Refinement and Reactivation of a Taste-Responsive Hippocampal Network

Animals need to remember the locations of nourishing and toxic food sources for survival, a fact that necessitates a mechanism for associating taste experiences with particular places. We have previously identified such responses within hippocampal place cells [1], the activity of which is thought t...

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Veröffentlicht in:Current biology 2020-04, Vol.30 (7), p.1306-1311.e4
Hauptverfasser: Herzog, Linnea E., Katz, Donald B., Jadhav, Shantanu P.
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Sprache:eng
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Zusammenfassung:Animals need to remember the locations of nourishing and toxic food sources for survival, a fact that necessitates a mechanism for associating taste experiences with particular places. We have previously identified such responses within hippocampal place cells [1], the activity of which is thought to aid memory-guided behavior by forming a mental map of an animal’s environment that can be reshaped through experience [2–7]. It remains unknown, however, whether taste responsiveness is intrinsic to a subset of place cells or emerges as a result of experience that reorganizes spatial maps. Here, we recorded from neurons in the dorsal CA1 region of rats running for palatable tastes delivered via intra-oral cannulae at specific locations on a linear track. We identified a subset of taste-responsive cells that, even prior to taste exposure, had larger place fields than non-taste-responsive cells overlapping with stimulus delivery zones. Taste-responsive cells’ place fields then contracted as a result of taste experience, leading to a stronger representation of stimulus delivery zones on the track. Taste-responsive units exhibited increased sharp-wave ripple co-activation during the taste delivery session and subsequent rest periods, which correlated with the degree of place field contraction. Our results reveal that novel taste experience evokes responses within a preconfigured network of taste-responsive hippocampal place cells with large fields, whose spatial representations are refined by sensory experience to signal areas of behavioral salience. This represents a possible mechanism by which animals identify and remember locations where ecologically relevant stimuli are found within their environment. [Display omitted] •Monitoring of hippocampal (CA1) place field changes during a novel taste experience•Larger initial place fields were linked to taste responsiveness•Taste-responsive cells’ place fields are selectively refined with experience•Reactivation supports place map reorganization to signal areas of food availability Herzog et al. monitor place field changes during a novel taste experience to show that taste responsiveness is associated with larger initial place field size. Taste-responsive cells selectively refine their place fields to signal areas of food availability with experience and are preferentially reactivated during sharp-wave ripples.
ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2020.01.063