Abstract
Animals must quickly adapt food-seeking strategies to locate nutrient sources in dynamically changing environments. Learned associations between food and environmental cues that predict its availability promote food-seeking behaviors. However, when such cues cease to predict food availability, animals undergo "extinction" learning, resulting in the inhibition of food-seeking responses. Repeatedly activated sets of neurons, or "neuronal ensembles," in the dorsal medial prefrontal cortex (dmPFC) are recruited following appetitive conditioning and undergo physiological adaptations thought to encode cue-reward associations. However, little is known about how the recruitment and intrinsic excitability of such dmPFC ensembles are modulated by extinction learning. Here, we used in vivo 2-Photon imaging in male Fos-GFP mice that express green fluorescent protein (GFP) in recently behaviorally activated neurons to determine the recruitment of activated pyramidal and GABAergic interneuron dmPFC ensembles during extinction. During extinction, we revealed a persistent activation of a subset of interneurons which emerged from a wider population of interneurons activated during the initial extinction session. This activation pattern was not observed in pyramidal cells, and extinction learning did not modulate the excitability properties of activated pyramidal cells. Moreover, extinction learning reduced the likelihood of reactivation of pyramidal cells activated during the initial extinction session. Our findings illuminate novel neuronal activation patterns in the dmPFC underlying extinction of food-seeking, and in particular, highlight an important role for interneuron ensembles in this inhibitory form of learning.
Highlights
Animals need to efficiently adapt to changes in the predictive value of environmental ‘cues’ which signal food availability to optimize energy use when foraging (MacArthur and Pianka, 1966)
Our findings demonstrate that extinction learning leads to the recruitment of an interneuron ensemble recruited from neurons activated in E1
Little attention has been paid to the role of dorsal medial prefrontal cortex (dmPFC) ensembles, especially with regards to the role of interneurons, in controlling extinction learning following the establishment of an appetitive conditioned stimulus (CS)-unconditioned stimulus (US) association
Summary
Animals need to efficiently adapt to changes in the predictive value of environmental ‘cues’ which signal food availability to optimize energy use when foraging (MacArthur and Pianka, 1966) This includes being able to learn how to inhibit food-seeking behaviors, after cues that previously predicted food availability cease to do so. Following this procedure, the CS alone will no longer elicit food-related behaviors, such as approach behaviors towards the location where food was previously made available (van den Akker et al, 2018; Pavlov (1927), 2010) It is well-known that while the conditioned response ceases to be expressed, the original underlying CS-US association remains intact and is actively ‘inhibited’ rather than unlearned. This idea is supported for instance from phenomena such as spontaneous recovery in which an ‘extinguished’ CS-evoked response re-emerges as a result of the mere passage of time due to a failure to retrieve extinction memories (Bouton, 1993; Pavlov, 1927; Pearce and Hall, 1980; Ziminski et al, 2017)
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