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

1. Comparative Connectomics Reveals How Partner Identity, Location, and Activity Specify Synaptic Connectivity in Drosophila.

Author

Valdes-Aleman J, Fetter RD, Sales EC, Heckman EL, Venkatasubramanian L, Doe CQ, Landgraf M, Cardona A, and Zlatic M

Subjects

Animals, Animals, Genetically Modified, Drosophila melanogaster, Interneurons chemistry, Nerve Net chemistry, Optogenetics methods, Synapses chemistry, Synapses genetics, Connectome methods, Interneurons metabolism, Nerve Net metabolism, Synapses metabolism

Abstract

The mechanisms by which synaptic partners recognize each other and establish appropriate numbers of connections during embryonic development to form functional neural circuits are poorly understood. We combined electron microscopy reconstruction, functional imaging of neural activity, and behavioral experiments to elucidate the roles of (1) partner identity, (2) location, and (3) activity in circuit assembly in the embryonic nerve cord of Drosophila. We found that postsynaptic partners are able to find and connect to their presynaptic partners even when these have been shifted to ectopic locations or silenced. However, orderly positioning of axon terminals by positional cues and synaptic activity is required for appropriate numbers of connections between specific partners, for appropriate balance between excitatory and inhibitory connections, and for appropriate functional connectivity and behavior. Our study reveals with unprecedented resolution the fine connectivity effects of multiple factors that work together to control the assembly of neural circuits., Competing Interests: Declaration of Interests The authors declare no competing interests., (Crown Copyright © 2020. Published by Elsevier Inc. All rights reserved.)

Published

2021

2. Neural Substrates of Drosophila Larval Anemotaxis.

Author

Jovanic T, Winding M, Cardona A, Truman JW, Gershow M, and Zlatic M

Subjects

Air Movements, Animals, Drosophila growth & development, Larva physiology, Sensory Receptor Cells physiology, Drosophila physiology, Taxis Response physiology, Wind

Abstract

Animals use sensory information to move toward more favorable conditions. Drosophila larvae can move up or down gradients of odors (chemotax), light (phototax), and temperature (thermotax) by modulating the probability, direction, and size of turns based on sensory input. Whether larvae can anemotax in gradients of mechanosensory cues is unknown. Further, although many of the sensory neurons that mediate taxis have been described, the central circuits are not well understood. Here, we used high-throughput, quantitative behavioral assays to demonstrate Drosophila larvae anemotax in gradients of wind speeds and to characterize the behavioral strategies involved. We found that larvae modulate the probability, direction, and size of turns to move away from higher wind speeds. This suggests that similar central decision-making mechanisms underlie taxis in somatosensory and other sensory modalities. By silencing the activity of single or very few neuron types in a behavioral screen, we found two sensory (chordotonal and multidendritic class III) and six nerve cord neuron types involved in anemotaxis. We reconstructed the identified neurons in an electron microscopy volume that spans the entire larval nervous system and found they received direct input from the mechanosensory neurons or from each other. In this way, we identified local interneurons and first- and second-order subesophageal zone (SEZ) and brain projection neurons. Finally, silencing a dopaminergic brain neuron type impairs anemotaxis. These findings suggest that anemotaxis involves both nerve cord and brain circuits. The candidate neurons and circuitry identified in our study provide a basis for future detailed mechanistic understanding of the circuit principles of anemotaxis., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

3. 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

4. Competitive Disinhibition Mediates Behavioral Choice and Sequences in Drosophila.

Author

Jovanic T, Schneider-Mizell CM, Shao M, Masson JB, Denisov G, Fetter RD, Mensh BD, Truman JW, Cardona A, and Zlatic M

Subjects

Animals, Larva physiology, Optogenetics, Choice Behavior physiology, Drosophila melanogaster physiology, Feedback, Sensory physiology, Mechanotransduction, Cellular physiology, Renshaw Cells physiology

Abstract

Even a simple sensory stimulus can elicit distinct innate behaviors and sequences. During sensorimotor decisions, competitive interactions among neurons that promote distinct behaviors must ensure the selection and maintenance of one behavior, while suppressing others. The circuit implementation of these competitive interactions is still an open question. By combining comprehensive electron microscopy reconstruction of inhibitory interneuron networks, modeling, electrophysiology, and behavioral studies, we determined the circuit mechanisms that contribute to the Drosophila larval sensorimotor decision to startle, explore, or perform a sequence of the two in response to a mechanosensory stimulus. Together, these studies reveal that, early in sensory processing, (1) reciprocally connected feedforward inhibitory interneurons implement behavioral choice, (2) local feedback disinhibition provides positive feedback that consolidates and maintains the chosen behavior, and (3) lateral disinhibition promotes sequence transitions. The combination of these interconnected circuit motifs can implement both behavior selection and the serial organization of behaviors into a sequence., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

