Project description:The epigenome and three-dimensional (3D) genomic architecture are emerging as key factors in the dynamic regulation of different transcriptional programs required for neuronal functions. In this study, we used an activity-dependent tagging system in mice to determine the epigenetic state, 3D genome architecture and transcriptional landscape of engram cells over the lifespan of memory formation and recall. Our findings reveal that memory encoding leads to an epigenetic priming event, marked by increased accessibility of enhancers without the corresponding transcriptional changes. Memory consolidation subsequently results in spatial reorganization of large chromatin segments and promoter-enhancer interactions. Finally, with reactivation, engram neurons use a subset of de novo long-range interactions, where primed enhancers are brought in contact with their respective promoters to upregulate genes involved in local protein translation in synaptic compartments. Collectively, our work elucidates the comprehensive transcriptional and epigenomic landscape across the lifespan of memory formation and recall in the hippocampal engram ensemble.

Project description:A specific memory is thought to be encoded by a sparse population of neurons. These neurons can be tagged during learning for subsequent identification and manipulation. Moreover, their ablation or inactivation results in reduced memory expression, suggesting their necessity in mnemonic processes. However, the question of sufficiency remains: it is unclear whether it is possible to elicit the behavioural output of a specific memory by directly activating a population of neurons that was active during learning. Here we show in mice that optogenetic reactivation of hippocampal neurons activated during fear conditioning is sufficient to induce freezing behaviour. We labelled a population of hippocampal dentate gyrus neurons activated during fear learning with channelrhodopsin-2 (ChR2) and later optically reactivated these neurons in a different context. The mice showed increased freezing only upon light stimulation, indicating light-induced fear memory recall. This freezing was not detected in non-fear-conditioned mice expressing ChR2 in a similar proportion of cells, nor in fear-conditioned mice with cells labelled by enhanced yellow fluorescent protein instead of ChR2. Finally, activation of cells labelled in a context not associated with fear did not evoke freezing in mice that were previously fear conditioned in a different context, suggesting that light-induced fear memory recall is context specific. Together, our findings indicate that activating a sparse but specific ensemble of hippocampal neurons that contribute to a memory engram is sufficient for the recall of that memory. Moreover, our experimental approach offers a general method of mapping cellular populations bearing memory engrams.

Project description:Fragile X syndrome (FXS) is an X chromosome-linked disease associated with severe intellectual disabilities. Previous studies using the Fmr1 knockout (KO) mouse, an FXS mouse model, have attributed behavioral deficits to synaptic dysfunctions. However, how functional deficits at neural network level lead to abnormal behavioral learning remains unexplored. Here, we show that the efficacy of hippocampal engram reactivation is reduced in Fmr1 KO mice performing contextual fear memory recall. Experiencing an enriched environment (EE) prior to learning improved the engram reactivation efficacy and rescued memory recall in the Fmr1 KO mice. In addition, chemogenetically inhibiting EE-engaged neurons in CA1 reverses the rescue effect of EE on memory recall. Thus, our results suggest that inappropriate engram reactivation underlies cognitive deficits in FXS, and enriched environment may rescue cognitive deficits by improving network activation accuracy.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Purpose: we utilized a mouse model that permanently labels neurons activated throughout a specific experience to decipher the interplay between chromatin accessibility, 3D-chromatin architecture and transcriptional changes across different memory phases. Non activated (basal) and activated neurons during memory encoding (early), consolidation (late) and recall (reactivated) were sorted and subjected to nuclear RNA sequencing (nRNA-seq) to determine gene expression, ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) to assess chromatin accessibility, chromosome conformation capture (Hi-C) to identify global 3D -genome architecture and promoter capture Hi-C to identify the long range promoter-enhancer interactions. Results: our data demonstrates that the initial phase of memory formation alters the chromatin accessibility landscape of activated neurons, with long lasting stable changes occurring predominantly within enhancer regions. Moreover, many of these enhancers did not return to their baseline state after stimulation ceased, but remain accessible and stable throughout all memory phases.

Project description:Purpose: we utilized a mouse model that permanently labels neurons activated throughout a specific experience to decipher the interplay between chromatin accessibility, 3D-chromatin architecture and transcriptional changes across different memory phases. Non activated (basal) and activated neurons during memory encoding (early), consolidation (late) and recall (reactivated) were sorted and subjected to nuclear RNA sequencing (nRNA-seq) to determine gene expression, ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) to assess chromatin accessibility, chromosome conformation capture (Hi-C) to identify global 3D -genome architecture and promoter capture Hi-C to identify the long range promoter-enhancer interactions. Results: Our analysis revealed dynamic changes in compartments organization, where we observed re-localization of large chromatin segments from inactive to permissive environment (and vice versa) during the initial and late phase of memory formation. Interestingly, 52% of the regions in the early phase that switched from B to A maintained that state in the late phase (i.e. remained in state A. Moreover, nearly all these regions significantly overlapped with gained DARs identified in our ATAC-seq analysis, confirming the transition of sub-compartment from inactive to permissive environment. This data indicates that while some loci undergo sub-compartment switching across different memory phases, the majority are stable, correlate with chromatin accessibility and therefore might contribute to long-term changes in neuronal properties and function after initial activation.

