Elucidating memory in the brain via single‐cell transcriptomics

Sullivan, Kaitlin E; Kendrick, Rennie M; Cembrowski, Mark S.

doi:10.1111/jnc.15250

Cited by 11 publications

(12 citation statements)

References 107 publications

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“…From a technical standpoint, mFISH also allows higher sensitivity of detection relative to scRNA-seq, circumventing issues of scRNA-seq drop-out. 25 , 46 , 47 , 48 , 49 Ultimately, the general concordance across methodologies for our derived cell-type assignments illustrates that the CEA can be well-captured by a low-dimensional representation in gene-expression space, and that our derived cell type definitions encompass the spatial extent of the CEA.…”

Section: Discussionmentioning

confidence: 58%

“…Although a variety of work has examined CEA cell types using these a priori marker genes or bulk transcriptional profiling, 14 , 21 , 22 , 23 , 24 to date no published work has examined CEA organization from a whole-genome perspective at a single-cell resolution. Defining cell types at this fine level of granularity is likely to provide a more complete understanding of the cell-type organization of the CEA (for review, see 25 , 26 ): which may validate whether known marker genes capture all cell types, or conversely identify new cell types and organizational principles within the CEA. 27 , 28 In either case, such results can provide a cell-type framework for integrating spatial organization with other structural and functional properties.…”

Section: Introductionmentioning

confidence: 99%

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Neuronal cell types, projections, and spatial organization of the central amygdala

et al. 2022

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Section: Discussionmentioning

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Neuronal cell types, projections, and spatial organization of the central amygdala

et al. 2022

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“…Besides MRI techniques, the advancement and refining of other techniques over the years might also help to gain insight in the processes unfolding during learning. At the molecular level, transcriptomic methods allow the quantification of single gene's expression by accessing RNA levels, making them a prominent, reliable and unbiased tool for to identification of the cells and molecules participating in memory processes [131]. Two main approaches coexist to assess gene expression.…”

Section: Learning and Sleep At The Molecular Levelmentioning

confidence: 99%

“…However, it allows identifying at the whole-genome scale all RNA transcripts, hence allowing to measure gene expression levels in an unbiased and accurate way. The combination of both methods makes it possible to sequence the entire transcriptome, without losing the organizational pattern [131]. Using these methods, genes coding for particular rRNAs [132] and specific proteins regulating synaptic plasticity through the modulation of certain mRNA [133,134] could already be identified, and microRNAs were also found to intervene in synaptic plasticity and learning (for reviews, see [135,136].…”

Section: Learning and Sleep At The Molecular Levelmentioning

confidence: 99%

Post-learning micro- and macro-structural neuroplasticity changes with time and sleep

Stee

Peigneux

2021

Biochemical Pharmacology

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Neuroplasticity refers to the fact that our brain can partially modify both structure and function to adequately respond to novel environmental stimulations. Neuroplasticity mechanisms are not only operating during the acquisition of novel information (i.e., online) but also during the offline periods that take place after the end of the actual learning episode. Structural brain changes as a consequence of learning have been consistently demonstrated on the long term using non-invasive neuroimaging methods, but short-term changes remained more elusive. Fortunately, the swift development of advanced MR methods over the last decade now allows tracking fine-grained cerebral changes on short timescales beyond gross volumetric modifications stretching over several days or weeks. Besides a mere effect of time, post-learning sleep mechanisms have been shown to play an important role in memory consolidation and promote long-lasting changes in neural networks. Sleep was shown to contribute to structural modifications over weeks of prolonged training, but studies evidencing more rapid post-training sleep structural effects linked to memory consolidation are still scarce in human. On the other hand, animal studies convincingly show how sleep might modulate synaptic microstructure. We aim here at reviewing the literature establishing a link between different types of training/learning and the resulting structural changes, with an emphasis on the role of post-training sleep and time in tuning these modifications. Open questions are raised such as the role of post-learning sleep in macrostructural changes, the links between different MR structural measurement-related modifications and the underlying microstructural brain processes, and bidirectional influences between structural and functional brain changes.

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“…Single-cell transcriptomics was used for detecting more general transcriptional signatures of neuronal activation 18,70 . It has recently been suggested and 1025 gained momentum as a tool for comprehensive and unbiased identification of cellular and molecular substrates of learning and memory 22,23,71 . As a word of caution, however, the approach and our study contain a few limitations.…”

Section: Discussionmentioning

confidence: 99%

Cell types in the mouse amygdala and their transcriptional response to fear conditioning

Hochgerner

Tibi

Netser

et al. 2022

Preprint

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The amygdala is one of the most widely studied regions in behavioral neuroscience. A plethora of classical, and new paradigms have dissected its precise involvement in emotional and social sensing, learning, and memory. Several important insights resulted from the use of genetic markers - yet, in the age of single cell transcriptomics, the amygdala remains molecularly underdescribed. Here, we present a molecular cell type taxonomy of the full mouse amygdala in fear learning and consolidation. We performed single-cell RNA-seq on naïve and fear conditioned mice, inferred the 130 neuronal cell types distributions in silico using orthogonal spatial transcriptomic datasets, and describe the cell types' transcriptional responses to learning and memory consolidation. Only a fraction of cells, within a subset of all neuronal types, were transcriptionally responsive to fear learning, memory and retrieval. These activated engram cells upregulated activity-response genes, and processes of synaptic signaling, plasticity, development and neurite outgrowth. Our transcriptome-wide data confirm known actors, and describe several new candidate genes. The atlas may help pinpoint the amygdala's circuits in performing emotional sensing and integration, and provide new insights to the global cellular processes involved.

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Elucidating memory in the brain via single‐cell transcriptomics

Cited by 11 publications

References 107 publications

Neuronal cell types, projections, and spatial organization of the central amygdala

Neuronal cell types, projections, and spatial organization of the central amygdala

Post-learning micro- and macro-structural neuroplasticity changes with time and sleep

Cell types in the mouse amygdala and their transcriptional response to fear conditioning

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