Your search keyword '"Zlatic M"' showing total 7 results

1. Circuits for integrating learned and innate valences in the insect brain.

Author

Eschbach C, Fushiki A, Winding M, Afonso B, Andrade IV, Cocanougher BT, Eichler K, Gepner R, Si G, Valdes-Aleman J, Fetter RD, Gershow M, Jefferis GS, Samuel AD, Truman JW, Cardona A, and Zlatic M

Subjects

Animals, Brain physiology, Connectome, Drosophila melanogaster growth & development, Larva growth & development, Larva physiology, Learning physiology, Drosophila melanogaster physiology, Mushroom Bodies physiology, Neurons physiology

Abstract

Animal behavior is shaped both by evolution and by individual experience. Parallel brain pathways encode innate and learned valences of cues, but the way in which they are integrated during action-selection is not well understood. We used electron microscopy to comprehensively map with synaptic resolution all neurons downstream of all mushroom body (MB) output neurons (encoding learned valences) and characterized their patterns of interaction with lateral horn (LH) neurons (encoding innate valences) in Drosophila larva. The connectome revealed multiple convergence neuron types that receive convergent MB and LH inputs. A subset of these receives excitatory input from positive-valence MB and LH pathways and inhibitory input from negative-valence MB pathways. We confirmed functional connectivity from LH and MB pathways and behavioral roles of two of these neurons. These neurons encode integrated odor value and bidirectionally regulate turning. Based on this, we speculate that learning could potentially skew the balance of excitation and inhibition onto these neurons and thereby modulate turning. Together, our study provides insights into the circuits that integrate learned and innate valences to modify behavior., Competing Interests: CE, AF, MW, BA, IA, BC, KE, RG, GS, JV, RF, MG, GJ, AS, JT, AC, MZ No competing interests declared, (© 2021, Eschbach et al.)

Published

2021

2. Identifying neural substrates of competitive interactions and sequence transitions during mechanosensory responses in Drosophila.

Author

Masson JB, Laurent F, Cardona A, Barré C, Skatchkovsky N, Zlatic M, and Jovanic T

Subjects

Animals, Animals, Genetically Modified, Brain anatomy & histology, Brain metabolism, Brain Mapping, Cues, Drosophila melanogaster genetics, Neural Pathways metabolism, Neurons metabolism, Phenotype, Action Potentials physiology, Binding, Competitive physiology, Mechanotransduction, Cellular physiology, Neural Pathways physiology, Neurons physiology, Sensory Receptor Cells physiology, Synaptic Transmission physiology

Abstract

Nervous systems have the ability to select appropriate actions and action sequences in response to sensory cues. The circuit mechanisms by which nervous systems achieve choice, stability and transitions between behaviors are still incompletely understood. To identify neurons and brain areas involved in controlling these processes, we combined a large-scale neuronal inactivation screen with automated action detection in response to a mechanosensory cue in Drosophila larva. We analyzed behaviors from 2.9x105 larvae and identified 66 candidate lines for mechanosensory responses out of which 25 for competitive interactions between actions. We further characterize in detail the neurons in these lines and analyzed their connectivity using electron microscopy. We found the neurons in the mechanosensory network are located in different regions of the nervous system consistent with a distributed model of sensorimotor decision-making. These findings provide the basis for understanding how selection and transition between behaviors are controlled by the nervous system., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

3. Functional architecture of reward learning in mushroom body extrinsic neurons of larval Drosophila.

Author

Saumweber T, Rohwedder A, Schleyer M, Eichler K, Chen YC, Aso Y, Cardona A, Eschbach C, Kobler O, Voigt A, Durairaja A, Mancini N, Zlatic M, Truman JW, Thum AS, and Gerber B

Subjects

Animals, Behavior, Animal, Drosophila cytology, Drosophila growth & development, Female, Larva growth & development, Larva physiology, Learning, Male, Reward, Smell, Taste, Drosophila physiology, Mushroom Bodies physiology, Neurons physiology

