping Wu ◽  
Marjan Nassiri Asl ◽  
Jesse Gillis ◽  
Frances K. Skinner ◽  
Liang Zhang
Keyword(s):  
Dentate Gyrus ◽  
Large Amplitude ◽  
Pyramidal Neurons ◽  
Slow Wave Sleep ◽  
Hippocampal Slices ◽  
Field Potentials ◽  
Sharp Wave ◽  
Sharp Waves ◽  
Hippocampal Circuitry

During slow wave sleep and consummatory behaviors, electroencephalographic recordings from the rodent hippocampus reveal large amplitude potentials called sharp waves. The sharp waves originate from the CA3 circuitry and their generation is correlated with coherent discharges of CA3 pyramidal neurons and dependent on activities mediated by AMPA glutamate receptors. To model sharp waves in a relatively large hippocampal circuitry in vitro, we developed thick (1 mm) mouse hippocampal slices by separating the dentate gyrus from the CA2/CA1 areas while keeping the functional dentate gyrus-CA3-CA1 connections. We found that large amplitude (0.3–3 mV) sharp wave-like field potentials occurred spontaneously in the thick slices without extra ionic or pharmacological manipulation and they resemble closely electroencephalographic sharp waves with respect to waveform, regional initiation, pharmacological manipulations, and intracellular correlates. Through measuring tissue O2, K+, and synaptic and single cell activities, we verified that the sharp wave-like potentials are not a consequence of anoxia, nonspecific elevation of extracellular K+ and dissection-related tissue damage. Our data suggest that a subtle but crucial increase in the CA3 glutamatergic activity effectively recruits a population of neurons thus responsible for the generation of the sharp wave-like spontaneous field potentials in isolated hippocampal circuitry.

scholarly journals Uniform Range of Conduction Times From the Lateral Amygdala to Distributed Perirhinal Sites

2002 ◽  
Vol 87 (3) ◽  
pp. 1213-1221 ◽  
Author(s):  
J. Guillaume Pelletier ◽  
Denis Paré
Keyword(s):  
Response Latency ◽  
Declarative Memory ◽  
Time Windows ◽  
Activity Patterns ◽  
Critical Role ◽  
Memory Storage ◽  
Response Latencies ◽  
Lateral Amygdala ◽  
Electrical Stimuli ◽  
Antidromic Response

Much data indicate that the perirhinal (PRH) cortex plays a critical role in declarative memory and that the amygdala facilitates this process under emotionally arousing conditions. However, assuming that the amygdala does so by promoting Hebbian interactions in the PRH cortex is hard to reconcile with the fact that variable distances separate amygdala neurons from their PRH projection sites. Indeed, to achieve a synchronized activation of distributed PRH sites, amygdala axons should display a uniform range of conduction times, irrespective of distance to target. To determine if amygdala axons meet this condition, we measured the antidromic response latencies of lateral amygdala (LA) neurons to electrical stimuli delivered at various rostrocaudal levels of the PRH cortex in cats anesthetized with isoflurane. Although large variations in antidromic response latencies were observed, they were unrelated to the distance between the PRH stimulation sites and LA neurons. To determine whether this result was an artifact due to current spread, two control experiments were performed. First, we examined the antidromic response latency of intrinsic PRH neurons. Although we used the same methods as in the first experiment, the antidromic response latency of PRH neurons to electrical stimuli applied in the PRH cortex increased linearly with the distance between the stimulating and recording sites. Second, we measured the antidromic response latency of PRH neurons projecting to the LA. In this pathway, we also found a statistically significant correlation between conduction times and distance to target. Thus these results support the intriguing possibility that the conduction velocity and/or trajectory of LA axons are adjusted to compensate for variations in distance between the LA and distinct rostrocaudal PRH sites. We hypothesize that because of their uniform range of conduction times to the PRH cortex, LA neurons can generate short time windows of depolarization facilitating Hebbian associations between coincident, but spatially distributed, activity patterns in the PRH cortex. In this context, the temporal scatter of conduction times in the LA to PRH pathway is conceived as a mechanism used to lengthen the period of depolarization to compensate for conduction delays within intrinsic PRH pathways. In part, this mechanism might explain how the amygdala promotes memory storage in emotionally arousing conditions.

