Your search keyword '"behavioral valence"' showing total 5 results

1. Motivational and Valence‐Related Modulation of Sleep/Wake Behavior are Mediated by Midbrain Dopamine and Uncoupled from the Homeostatic and Circadian Processes

Author

Karim Fifel, Amina El Farissi, Yoan Cherasse, and Masashi Yanagisawa

Subjects

behavioral valence, dopamine, motivation, sleep regulation, Science

Abstract

Abstract Motivation and its hedonic valence are powerful modulators of sleep/wake behavior, yet its underlying mechanism is still poorly understood. Given the well‐established role of midbrain dopamine (mDA) neurons in encoding motivation and emotional valence, here, neuronal mechanisms mediating sleep/wake regulation are systematically investigated by DA neurotransmission. It is discovered that mDA mediates the strong modulation of sleep/wake states by motivational valence. Surprisingly, this modulation can be uncoupled from the classically employed measures of circadian and homeostatic processes of sleep regulation. These results establish the experimental foundation for an additional new factor of sleep regulation. Furthermore, an electroencephalographic marker during wakefulness at the theta range is identified that can be used to reliably track valence‐related modulation of sleep. Taken together, this study identifies mDA signaling as an important neural substrate mediating sleep modulation by motivational valence.

Published

2022

2. A big picture of a small brain

Author

Leslie C Griffith

Subjects

mushroom body, olfactory learning, associative memory, behavioral valence, sleep, Medicine, Science, Biology (General), QH301-705.5

Abstract

A detailed map of the neurons that carry information away from the mushroom bodies in the brains of fruit flies has improved our understanding of the ways in which experiences can modify behaviour.

Published

2014

3. Mushroom body output neurons encode valence and guide memory-based action selection in Drosophila

Author

Yoshinori Aso, Divya Sitaraman, Toshiharu Ichinose, Karla R Kaun, Katrin Vogt, Ghislain Belliart-Guérin, Pierre-Yves Plaçais, Alice A Robie, Nobuhiro Yamagata, Christopher Schnaitmann, William J Rowell, Rebecca M Johnston, Teri-T B Ngo, Nan Chen, Wyatt Korff, Michael N Nitabach, Ulrike Heberlein, Thomas Preat, Kristin M Branson, Hiromu Tanimoto, and Gerald M Rubin

Subjects

mushroom body, memory, behavioral valence, sleep, population code, action selection, Medicine, Science, Biology (General), QH301-705.5

Abstract

Animals discriminate stimuli, learn their predictive value and use this knowledge to modify their behavior. In Drosophila, the mushroom body (MB) plays a key role in these processes. Sensory stimuli are sparsely represented by ∼2000 Kenyon cells, which converge onto 34 output neurons (MBONs) of 21 types. We studied the role of MBONs in several associative learning tasks and in sleep regulation, revealing the extent to which information flow is segregated into distinct channels and suggesting possible roles for the multi-layered MBON network. We also show that optogenetic activation of MBONs can, depending on cell type, induce repulsion or attraction in flies. The behavioral effects of MBON perturbation are combinatorial, suggesting that the MBON ensemble collectively represents valence. We propose that local, stimulus-specific dopaminergic modulation selectively alters the balance within the MBON network for those stimuli. Our results suggest that valence encoded by the MBON ensemble biases memory-based action selection.

Published

2014

4. Mushroom body output neurons encode valence and guide memory-based action selection in Drosophila

Author

Toshiharu Ichinose, Teri T.B. Ngo, Karla R. Kaun, Christopher Schnaitmann, Thomas Preat, Ghislain Belliart-Guérin, Nobuhiro Yamagata, Alice A. Robie, Divya Sitaraman, Ulrike Heberlein, Wyatt Korff, Pierre-Yves Plaçais, Nan Chen, Katrin Vogt, William J Rowell, Gerald M. Rubin, Michael N. Nitabach, Yoshinori Aso, Rebecca M. Johnston, Hiromu Tanimoto, and Kristin Branson

Subjects

Sensory Receptor Cells, QH301-705.5, Logic, Science, Sensory system, Optogenetics, Stimulus (physiology), Biology, Choice Behavior, General Biochemistry, Genetics and Molecular Biology, action selection, memory, 03 medical and health sciences, 0302 clinical medicine, ddc:570, Premovement neuronal activity, Animals, Olfactory memory, Biology (General), sleep, Mushroom Bodies, 030304 developmental biology, Neurons, 0303 health sciences, behavioral valence, General Immunology and Microbiology, D. melanogaster, Long-term memory, General Neuroscience, fungi, Association Learning, General Medicine, mushroom body, Associative learning, Drosophila melanogaster, nervous system, population code, Mushroom bodies, Medicine, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Animals discriminate stimuli, learn their predictive value and use this knowledge to modify their behavior. In Drosophila, the mushroom body (MB) plays a key role in these processes. Sensory stimuli are sparsely represented by ∼2000 Kenyon cells, which converge onto 34 output neurons (MBONs) of 21 types. We studied the role of MBONs in several associative learning tasks and in sleep regulation, revealing the extent to which information flow is segregated into distinct channels and suggesting possible roles for the multi-layered MBON network. We also show that optogenetic activation of MBONs can, depending on cell type, induce repulsion or attraction in flies. The behavioral effects of MBON perturbation are combinatorial, suggesting that the MBON ensemble collectively represents valence. We propose that local, stimulus-specific dopaminergic modulation selectively alters the balance within the MBON network for those stimuli. Our results suggest that valence encoded by the MBON ensemble biases memory-based action selection. DOI: http://dx.doi.org/10.7554/eLife.04580.001, eLife digest An animal's survival depends on its ability to respond appropriately to its environment, approaching stimuli that signal rewards and avoiding any that warn of potential threats. In fruit flies, this behavior requires activity in a region of the brain called the mushroom body, which processes sensory information and uses that information to influence responses to stimuli. Aso et al. recently mapped the mushroom body of the fruit fly in its entirety. This work showed, among other things, that the mushroom body contained 21 different types of output neurons. Building on this work, Aso et al. have started to work out how this circuitry enables flies to learn to associate a stimulus, such as an odor, with an outcome, such as the presence of food. Two complementary techniques—the use of molecular genetics to block neuronal activity, and the use of light to activate neurons (a technique called optogenetics)—were employed to study the roles performed by the output neurons in the mushroom body. Results revealed that distinct groups of output cells must be activated for flies to avoid—as opposed to approach—odors. Moreover, the same output neurons are used to avoid both odors and colors that have been associated with punishment. Together, these results indicate that the output cells do not encode the identity of stimuli: rather, they signal whether a stimulus should be approached or avoided. The output cells also regulate the amount of sleep taken by the fly, which is consistent with the mushroom body having a broader role in regulating the fly's internal state. The results of these experiments—combined with new knowledge about the detailed structure of the mushroom body—lay the foundations for new studies that explore associative learning at the level of individual circuits and their component cells. Given that the organization of the mushroom body has much in common with that of the mammalian brain, these studies should provide insights into the fundamental principles that underpin learning and memory in other species, including humans. DOI: http://dx.doi.org/10.7554/eLife.04580.002

