Eliott R. J. Levy scite author profile

In 1980, Nadel and Wilner extended Richard Hirsh's notion that the hippocampus creates environmental representations, called “contexts,” suggesting that the fundamental structure of context was the spatial representation proposed by O'Keefe and Nadel's landmark book, The Hippocampus as a Cognitive Map (1978). This book, in turn, derives from the discovery that individual hippocampal neurons act as place cells, with the complete set of place cells tiling an enclosure, forming a type of spatial map. It was found that unique environments had unique place cell representations. That is, if one takes the hippocampal map of a specific environment, this representation scrambles, or “remaps” when the animal is placed in a different environment. Several authors have speculated that “maps” and “remapping” form the physiological substrates for context and context shifting. One difficulty with this definition is that it is exclusively spatial; it can only be inferred when an animal locomotes in an enclosure. There are five aims for this article. The first is to give an historical overview of context as a variable that controls behavior. The second aim is to give an historical overview of concepts of place cell maps and remapping. The third aim is to propose an updated definition of a place cell map, based on temporal rather than spatial overlaps, which adds flexibility. The fourth aim is to address the issue of whether the biological phenomenon of hippocampal remapping, is, in fact, the substrate for shifts in the psychological phenomenon of context. The final aim is speculation of how contextual representations may contribute to effective behavior.

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Cognitive control persistently enhances hippocampal information processing

Chung

Jou

Grau‐Perales

et al. 2021

Nature

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A manifold neural population code for space in hippocampal coactivity dynamics independent of place fields

Levy

Carrillo-Segura²,

Redman

et al. 2021

Preprint

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Hippocampus CA1 place cells express a spatial neural code by discharging action potentials in cell-specific locations (′place fields′), but their discharge timing is also coordinated by multiple mechanisms, suggesting an alternative ′ensemble cofiring′ neural code, potentially distinct from place fields. We compare the importance of these distinct information representation schemes for encoding environments. Using miniature microscopes, we recorded the ensemble activity of mouse CA1 principal neurons expressing GCaMP6f across a multi-week experience of two distinct environments. We find that both place fields and ensemble coactivity relationships are similarly reliable within environments and distinctive between environments. Decoding the environment from cell-pair coactivity relationships is effective and improves after removing cell-specific place tuning. Ensemble decoding relies most crucially on anti-coactive cell pairs distributed across CA1 and is independent of place cell firing fields. We conclude that ensemble cofiring relationships constitute an advantageous neural code for environmental space, independent of place fields.

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Learning to learn persistently modifies an entorhinal-hippocampal excitatory-inhibitory subcircuit

Chung

Jou

Grau‐Perales

et al. 2019

Preprint

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SUMMARYThe neurobiology of psychological concepts like schema, and psychotherapeutic strategies of cognitive behavioral therapy (CBT) is poorly understood, partly because learning to process information confounds, and is rarely distinguished from acquiring content-specific memory. Learning to learn changes one’s overall information-processing ability, whereas neurobiological investigations typically focus on memory for content from particular experiences. We investigated entorhinal cortex-to-dentate gyrus neural circuit changes while mice learn to learn during cognitive control training (CCT) to judiciously use and ignore information. CCT changes synaptic circuit function by persistently modifying an excitatory-inhibitory interneuron subcircuit lasting weeks. CCT increases dentate gyrus expression of PKMζ that maintains long-term potentiation, particularly in somatostatin-expressing inhibitory interneurons that mediate both widespread inhibition, and through disinhibition, also local excitation of dentate gyrus. These findings that CCT modifies excitation-inhibition circuit coordination provide direct neurobiological evidence for a CBT-neuroplasticity hypothesis that, beyond particular item/event associations, learning to learn persistently changes neural circuit function.

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Sub-circuit alterations in dorsal hippocampus structure and function after global neurodevelopmental insult

et al. 2018

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Patients with neuropsychiatric and neurological disorders often express limbic circuit abnormalities and deficits in information processing. While these disorders appear to have diverse etiologies, their common features suggest neurodevelopmental origins. Neurodevelopment is a prolonged process of diverse events including neurogenesis/apoptosis, axon pathfinding, synaptogenesis, and pruning, to name a few. The precise timing of the neurodevelopmental insult to these processes likely determines the resulting functional outcome. We used the epilepsy and schizophrenia-related gestational day 17 methylazoxymethanol acetate model to examine the impact of this timed neurodevelopmental insult on principal cell morphology and synaptic network function of the dorsal hippocampus (dHPC) circuit. Our observed structural and functional alterations in dHPC are compartment specific, indicating that adverse global exposure during gestation can produce specific alterations and distort information processing in neural circuits that underlie cognitive abilities.

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Eliott R. J. Levy

Is hippocampal remapping the physiological basis for context?

Cognitive control persistently enhances hippocampal information processing

A manifold neural population code for space in hippocampal coactivity dynamics independent of place fields

Learning to learn persistently modifies an entorhinal-hippocampal excitatory-inhibitory subcircuit

Sub-circuit alterations in dorsal hippocampus structure and function after global neurodevelopmental insult

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