Four GABAergic Interneurons Impose Feeding Restraint in Drosophila

Pool, Allan-Hermann; Kvello, Pål; Mann, Kevin; Cheung, Samantha K.; Gordon, Michael D.; Wang, Liming; Scott, Kristin

doi:10.1016/j.neuron.2014.05.006

Cited by 87 publications

(89 citation statements)

References 60 publications

(84 reference statements)

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“…We therefore asked whether fluid ingestion is a critical step for both types of food cues to suppress starvation-induced hyperactivity. Mutant flies with overfeeding and overingestion phenotypes exhibit normal starvation-induced hyperactivity (27). Consistently, we found that certain concentrations (e.g., 200 mM) of sorbitol failed to suppress starvation-induced hyperactivity, but could nevertheless support fly survival, which must be accompanied Student's t test (C) and one-way ANOVA (F and H) were applied for statistical analysis.…”

Section: Significancesupporting

confidence: 68%

Octopamine mediates starvation-induced hyperactivity in adult Drosophila

Yang

Zhang

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Starved animals often exhibit elevated locomotion, which has been speculated to partly resemble foraging behavior and facilitate food acquisition and energy intake. Despite its importance, the neural mechanism underlying this behavior remains unknown in any species. In this study we confirmed and extended previous findings that starvation induced locomotor activity in adult fruit flies Drosophila melanogaster. We also showed that starvationinduced hyperactivity was directed toward the localization and acquisition of food sources, because it could be suppressed upon the detection of food cues via both central nutrient-sensing and peripheral sweet-sensing mechanisms, via induction of food ingestion. We further found that octopamine, the insect counterpart of vertebrate norepinephrine, as well as the neurons expressing octopamine, were both necessary and sufficient for starvationinduced hyperactivity. Octopamine was not required for starvation-induced changes in feeding behaviors, suggesting independent regulations of energy intake behaviors upon starvation. Taken together, our results establish a quantitative behavioral paradigm to investigate the regulation of energy homeostasis by the CNS and identify a conserved neural substrate that links organismal metabolic state to a specific behavioral output.T he CNS plays an essential role in energy homeostasis (1). It actively monitors changes in the internal energy state and modulates an array of physiological and behavioral responses to enable energy homeostasis. Foraging behavior is critical for the localization and acquisition of food supply and hence energy homeostasis. It has been extensively documented both in ethological settings (2, 3) and under well-controlled laboratory conditions (4). Laboratory rodents with limited food access exhibit stereotypic food anticipatory activity (FAA) several hours before the mealtime, which is characterized by a steady increase in locomotion and other appetitive behaviors (5). The neural substrate that drives FAA still remains elusive (5, 6). Notably, the regulation of FAA seems to be dissociable from that of feeding behavior (7,8). These results hint at the presence of an independent and somewhat discrete regulatory mechanism of foraging behavior.Foraging behavior has also been extensively studied in invertebrate species such as the roundworm Caenorhabditis elegans (9) and fruit flies Drosophila melanogaster (10). Roundworm populations exhibit two naturally emerged foraging patterns: "solitary" worms disperse across the bacterial lawn, and "social" worms aggregate along the food edge and form clumps (9). This behavioral dimorphism is controlled by natural variations of the npr-1 (neuropeptide receptor resemblance) gene that encodes a receptor homologous to the receptor family of orexigenic neuropeptide Y in mammals (9). A comparable scenario has also been identified in larval fruit flies (10), with two distinct forms of foraging present in nature: "rover" and "sitter." On food sources, sitter but not rover reduces moving speed ...

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Section: Significancesupporting

confidence: 68%

Octopamine mediates starvation-induced hyperactivity in adult Drosophila

Yang

Zhang

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

158

180

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“…The AMMC has also been implicated in auditory processing suggesting this may be a generalized sensory processing center (Lai et al 2012, Tootoonian et al 2012, Vaughan et al 2014). In addition, a number of interneurons have been identified that modulate feeding in accordance with other competing behaviors or satiation state, suggesting complex central brain circuitry underlies innate feeding behavior (Marella et al 2012, Flood et al 2013, Mann et al 2013, Pool et al 2014). While much is known about the coding of sweet and bitter tastants by GRNs, and how both motoneurons and interneurons govern behavioral response to tastants (Gordon and Scott 2009, Manzo et al 2012), fewer studies have examined how gustatory information is processed and transferred to higher brain centers.…”

