Balancing the Robustness and Efficiency of Odor Representations during Learning

Chu, Monica W.; Li, Wankun L.; Komiyama, Takaki

doi:10.1016/j.neuron.2016.09.004

Cited by 117 publications

(181 citation statements)

References 61 publications

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“…The change in MC representation is consistent with a recent report (Chu et al., 2016), though we observed neither a strong sparsening of representation during learning (Figure 6) nor improved pattern separation during passive sensory experience (Figure 7). Furthermore, we showed that the ensemble pattern separation in MCs but not in TCs improves simultaneously as animals learn to discriminate perceptually similar odors (Figure 7).…”

Section: Discussionsupporting

confidence: 92%

“…Although the ensemble correlation analysis was not performed, this could translate as a weak and transient improvement of pattern separation in our setting, which would be in contrast to the gradual development of significant pattern separation that we observed in MCs. A potential source of this discrepancy could be the difficulty of the task: the sets of odorants these authors used for the task were easier to discriminate than ours and therefore might not necessarily involve improvement of pattern separation upon learning (Chu et al., 2016, Gödde et al., 2016, Gschwend et al., 2015). Moreover, with multi-unit recording, they could neither distinguish MCs and TCs nor track the same cell ensembles across multiple days, demonstrating the advantage of the chronic imaging technique we employed in the current study.…”

Section: Discussionmentioning

confidence: 87%

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Context- and Output Layer-Dependent Long-Term Ensemble Plasticity in a Sensory Circuit

Yamada

Bhaukaurally

Madarasz

et al. 2017

Neuron

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SummarySensory information is translated into ensemble representations by various populations of projection neurons in brain circuits. The dynamics of ensemble representations formed by distinct channels of output neurons in diverse behavioral contexts remains largely unknown. We studied the two output neuron layers in the olfactory bulb (OB), mitral and tufted cells, using chronic two-photon calcium imaging in awake mice. Both output populations displayed similar odor response profiles. During passive sensory experience, both populations showed reorganization of ensemble odor representations yet stable pattern separation across days. Intriguingly, during active odor discrimination learning, mitral but not tufted cells exhibited improved pattern separation, although both populations showed reorganization of ensemble representations. An olfactory circuitry model suggests that cortical feedback on OB interneurons can trigger both forms of plasticity. In conclusion, we show that different OB output layers display unique context-dependent long-term ensemble plasticity, allowing parallel transfer of non-redundant sensory information to downstream centers.Video Abstract

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Section: Discussionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 87%

Context- and Output Layer-Dependent Long-Term Ensemble Plasticity in a Sensory Circuit

Yamada

Bhaukaurally

Madarasz

et al. 2017

Neuron

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“…Previous studies have revealed that mice require extensive active learning, which likely triggers plasticity in the OB network, to disentangle similar sensory inputs during a difficult discrimination task. 33,42,43 Because the M/Ts, the granule cells, and their interactions are involved in the plasticity of the OB, [44][45][46] our findings suggest that leptin likely influences odor discrimination through its effects on these neurons and the OB network between them.…”

Section: Discussionmentioning

confidence: 81%

Leptin modulates olfactory discrimination and neural activity in the olfactory bulb

Sun

Ke-ke

et al. 2019

Acta Physiologica

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Aim Leptin is an important peptide hormone that regulates food intake and plays a crucial role in modulating olfactory function. Although a few previous studies have investigated the effect of leptin on odor perception and discrimination in rodents, research on the neural basis underlying the behavioral changes is lacking. Here we study how leptin affects behavioral performance during a go/no‐go task and how it modulates neural activity of mitral/tufted cells in the olfactory bulb, which plays an important role in odor information processing and representation. Methods A go/no‐go odor discrimination task was used in the behavioral test. For in vivo studies, single unit recordings, local field potential recordings and fiber photometry recordings were used. For in vitro studies, we performed patch clamp recordings in the slice of the olfactory bulb. Results Behaviorally, leptin affects performance and reaction time in a difficult odor‐discrimination task. Leptin decreases the spontaneous firing of single mitral/tufted cells, decreases the odor‐evoked beta and high gamma local field potential response, and has bidirectional effects on the odor‐evoked responses of single mitral/tufted cells. Leptin also inhibits the population calcium activity in genetically identified mitral/tufted cells and granule cells. Furthermore, in vitro slice recordings reveal that leptin inhibits mitral cell activity through direct modulation of the voltage‐sensitive potassium channel. Conclusions The behavioral reduction in odor discrimination observed after leptin administration is likely due to decreased neural activity in mitral/tufted cells, caused by modulation of potassium channels in these cells.

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“…However, when mice discriminated between very dissimilar odorants, counterintuitively, the representations of the two odorants gradually became more similar. This bidirectional effect was interpreted such that learning achieves an optimal separation of representations of familiar stimuli, balancing the robustness of discrimination and capacity of coding (Chu et al, 2016). …”

Section: Sensory Perceptual Learningmentioning

confidence: 99%

“…The reduction in population responses may be a common feature of learning-driven changes in population coding (see also the motor skill learning section below), which could reduce overlaps between representations in space and time and facilitate decoding by downstream areas (Laurent, 2002). Indeed, chronic tracking of the same neural population over sensorimotor learning demonstrated a decrease in the number of responsive neurons and/or magnitudes of responses to the same sensory stimuli (Chu et al, 2016; Gdalyahu et al, 2012; Makino and Komiyama, 2015). …”

Section: Sensory Perceptual Learningmentioning

confidence: 99%

Circuit Mechanisms of Sensorimotor Learning

Makino

Hwang

Hedrick

et al. 2016

Neuron

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176

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SUMMARY The relationship between the brain and the environment is flexible, forming the foundation for our ability to learn. Here we review the current state of our understanding of the modifications in the sensorimotor pathway related to sensorimotor learning. We divide the process in three hierarchical levels with distinct goals: 1) sensory perceptual learning, 2) sensorimotor associative learning, and 3) motor skill learning. Perceptual learning optimizes the representations of important sensory stimuli. Associative learning and the initial phase of motor skill learning are ensured by feedback-based mechanisms that permit trial-and-error learning. The later phase of motor skill learning may primarily involve feedback-independent mechanisms operating under the classic Hebbian rule. With these changes under distinct constraints and mechanisms, sensorimotor learning establishes dedicated circuitry for the reproduction of stereotyped neural activity patterns and behavior.

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Balancing the Robustness and Efficiency of Odor Representations during Learning

Cited by 117 publications

References 61 publications

Context- and Output Layer-Dependent Long-Term Ensemble Plasticity in a Sensory Circuit

Context- and Output Layer-Dependent Long-Term Ensemble Plasticity in a Sensory Circuit

Leptin modulates olfactory discrimination and neural activity in the olfactory bulb

Circuit Mechanisms of Sensorimotor Learning

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