Gaurav Das scite author profile

Dopamine (DA) is synonymous with reward and motivation in mammals1,2. However, only recently has dopamine been linked to motivated behavior and rewarding reinforcement in fruit flies3,4. Instead octopamine (OA) has historically been considered the signal for reward in insects5–7. Here we show using temporal control of neural function in Drosophila that only short-term appetitive memory is reinforced by OA. Moreover, OA-dependent memory formation requires signaling through DA neurons. Part of the OA signal requires the α-adrenergic like OAMB receptor in an identified subset of mushroom body (MB)-targeted DA neurons. OA triggers an increase in intracellular calcium in these DA neurons and their direct activation can substitute for sugar to form appetitive memory, even in flies lacking OA. Analysis of the β-adrenergic like Octβ2R receptor reveals that OA-dependent reinforcement also requires an interaction with DA neurons that control appetitive motivation. These data suggest that sweet taste engages a distributed OA signal that reinforces memory through discrete subsets of MB-targeted DA neurons. In addition, they reconcile prior findings with OA and DA and suggest that reinforcement systems in flies are more similar to mammals than previously envisaged.

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Activity of Defined Mushroom Body Output Neurons Underlies Learned Olfactory Behavior in Drosophila

Owald

Felsenberg

Talbot

et al. 2015

Neuron

332

538

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SummaryDuring olfactory learning in fruit flies, dopaminergic neurons assign value to odor representations in the mushroom body Kenyon cells. Here we identify a class of downstream glutamatergic mushroom body output neurons (MBONs) called M4/6, or MBON-β2β′2a, MBON-β′2mp, and MBON-γ5β′2a, whose dendritic fields overlap with dopaminergic neuron projections in the tips of the β, β′, and γ lobes. This anatomy and their odor tuning suggests that M4/6 neurons pool odor-driven Kenyon cell synaptic outputs. Like that of mushroom body neurons, M4/6 output is required for expression of appetitive and aversive memory performance. Moreover, appetitive and aversive olfactory conditioning bidirectionally alters the relative odor-drive of M4β′ neurons (MBON-β′2mp). Direct block of M4/6 neurons in naive flies mimics appetitive conditioning, being sufficient to convert odor-driven avoidance into approach, while optogenetically activating these neurons induces avoidance behavior. We therefore propose that drive to the M4/6 neurons reflects odor-directed behavioral choice.

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Drosophila Learn Opposing Components of a Compound Food Stimulus

et al. 2014

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SummaryDopaminergic neurons provide value signals in mammals and insects [1–3]. During Drosophila olfactory learning, distinct subsets of dopaminergic neurons appear to assign either positive or negative value to odor representations in mushroom body neurons [4–9]. However, it is not known how flies evaluate substances that have mixed valence. Here we show that flies form short-lived aversive olfactory memories when trained with odors and sugars that are contaminated with the common insect repellent DEET. This DEET-aversive learning required the MB-MP1 dopaminergic neurons that are also required for shock learning [7]. Moreover, differential conditioning with DEET versus shock suggests that formation of these distinct aversive olfactory memories relies on a common negatively reinforcing dopaminergic mechanism. Surprisingly, as time passed after training, the behavior of DEET-sugar-trained flies reversed from conditioned odor avoidance into odor approach. In addition, flies that were compromised for reward learning exhibited a more robust and longer-lived aversive-DEET memory. These data demonstrate that flies independently process the DEET and sugar components to form parallel aversive and appetitive olfactory memories, with distinct kinetics, that compete to guide learned behavior.

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Cyclin D1 fine-tunes the neurogenic output of embryonic retinal progenitor cells

et al. 2009

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Background: Maintaining the correct balance of proliferation versus differentiation in retinal progenitor cells (RPCs) is essential for proper development of the retina. The cell cycle regulator cyclin D1 is expressed in RPCs, and mice with a targeted null allele at the cyclin D1 locus (Ccnd1 -/ -) have microphthalmia and hypocellular retinas, the latter phenotype attributed to reduced RPC proliferation and increased photoreceptor cell death during the postnatal period. How cyclin D1 influences RPC behavior, especially during the embryonic period, is unclear.

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Gaurav Das

Layered reward signalling through octopamine and dopamine in Drosophila

Activity of Defined Mushroom Body Output Neurons Underlies Learned Olfactory Behavior in Drosophila

Drosophila Learn Opposing Components of a Compound Food Stimulus

Cyclin D1 fine-tunes the neurogenic output of embryonic retinal progenitor cells

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