Section: Taste Processing In Drosophilamentioning

confidence: 99%

“…The fly brain contains only ~300 dopamine neurons (Nassel and Elekes 1992), composed of 20 distinct clusters that have been implicated in numerous memory modalities (Friggi-Grelin et al 2003) and innervate diverse brain regions including the mushroom bodies (MBs) and GNG (Marella et al 2012, Pool et al 2014). To identify whether dopamine neurons are required for aversive taste memory, Kirkhart and Scott (2015) silenced two populations of dopamine neurons, PAM and PPL1, through expression of the dominant negative GTPAse Shibire TS1 .…”

Section: Neuroanatomy Of Aversive Taste Memorymentioning

confidence: 99%

Gustatory processing and taste memory inDrosophila

Mašek

Keene

2016

Journal of Neurogenetics

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Taste allows animals to discriminate the value and potential toxicity of food prior to ingestion. Many tastants elicit an innate attractive or avoidance response that is modifiable with nutritional state and prior experience. A powerful genetic tool kit, well-characterized gustatory system, and standardized behavioral assays make the fruit fly, Drosophila melanogaster, an excellent system for investigating taste processing and memory. Recent studies have used this system to identify the neural basis for acquired taste preference. These studies have revealed a role for dopamine-mediated plasticity of the mushroom bodies that modulate the threshold of response to appetitive tastants. The identification of neural circuitry regulating taste memory provides a system to study the genetic and physiological processes that govern plasticity within a defined memory circuit.

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“…Thus, expressing GAL4 and FLP in two partially overlapping enhancer patterns removes GAL80 and allows GAL4 to activate a UAS-controlled transgene in the intersectional cells (Shang et al 2008;Bohm et al 2010;Pool et al 2014). Notably, this method requires four transgenes: 1) a ubiquitously expressed, FRT-flanked GAL80 cassette, 2) an enhancer-FLP line, 3) an enhancer-GAL4 line, and 4) a coding sequence of interest expressed under UAS control.…”

Section: Intersectional Techniques For Identifying Behaviorally Relevmentioning

confidence: 99%

“…In the case where a FLP-based method is being used, a GAL4 line that expresses in a neuron of interest is screened against a FLP enhancer trap library (Bohm et al 2010;Rezával et al 2012;Pool et al 2014). Although it is feasible that intersectional approaches can refine expression patterns to a single neuron (Figure 3a,b), in many cases the neurons of interest are not the only ones targeted by a particular spGAL4 or FLP/FRT pattern.…”

Section: Intersectional Techniques For Identifying Behaviorally Relevmentioning

confidence: 99%

Targeted manipulation of neuronal activity in behaving adult flies

Hampel

Seeds

2016

Preprint

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The ability to control the activity of specific neurons in freely behaving animals provides an effective way to probe the contributions of neural circuits to behavior. Wide interest in studying principles of neural circuit function using the fruit fly Drosophila melanogaster has fueled the construction of an extensive transgenic toolkit for performing such neural manipulations. Here we describe approaches for using these tools to manipulate the activity of specific neurons and assess how those manipulations impact the behavior of flies. We also describe methods for examining connectivity among multiple neurons that together form a neural circuit controlling a specific behavior. This work provides a resource ABSTRACTThe ability to control the activity of specific neurons in freely behaving animals provides an effective way to probe the contributions of neural circuits to behavior. Wide interest in studying principles of neural circuit function using the fruit fly Drosophila melanogaster has fueled the construction of an extensive transgenic toolkit for performing such neural manipulations. Here we describe approaches for using these tools to manipulate the activity of specific neurons and assess how those manipulations impact the behavior of flies. We also describe methods for examining connectivity among multiple neurons that together form a neural circuit controlling a specific behavior. This work provides a resource for researchers interested in examining how neurons and neural circuits contribute to the rich repertoire of behaviors performed by flies.

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Four GABAergic Interneurons Impose Feeding Restraint in Drosophila

Cited by 87 publications

References 60 publications

Octopamine mediates starvation-induced hyperactivity in adult Drosophila

Octopamine mediates starvation-induced hyperactivity in adult Drosophila

Gustatory processing and taste memory inDrosophila

Targeted manipulation of neuronal activity in behaving adult flies

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