Interplay between persistent activity and activity-silent dynamics in the prefrontal cortex underlies serial biases in working memory

Barbosa, João; Stein, Heike; Martinez, Rebecca L.; Galan-Gadea, Adrià; Li, Sihai; Dalmau, Josep; Adam, Kirsten; Valls‐Solé, Josep; Constantinidis, Christos; Compte, Albert

doi:10.1038/s41593-020-0644-4

Cited by 211 publications

(316 citation statements)

References 70 publications

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“…OFC is likely supported in this by other brain regions, which may hold sustained or dynamic neural activation during the long delay time. However it is likely that maintaining such information across the relatively long delay period used here requires additional mechanisms such as short-term synaptic plasticity, either in OFC or elsewhere, which is not necessarily reflected in increased or decreased neural firing rates (Barbosa et al, 2020;Mongillo, Barak, & Tsodyks, 2008;Stokes, 2015). More investigations are needed in the future to shed light on this important question.…”

Section: Discussionmentioning

confidence: 98%

Prospective Representations in Rat Orbitofrontal Ensembles

Zhou

Zong

Jia

et al. 2020

Preprint

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The orbitofrontal cortex (OFC) has been proposed to encode expected outcomes, which is thought to be important for outcome-directed behavior. However, such neural encoding can also often be explained by the recall of information about the recent past. To dissociate the retrospective and prospective aspects of encoding in the OFC, we designed a non-spatial, continuous, alternating odor-sequence task that mimicked a continuous T-maze. The task consisted of two alternating sequences of four odor-guided trials (2 sequences × 4 positions). In each trial, rats were asked to make a “go” or “no-go” action based on a fixed odor-reward contingency. Odors at both the first and last positions were distinct across the two sequences, such that they resembled unique paths in the past and future, respectively; odors at positions in between were the same and thus resembled a common path. We trained classifiers using neural activity to distinguish between either sequences or positions and asked whether the neural activity patterns in the common path were more like the ones in the past or the future. We found a proximal prospective code for sequence information as well as a distal prospective code for positional information, the latter of which was closely associated with rats’ ability to predict future outcomes. This study demonstrates a prospective behaviorally-relevant predictive code in rat OFC.

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Section: Discussionmentioning

confidence: 98%

Prospective Representations in Rat Orbitofrontal Ensembles

Zhou

Zong

Jia

et al. 2020

Preprint

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“…We searched for representations of the current goal encoded in terms of the major forms of delay period activity previously found in other working memory tasks, spatial or non-spatial, involving recordings from the PFC or elsewhere in primates and rodents: activity reflecting the representation at the time of encoding the sample item (Funahashi et al, 1989;Miller et al, 1996;Rainer et al, 1998;Romo et al, 1999;Wu et al, 2020), elevated/suppressed activity in single cells (Fuster & Alexander, 1971;Funahashi et al, 1989;Miller et al, 1996;Rainer et al, 1998;Romo et al, 1999;Kim et al, 2016;Inagaki et al, 2019) or sequential firing patterns across multiple cells that tile the delay period (Baeg et al, 2003;Fujisawa et al, 2008;Pastalkova et al, 2008;Harvey et al, 2012;Ito et al, 2015), oscillatory phase-dependent firing (Siegel et al, 2009;Watrous et al, 2018), and elevated/suppressed covariances in firing among pairs of neurons (Barbosa et al, 2020).…”

Section: Resultsmentioning

confidence: 93%

“…If the remembered goal is not maintained by activity directly related to activity at the goal itself, it could be (i) transformed into a different, but goal-specific, pattern, potentially dependent on the start location (ii) encoded in egocentric coordinates (i.e. the direction relative to the current start location) (Sarel et al, 2017) instead of in terms of the absolute (allocentric) goal location, (iii) represented by a sequential, instead of tonic, activity pattern and/or (iv) reflected in the phase of spike times or the short timescale interactions between pairs of neurons (Barbosa et al, 2020). We initially tested if any single cell activity in 100-ms-to full-delay-period-sized time bins showed consistent firing differences for allocentric, start-dependent or egocentric goal location ( Figure S3-1).…”

Section: Resultsmentioning

confidence: 99%

Canonical goal-selective representations are absent from prefrontal cortex in a spatial working memory task requiring behavioral flexibility

Böhm

Lee

2020

Preprint

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The prefrontal cortex (PFC)'s functions are thought to include working memory, as its activity can reflect information that must be temporarily maintained to realize the current goal. We designed a flexible spatial working memory task that required rats to navigate - after distractions and a delay - to multiple possible goal locations from different starting points and via multiple routes. This made the current goal location the key variable to remember, instead of a particular direction or route to the goal. However, across a broad population of PFC neurons, we found no evidence of current-goal-specific memory in any previously reported form - i.e. differences in the rate, sequence, phase or covariance of firing. This suggests such patterns do not hold working memory in the PFC when information must be employed flexibly. Instead, the PFC grouped locations representing behaviorally equivalent task features together, consistent with a role in encoding long-term knowledge of task structure.

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“…Unconscious working memory is thought to rely on 'activity-silent' synaptic mechanisms (Stokes 2015;Trübutschek et al 2017). Slow cellular and synaptic processes may not only contribute to such mechanisms but also induce trial-by-trial history-dependent effects (Barbosa et al 2020;Bliss and D'Esposito 2017;Carter and Wang 2007;Pereira and Wang 2015). Previous models of working memory with short-term synaptic plasticity have focused on local activity in the prefrontal cortex (Mongillo et al 2008;Stokes 2015), and thus implicitly imply that it is short-term plasticity in local connections between prefrontal neurons that stores the memory trace.…”

Section: Ignition Silent Activity and Maintenancementioning

confidence: 99%

A dopamine gradient controls access to distributed working memory in monkey cortex

Bliss

Ding

Jankovic-Rapan

et al. 2020

Preprint

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SummaryDopamine is critical for working memory. However, its effects throughout the large-scale primate cortex are poorly understood. Here we report that dopamine receptor density per neuron, measured by receptor autoradiography in the macaque monkey cortex, displays a macroscopic gradient along the cortical hierarchy. We developed a connectome- and biophysically-based model for distributed working memory that incorporates multiple neuron types and a dopamine gradient. The model captures an inverted U-shaped dependence of working memory on dopamine. The spatial distribution of mnemonic persistent activity matches that observed in over 90 experimental studies. We show that dopamine filters out irrelevant stimuli by enhancing inhibition of pyramidal cell dendrites. The level of cortical dopamine can also determine whether memory encoding is through persistent activity or an internal synaptic state. Taken together, our work represents a cross-level understanding that links molecules, cell types, recurrent circuit dynamics and a core cognitive function distributed across the cortex.

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Interplay between persistent activity and activity-silent dynamics in the prefrontal cortex underlies serial biases in working memory

Cited by 211 publications

References 70 publications

Prospective Representations in Rat Orbitofrontal Ensembles

Prospective Representations in Rat Orbitofrontal Ensembles

Canonical goal-selective representations are absent from prefrontal cortex in a spatial working memory task requiring behavioral flexibility

A dopamine gradient controls access to distributed working memory in monkey cortex

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