Olivia J. Hon scite author profile

Summary The medial entorhinal cortex (mEC) has been identified as a hub for spatial information processing by the discovery of grid, border, and head-direction cells. Here we find that in addition to these well characterized classes, nearly all of the remaining two thirds of mEC cells can be categorized as spatially selective. We refer to these cells as non-grid spatial cells and confirmed that their spatial firing patterns were unrelated to running speed and highly reproducible within the same environment. However, in response to manipulations of environmental features, such as box shape or box color, non-grid spatial cells completely reorganized their spatial firing patterns. At the same time, grid cells retained their spatial alignment and predominantly responded with redistributed firing rates across their grid fields. Thus, mEC contains a joint representation of both spatial and environmental feature content, with specialized cell types showing different types of integrated coding of multimodal information.

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Dynamic Interstitial Cell Response during Myocardial Infarction Predicts Resilience to Rupture in Genetically Diverse Mice

Forte

et al. 2020

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Directed Evolution of a Selective and Sensitive Serotonin Sensor via Machine Learning

Unger

Keller

Altermatt

et al. 2020

Cell

144

116

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Central Amygdala Prepronociceptin-Expressing Neurons Mediate Palatable Food Consumption and Reward

Hardaway

Halladay

Mazzone

et al. 2019

Neuron

106

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Dynamic Interstitial Cell Response During Myocardial Infarction Predicts Resilience to Rupture in Genetically Diverse Mice

et al. 2019

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Cardiac ischemia leads to the loss of myocardial tissue and the activation of a repair process that culminates in the formation of a scar whose structural characteristics dictate propensity to favorable healing or detrimental cardiac wall rupture. To elucidate the cellular processes underlying scar formation, here we perform unbiased single-cell mRNA sequencing of interstitial cells isolated from infarcted mouse hearts carrying a genetic tracer that labels epicardial-derived cells. Sixteen interstitial cell clusters are revealed, five of which were of epicardial origin. Focusing on stromal cells, we define 11 sub-clusters, including diverse cell states of epicardial-and endocardial-derived fibroblasts. Comparing transcript profiles from post-infarction hearts in C57BL/6J and 129S1/SvImJ inbred mice, which displays a marked divergence in the frequency of cardiac rupture, uncovers an early increase in activated myofibroblasts, enhanced collagen deposition, and persistent acute phase response in 129S1/SvImJ mouse hearts, defining a crucial time window of pathological remodeling that predicts disease outcome.

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Olivia J. Hon

Grid and Nongrid Cells in Medial Entorhinal Cortex Represent Spatial Location and Environmental Features with Complementary Coding Schemes

Dynamic Interstitial Cell Response during Myocardial Infarction Predicts Resilience to Rupture in Genetically Diverse Mice

Directed Evolution of a Selective and Sensitive Serotonin Sensor via Machine Learning

Central Amygdala Prepronociceptin-Expressing Neurons Mediate Palatable Food Consumption and Reward

Dynamic Interstitial Cell Response During Myocardial Infarction Predicts Resilience to Rupture in Genetically Diverse Mice

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