Abstract

The brain adaptively integrates present sensory input, past experience, and options for future action. The insect mushroom body exemplifies how a central brain structure brings about such integration. Here we use a combination of systematic single-cell labeling, connectomics, transgenic silencing, and activation experiments to study the mushroom body at single-cell resolution, focusing on the behavioral architecture of its input and output neurons (MBINs and MBONs), and of the mushroom body intrinsic APL neuron. Our results reveal the identity and morphology of almost all of these 44 neurons in stage 3 Drosophila larvae. Upon an initial screen, functional analyses focusing on the mushroom body medial lobe uncover sparse and specific functions of its dopaminergic MBINs, its MBONs, and of the GABAergic APL neuron across three behavioral tasks, namely odor preference, taste preference, and associative learning between odor and taste. Our results thus provide a cellular-resolution study case of how brains organize behavior.

Published

2018

4. Divergent Connectivity of Homologous Command-like Neurons Mediates Segment-Specific Touch Responses in Drosophila.

Author

Takagi S, Cocanougher BT, Niki S, Miyamoto D, Kohsaka H, Kazama H, Fetter RD, Truman JW, Zlatic M, Cardona A, and Nose A

Subjects

Animals, Animals, Genetically Modified, Brain ultrastructure, Calcium metabolism, Channelrhodopsins genetics, Channelrhodopsins metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Larva physiology, Locomotion genetics, Male, Microscopy, Electron, Neurons ultrastructure, Neurotransmitter Agents metabolism, Optogenetics, Physical Stimulation, RNA Interference physiology, Vesicular Glutamate Transport Proteins metabolism, Brain physiology, Locomotion physiology, Neurons physiology, Touch physiology

Abstract

Animals adaptively respond to a tactile stimulus by choosing an ethologically relevant behavior depending on the location of the stimuli. Here, we investigate how somatosensory inputs on different body segments are linked to distinct motor outputs in Drosophila larvae. Larvae escape by backward locomotion when touched on the head, while they crawl forward when touched on the tail. We identify a class of segmentally repeated second-order somatosensory interneurons, that we named Wave, whose activation in anterior and posterior segments elicit backward and forward locomotion, respectively. Anterior and posterior Wave neurons extend their dendrites in opposite directions to receive somatosensory inputs from the head and tail, respectively. Downstream of anterior Wave neurons, we identify premotor circuits including the neuron A03a5, which together with Wave, is necessary for the backward locomotion touch response. Thus, Wave neurons match their receptive field to appropriate motor programs by participating in different circuits in different segments., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

5. Facilitating Neuron-Specific Genetic Manipulations in Drosophila melanogaster Using a Split GAL4 Repressor.

Author

Dolan MJ, Luan H, Shropshire WC, Sutcliffe B, Cocanougher B, Scott RL, Frechter S, Zlatic M, Jefferis GSXE, and White BH

Subjects

Animals, DNA-Binding Proteins biosynthesis, Drosophila Proteins antagonists & inhibitors, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Gene Expression Regulation, Developmental, Transcription Factors antagonists & inhibitors, DNA-Binding Proteins genetics, Drosophila Proteins genetics, Neurons metabolism, Repressor Proteins genetics, Transcription Factors genetics

Abstract

Efforts to map neural circuits have been galvanized by the development of genetic technologies that permit the manipulation of targeted sets of neurons in the brains of freely behaving animals. The success of these efforts relies on the experimenter's ability to target arbitrarily small subsets of neurons for manipulation, but such specificity of targeting cannot routinely be achieved using existing methods. In Drosophila melanogaster , a widely-used technique for refined cell type-specific manipulation is the Split GAL4 system, which augments the targeting specificity of the binary GAL4-UAS (Upstream Activating Sequence) system by making GAL4 transcriptional activity contingent upon two enhancers, rather than one. To permit more refined targeting, we introduce here the "Killer Zipper" (KZip + ), a suppressor that makes Split GAL4 targeting contingent upon a third enhancer. KZip + acts by disrupting both the formation and activity of Split GAL4 heterodimers, and we show how this added layer of control can be used to selectively remove unwanted cells from a Split GAL4 expression pattern or to subtract neurons of interest from a pattern to determine their requirement in generating a given phenotype. To facilitate application of the KZip + technology, we have developed a versatile set of LexA op -KZip + fly lines that can be used directly with the large number of LexA driver lines with known expression patterns. KZip + significantly sharpens the precision of neuronal genetic control available in Drosophila and may be extended to other organisms where Split GAL4-like systems are used., (Copyright © 2017 Dolan et al.)