Project description:Purpose: we utilized a mouse model that permanently labels neurons activated throughout a specific experience to decipher the interplay between chromatin accessibility, 3D-chromatin architecture and transcriptional changes across different memory phases. Non activated (basal) and activated neurons during memory encoding (early), consolidation (late) and recall (reactivated) were sorted and subjected to nuclear RNA sequencing (nRNA-seq) to determine gene expression, ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) to assess chromatin accessibility, chromosome conformation capture (Hi-C) to identify global 3D -genome architecture and promoter capture Hi-C to identify the long range promoter-enhancer interactions. Results: Our differentially expressed gene (DEG) analysis revealed relatively low amount of changes in the early phase, when compared to basal-state neurons (Basal vs. Early). In contrast, neurons from late phase presented higher numbers of DEGs despite there being more similarity in chromatin accessibility at these time points (Early vs. Late; Late vs. Reactivated). Our studies illuminate for the first time the unique transcriptional landscape of reactivated engram cells where we observed up-regulation of genes involved in mRNA transport and local protein translation in synaptic compartments. These changes corresponded to morphological and functional changes in those neurons.

Project description:Purpose: we utilized a mouse model that permanently labels neurons activated throughout a specific experience to decipher the interplay between chromatin accessibility, 3D-chromatin architecture and transcriptional changes across different memory phases. Non activated (basal) and activated neurons during memory encoding (early), consolidation (late) and recall (reactivated) were sorted and subjected to nuclear RNA sequencing (nRNA-seq) to determine gene expression, ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) to assess chromatin accessibility, chromosome conformation capture (Hi-C) to identify global 3D -genome architecture and promoter capture Hi-C to identify the long range promoter-enhancer interactions. Results: We have found that during each memory phase, the same promoters interact more frequently with a distinct subset of enhancers (i.e. unique). We also identified a smaller subset of interactions in which the promoters were interacting with the same enhancers across different memory phases (i.e. common). Furthermore, Reactivated neurons presented significantly stronger interaction scores (as calculated by CHiCAGO). Hence, although the number of unique interactions was similar across early, late and reactivated states, stronger interaction scores indicate that specific promoter- enhancer interactions occur more frequently during memory recall.

Project description:The theory of engrams, proposed several years ago, is highly crucial to understanding the progress of memory. Although it significantly contributes to identifying new treatments for cognitive disorders, it is limited by a lack of technology. Several scientists have attempted to validate this theory but failed. With the increasing availability of activity-dependent tools, several researchers have found traces of engram cells. Activity-dependent tools are based on the mechanisms underlying neuronal activity and use a combination of emerging molecular biological and genetic technology. Scientists have used these tools to tag and manipulate engram neurons and identified numerous internal connections between engram neurons and memory. In this review, we provide the background, principles, and selected examples of applications of existing activity-dependent tools. Using a combination of traditional definitions and concepts of engram cells, we discuss the applications and limitations of these tools and propose certain developmental directions to further explore the functions of engram cells.

Project description:Memory is incorporated into the brain as physicochemical changes to engram cells. These are neuronal populations that form complex neuroanatomical circuits, are modified by experiences to store information, and allow for memory recall. At the molecular level, learning modifies synaptic communication to rewire engram circuits, a mechanism known as synaptic plasticity. However, despite its functional role on memory formation, the 3D molecular architecture of synapses within engram circuits is unknown. Here, we demonstrate the use of engram labelling technology and cryogenic correlated light and electron microscopy (cryoCLEM)-guided cryogenic electron tomography (cryoET) to visualize the in-tissue 3D molecular architecture of engram synapses of a contextual fear memory within the CA1 region of the mouse hippocampus. Engram cells exhibited structural diversity of macromolecular constituents and organelles in both pre- and postsynaptic compartments and within the synaptic cleft, including in clusters of membrane proteins, synaptic vesicle occupancy, and F-actin copy number. This 'engram to tomogram' approach, harnessing in vivo functional neuroscience and structural biology, provides a methodological framework for testing fundamental molecular plasticity mechanisms within engram circuits during memory encoding, storage and recall.