Published

2014

5. The neuronal architecture of the mushroom body provides a logic for associative learning

Author

Heather Dionne, Yang Yu, Richard Axel, Teri T.B. Ngo, Daisuke Hattori, Nirmala Iyer, Larry F. Abbott, Gerald M. Rubin, Yoshinori Aso, Rebecca M. Johnston, and Hiromu Tanimoto

Subjects

Olfactory system, Biology (General), Neurotransmitter Agents, D. melanogaster, General Neuroscience, Brain, General Medicine, Anatomy, Olfactory Pathways, Content-addressable memory, Smell, medicine.anatomical_structure, Drosophila melanogaster, Mushroom bodies, Medicine, Olfactory Learning, dopamine, Insight, Research Article, associative memory, Sensory Receptor Cells, Logic, QH301-705.5, Science, Green Fluorescent Proteins, Models, Neurological, Sensory system, Biology, neuronal circuits, General Biochemistry, Genetics and Molecular Biology, medicine, Animals, olfactory learning, sleep, Cell Shape, Mushroom Bodies, behavioral valence, General Immunology and Microbiology, Dopaminergic Neurons, Association Learning, neuronal circuit, Dendrites, mushroom body, Associative learning, Cell Compartmentation, nervous system, plasticity, Antennal lobe, Neuron, Neuroscience

Abstract

We identified the neurons comprising the Drosophila mushroom body (MB), an associative center in invertebrate brains, and provide a comprehensive map describing their potential connections. Each of the 21 MB output neuron (MBON) types elaborates segregated dendritic arbors along the parallel axons of ∼2000 Kenyon cells, forming 15 compartments that collectively tile the MB lobes. MBON axons project to five discrete neuropils outside of the MB and three MBON types form a feedforward network in the lobes. Each of the 20 dopaminergic neuron (DAN) types projects axons to one, or at most two, of the MBON compartments. Convergence of DAN axons on compartmentalized Kenyon cell–MBON synapses creates a highly ordered unit that can support learning to impose valence on sensory representations. The elucidation of the complement of neurons of the MB provides a comprehensive anatomical substrate from which one can infer a functional logic of associative olfactory learning and memory. DOI: http://dx.doi.org/10.7554/eLife.04577.001, eLife digest One of the key goals of neuroscience is to understand how specific circuits of brain cells enable animals to respond optimally to the constantly changing world around them. Such processes are more easily studied in simpler brains, and the fruit fly—with its small size, short life cycle, and well-developed genetic toolkit—is widely used to study the genes and circuits that underlie learning and behavior. Fruit flies can learn to approach odors that have previously been paired with food, and also to avoid any odors that have been paired with an electric shock, and a part of the brain called the mushroom body has a central role in this process. When odorant molecules bind to receptors on the fly's antennae, they activate neurons in the antennal lobe of the brain, which in turn activate cells called Kenyon cells within the mushroom body. The Kenyon cells then activate output neurons that convey signals to other parts of the brain. It is known that relatively few Kenyon cells are activated by any given odor. Moreover, it seems that a given odor activates different sets of Kenyon cells in different flies. Because the association between an odor and the Kenyon cells it activates is unique to each fly, each fly needs to learn through its own experiences what a particular pattern of Kenyon cell activation means. Aso et al. have now applied sophisticated molecular genetic and anatomical techniques to thousands of different transgenic flies to identify the neurons of the mushroom body. The resulting map reveals that the mushroom body contains roughly 2200 neurons, including seven types of Kenyon cells and 21 types of output cells, as well as 20 types of neurons that use the neurotransmitter dopamine. Moreover, this map provides insights into the circuits that support odor-based learning. It reveals, for example, that the mushroom body can be divided into 15 anatomical compartments that are each defined by the presence of a specific set of output and dopaminergic neuron cell types. Since the dopaminergic neurons help to shape a fly's response to odors on the basis of previous experience, this organization suggests that these compartments may be semi-autonomous information processing units. In contrast to the rest of the insect brain, the mushroom body has a flexible organization that is similar to that of the mammalian brain. Elucidating the circuits that support associative learning in fruit flies should therefore make it easier to identify the equivalent mechanisms in vertebrate animals. DOI: http://dx.doi.org/10.7554/eLife.04577.002

Published

2014