Aubrey M. Demchuk scite author profile

The mechanisms governing how the hippocampus selects neurons to exhibit place fields are not well understood. A default assumption in some previous studies was the uniform random draw with replacement (URDWR) model, which, theoretically, maximizes spatial "pattern separation", and predicts a Poisson distribution of the numbers of place fields expressed by a given cell per unit area. The actual distribution of mean firing rates exhibited by a population of hippocampal neurons, however, is approximately exponential or log-normal in a given environment and these rates are somewhat correlated across multiple places, at least under some conditions. The advantage of neural activity-dependent immediate-early gene (IEG) analysis, as a proxy for electrophysiological recording, is the ability to obtain much larger samples of cells, even those whose activity is so sparse that they are overlooked in recording studies. Thus, a more accurate representation of the activation statistics can potentially be achieved. Some previous IEG studies that examined behavior-driven IEG expression in CA1 appear to support URDWR. There was, however, in some of the same studies, an under-recruitment of dentate gyrus granule cells, indicating a highly skewed excitability distribution, which is inconsistent with URDWR. Although it was suggested that this skewness might be related to increased excitability of recently generated granule cells, we show here that CA1, CA3, and subiculum also exhibit cumulative under-recruitment of neurons. Thus, a highly skewed excitability distribution is a general principle common to all major hippocampal subfields. Finally, a more detailed analysis of the frequency distributions of IEG intranuclear transcription foci suggests that a large fraction of hippocampal neurons is virtually silent, even during sleep. Whether the skewing of the excitability distribution is cell-intrinsic or a network phenomenon, and the degree to which this excitability is fixed or possibly time-varying are open questions for future studies. © 2016 Wiley Periodicals, Inc.

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The biomedical and bioengineering potential of protein nanocompartments

Demchuk

Patel

2020

Biotechnology Advances

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Postnatal development of Homer1a in the rat hippocampus

et al. 2013

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Homer1a (H1a) is an immediate early gene involved in multiple forms of synaptic plasticity. It exhibits a postnatal increase in the rat forebrain (Brakeman et al. (1997) Nature 386:284-288) and reduces the density and size of dendritic spines in hippocampal neurons (Sala et al. (2003) J Neurosci 23:6327-6337). We evaluated hippocampal H1a expression at different postnatal ages (P3, P5, P7, P9, P15, P19, P23, P35, and adult) using Fluorescence In Situ Hybridization (FISH) and qRT-PCR. Maximal electroconvulsive shock (MECS) was used to induce maximal expression relative to home cage (HC) controls. Large scale images and confocal z-stacks from dorsal subiculum (DS), CA1, CA3, and dentate gyrus (DG) were analyzed by both manual and automated methods. In DS, CA1, and CA3 a significant proportion of cells (40%) expressed small but detectable levels of H1a from P3; however, MECS did not up-regulate H1a during the first postnatal week. MECS induced H1a positive cells during the second postnatal week and induction reached adult levels at P9. H1a-Intra Nuclear Foci (INF) size and intensity varied with age, increasing at P19-23 in CA1 and CA3 and from P9 to P23 in DS. In DG, H1a expression exhibited a lamination pattern and an H1a-INF size and intensity gradient across the granule cell layer, consistent with the outside-in maturation of DG granule cells. The developmental progression of H1a corresponds to the synaptic refinement period supporting the conclusion that H1a could play an important role in this process.

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Place navigation in the Morris water task results in greater nuclear Arc mRNA expression in dorsal compared to ventral CA1

et al. 2019

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Previous work has shown that the dorsal hippocampus has greater activity than ventral regions during place navigation. Exposure to a novel context has also been found to increase hippocampal activation, possibly due to increased spatial demands. However, activation patterns in dorsal and ventral regions have not been investigated in the Morris water task (MWT), which remains the most popular assay of place memory in rodents. We measured activity in a large population of neurons across the CA1 dorsal–ventral axis by estimating nuclear Arc mRNA with stereologic systematic‐random sampling procedures following changes to goal location or spatial context in the MWT in rats. Following changes to goal location or spatial context in the MWT, we did not find an effect on Arc mRNA expression in CA1. However, Arc expression was greater in the dorsal compared to the ventral aspect of CA1 during task performance. Several views might account for these observed differences in dorsal–ventral Arc mRNA expression, including task parameters or the granularity of representation that differs along the dorsal–ventral hippocampal axis. Future work should determine the effects of task differences and required memory precision in relation to dorsal–ventral hippocampal neuronal activity.

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Limitations of the GENSAT Egr1-EGFP transgenic mouse strain for neural circuit activity mapping

Demchuk

Dube

Mesina

et al. 2020

Neuroscience Letters

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Aubrey M. Demchuk

Nonuniform allocation of hippocampal neurons to place fields across all hippocampal subfields

The biomedical and bioengineering potential of protein nanocompartments

Postnatal development of Homer1a in the rat hippocampus

Place navigation in the Morris water task results in greater nuclear Arc mRNA expression in dorsal compared to ventral CA1

Limitations of the GENSAT Egr1-EGFP transgenic mouse strain for neural circuit activity mapping

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