scholarly journals Distinct stages of synapse elimination are induced by burst firing of CA1 neurons and differentially require MEF2A/D

eLife ◽  
2017 ◽  
Vol 6 ◽  
Author(s):  
Chia-Wei Chang ◽  
Julia R Wilkerson ◽  
Carly F Hale ◽  
Jay R Gibson ◽  
Kimberly M Huber
Keyword(s):  
Hippocampal Neurons ◽  
Molecular Mechanisms ◽  
De Novo ◽  
Activity Patterns ◽  
Burst Firing ◽  
Excitatory Synapses ◽  
Synapse Elimination ◽  
Ca1 Neurons ◽  
Theta Frequency ◽  
Individual Mouse

Experience and activity refine cortical circuits through synapse elimination, but little is known about the activity patterns and downstream molecular mechanisms that mediate this process. We used optogenetics to drive individual mouse CA1 hippocampal neurons to fire in theta frequency bursts to understand how cell autonomous, postsynaptic activity leads to synapse elimination. Brief (1 hr) periods of postsynaptic bursting selectively depressed AMPA receptor (R) synaptic transmission, or silenced excitatory synapses, whereas more prolonged (24 hr) firing depressed both AMPAR and NMDAR EPSCs and eliminated spines, indicative of a synapse elimination. Both synapse silencing and elimination required de novo transcription, but only silencing required the activity-dependent transcription factors MEF2A/D. Burst firing induced MEF2A/D-dependent induction of the target gene Arc which contributed to synapse silencing and elimination. This work reveals new and distinct forms of activity and transcription-dependent synapse depression and suggests that these processes can occur independently.

Evoked Oscillations in the Thalamo-Cortical Auditory System Are Present in Anesthetized but not in Unanesthetized Rats

2003 ◽  
Vol 89 (4) ◽  
pp. 1968-1984 ◽  
Author(s):  
Nathalie Cotillon-Williams ◽  
Jean-Marc Edeline
Keyword(s):  
Auditory Cortex ◽  
Auditory System ◽  
Auditory Perception ◽  
Slow Wave Sleep ◽  
Paradoxical Sleep ◽  
Reticular Nucleus ◽  
Spontaneous Oscillations ◽  
Unanesthetized Animals ◽  
High Doses ◽  
The One

Over the last decade, a large number of studies have characterized stimulus-evoked oscillations in the visual cortex of anesthetized and unanesthetized animals. Comparatively, only a few studies have been performed in auditory cortex. This study compared the tone-evoked oscillations detected from the same recording sites in the thalamo-cortical auditory system of unanesthetized and anesthetized rats. Simultaneous multiunit recordings were collected in auditory cortex, auditory thalamus, and the auditory sector of the reticular nucleus of restrained rats, which spontaneously shifted from waking (W) to slow-wave sleep (SWS) and paradoxical sleep (PS). Subsequently, the same recording sites were tested under pentobarbital anesthesia, then under high doses of diazepam, and finally under urethan anesthesia. Under these drugs, oscillations were detected in 54% of the recordings: one-half of them were stimulus-locked oscillations and were directly observed on peri-stimulus time histograms (PSTHs); one-half of them were non–stimulus-locked oscillations and were detected on autocorrelograms. Spontaneous oscillations were present for 17% of the recordings. During SWS, only non–stimulus-locked oscillations were observed for a small percentage of recordings (12%). This percentage did not differ significantly from the one of spontaneous oscillations obtained during SWS (8%). No oscillations were found in W and PS. Both under anesthesia and in SWS, the frequency range of the oscillations was 5–15 Hz, and there was no frequency difference between evoked and spontaneous oscillations. Although surprising, the absence of oscillations in awake animals may allow each neuron to process acoustic information independently of its neighbors and may in fact benefit auditory perception.

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