RT Journal Article
SR Electronic
T1 The rat medial prefrontal cortex exhibits flexible neural activity states during the performance of an odor span task
JF eneuro
JO eNeuro
FD Society for Neuroscience
SP ENEURO.0424-18.2019
DO 10.1523/ENEURO.0424-18.2019
A1 De Falco, E.
A1 An, L.
A1 Sun, N.
A1 Roebuck, A. J.
A1 Greba, Q.
A1 Lapish, C. C.
A1 Howland, J. G.
YR 2019
UL http://www.eneuro.org/content/early/2019/03/04/ENEURO.0424-18.2019.abstract
AB Medial prefrontal cortex (mPFC) activity is fundamental for working memory (WM), attention, and behavioral inhibition; however, a comprehensive understanding of the neural computations underlying these processes is still forthcoming. Towards this goal, neural recordings were obtained from the mPFC of awake, behaving rats performing an odor span task of WM capacity. Neural populations were observed to encode distinct task epochs and the transitions between epochs were accompanied by abrupt shifts in neural activity patterns. Putative pyramidal neuron activity increased earlier in the delay for sessions where rats achieved higher spans. Furthermore, increased putative interneuron activity was only observed at the termination of the delay thus indicating that local processing in inhibitory networks was a unique feature to initiate foraging. During foraging, changes in neural activity patterns associated with the approach to a novel odor, but not familiar odors, were robust. Collectively, these data suggest that distinct mPFC activity states underlie the delay, foraging, and reward epochs of the odor span task. Transitions between these states enable successful performance in dynamic environments placing strong demands on the substrates of working memory.Significance Statement Working memory capacity is altered in psychiatric disorders including schizophrenia. In the present manuscript, we describe activity states of neurons in medial prefrontal cortex as well-trained rats perform the odor span task, which has been nominated as a task suitable for studying working memory capacity in rodents. Our results demonstrate dynamic and flexible activity patters during different epochs of the task (i.e., the delay period, foraging, reward collection, and after making errors). Our results bolster contemporary theories of the medial prefrontal cortex exhibiting metastable dynamics in complex environments. Disruptions in these dynamics may underlie some cognitive symptoms of schizophrenia, including reduced working memory capacity.