Published

2017

6. Discovery of brainwide neural-behavioral maps via multiscale unsupervised structure learning.

Author

Vogelstein JT, Park Y, Ohyama T, Kerr RA, Truman JW, Priebe CE, and Zlatic M

Subjects

Animals, Artificial Intelligence, Brain physiology, Brain Mapping, Drosophila melanogaster cytology, Larva physiology, Locomotion, Motor Neurons physiology, Movement, Optogenetics, Behavior, Animal, Drosophila melanogaster physiology, Neurons physiology

Abstract

A single nervous system can generate many distinct motor patterns. Identifying which neurons and circuits control which behaviors has been a laborious piecemeal process, usually for one observer-defined behavior at a time. We present a fundamentally different approach to neuron-behavior mapping. We optogenetically activated 1054 identified neuron lines in Drosophila larvae and tracked the behavioral responses from 37,780 animals. Application of multiscale unsupervised structure learning methods to the behavioral data enabled us to identify 29 discrete, statistically distinguishable, observer-unbiased behavioral phenotypes. Mapping the neural lines to the behavior(s) they evoke provides a behavioral reference atlas for neuron subsets covering a large fraction of larval neurons. This atlas is a starting point for connectivity- and activity-mapping studies to further investigate the mechanisms by which neurons mediate diverse behaviors.

Published

2014

7. A combinatorial semaphorin code instructs the initial steps of sensory circuit assembly in the Drosophila CNS.

Author

Wu Z, Sweeney LB, Ayoob JC, Chak K, Andreone BJ, Ohyama T, Kerr R, Luo L, Zlatic M, and Kolodkin AL

Subjects

Afferent Pathways embryology, Alkaline Phosphatase metabolism, Animals, Animals, Genetically Modified, Axons physiology, Behavior, Animal, Body Patterning genetics, Central Nervous System cytology, Central Nervous System embryology, Drosophila, Drosophila Proteins genetics, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Green Fluorescent Proteins genetics, Membrane Glycoproteins metabolism, Movement physiology, Mutation genetics, Nerve Tissue Proteins genetics, Neurons cytology, Physical Stimulation, Receptors, Cell Surface genetics, Semaphorins classification, Semaphorins genetics, Signal Transduction genetics, Signal Transduction physiology, Vibration, Afferent Pathways physiology, Body Patterning physiology, Central Nervous System physiology, Drosophila Proteins metabolism, Nerve Tissue Proteins metabolism, Neurons physiology, Receptors, Cell Surface metabolism, Semaphorins physiology

Abstract

Longitudinal axon fascicles within the Drosophila embryonic CNS provide connections between body segments and are required for coordinated neural signaling along the anterior-posterior axis. We show here that establishment of select CNS longitudinal tracts and formation of precise mechanosensory afferent innervation to the same CNS region are coordinately regulated by the secreted semaphorins Sema-2a and Sema-2b. Both Sema-2a and Sema-2b utilize the same neuronal receptor, plexin B (PlexB), but serve distinct guidance functions. Localized Sema-2b attraction promotes the initial assembly of a subset of CNS longitudinal projections and subsequent targeting of chordotonal sensory afferent axons to these same longitudinal connectives, whereas broader Sema-2a repulsion serves to prevent aberrant innervation. In the absence of Sema-2b or PlexB, chordotonal afferent connectivity within the CNS is severely disrupted, resulting in specific larval behavioral deficits. These results reveal that distinct semaphorin-mediated guidance functions converge at PlexB and are critical for functional neural circuit assembly., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011