5. Four Individually Identified Paired Dopamine Neurons Signal Reward in Larval Drosophila.

Author

Rohwedder A, Wenz NL, Stehle B, Huser A, Yamagata N, Zlatic M, Truman JW, Tanimoto H, Saumweber T, Gerber B, and Thum AS

Subjects

Animals, Dopaminergic Neurons physiology, Drosophila growth & development, Larva physiology, Reward, Tyrosine 3-Monooxygenase genetics, Tyrosine 3-Monooxygenase metabolism, Drosophila physiology, Mushroom Bodies physiology

Abstract

Dopaminergic neurons serve multiple functions, including reinforcement processing during associative learning [1-12]. It is thus warranted to understand which dopaminergic neurons mediate which function. We study larval Drosophila, in which only approximately 120 of a total of 10,000 neurons are dopaminergic, as judged by the expression of tyrosine hydroxylase (TH), the rate-limiting enzyme of dopamine biosynthesis [5, 13]. Dopaminergic neurons mediating reinforcement in insect olfactory learning target the mushroom bodies, a higher-order "cortical" brain region [1-5, 11, 12, 14, 15]. We discover four previously undescribed paired neurons, the primary protocerebral anterior medial (pPAM) neurons. These neurons are TH positive and subdivide the medial lobe of the mushroom body into four distinct subunits. These pPAM neurons are acutely necessary for odor-sugar reward learning and require intact TH function in this process. However, they are dispensable for aversive learning and innate behavior toward the odors and sugars employed. Optogenetical activation of pPAM neurons is sufficient as a reward. Thus, the pPAM neurons convey a likely dopaminergic reward signal. In contrast, DL1 cluster neurons convey a corresponding punishment signal [5], suggesting a cellular division of labor to convey dopaminergic reward and punishment signals. On the level of individually identified neurons, this uncovers an organizational principle shared with adult Drosophila and mammals [1-4, 7, 9, 10] (but see [6]). The numerical simplicity and connectomic tractability of the larval nervous system [16-19] now offers a prospect for studying circuit principles of dopamine function at unprecedented resolution., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

6. 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

7. Genetic specification of axonal arbors: atonal regulates robo3 to position terminal branches in the Drosophila nervous system.

Author

Zlatic M, Landgraf M, and Bate M

Subjects

Animals, Axons metabolism, Basic Helix-Loop-Helix Transcription Factors, Cell Communication genetics, DNA-Binding Proteins genetics, Drosophila melanogaster cytology, Drosophila melanogaster growth & development, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Female, Functional Laterality genetics, Growth Cones metabolism, Growth Cones ultrastructure, Larva cytology, Larva growth & development, Larva metabolism, Male, Membrane Proteins genetics, Membrane Proteins metabolism, Mutation physiology, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Nervous System cytology, Nervous System growth & development, Nervous System Malformations genetics, Neuronal Plasticity genetics, Neurons, Afferent cytology, Neurons, Afferent metabolism, Presynaptic Terminals metabolism, Presynaptic Terminals ultrastructure, Receptors, Immunologic genetics, Axons ultrastructure, Cell Differentiation genetics, DNA-Binding Proteins metabolism, Drosophila Proteins, Drosophila melanogaster embryology, Gene Expression Regulation, Developmental genetics, Nervous System embryology, Receptors, Immunologic metabolism

Abstract

Drosophila sensory neurons form distinctive terminal branch patterns in the developing neuropile of the embryonic central nervous system. In this paper we make a genetic analysis of factors regulating arbor position. We show that mediolateral position is determined in a binary fashion by expression (chordotonal neurons) or nonexpression (multidendritic neurons) of the Robo3 receptor for the midline repellent Slit. Robo3 expression is one of a suite of chordotonal neuron properties that depend on expression of the proneural gene atonal. Different features of terminal branches are separately regulated: an arbor can be shifted mediolaterally without affecting its dorsoventral location, and the distinctive remodeling of one arbor continues as normal despite this arbor shifting to an abnormal position in the neuropile.

Published

2003