Your search keyword '"Etienne Serbe"' showing total 8 results

1. Dynamic signal compression for robust motion vision in flies

Author

Michael S. Drews, Nadezhda Pirogova, Alexander Borst, Lukas Braun, Florian Richter, Anna Schuetzenberger, Etienne Serbe, and Aljoscha Leonhardt

Subjects

0301 basic medicine, Motion Perception, Biology, Convolutional neural network, Signal, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Robustness (computer science), Automatic gain control, Animals, Computer vision, Sensitivity (control systems), Vision, Ocular, Neurons, Artificial neural network, business.industry, Signal compression, Motion detection, 030104 developmental biology, Drosophila melanogaster, Artificial intelligence, Neural Networks, Computer, General Agricultural and Biological Sciences, business, 030217 neurology & neurosurgery

Abstract

Summary Sensory systems need to reliably extract information from highly variable natural signals. Flies, for instance, use optic flow to guide their course and are remarkably adept at estimating image velocity regardless of image statistics. Current circuit models, however, cannot account for this robustness. Here, we demonstrate that the Drosophila visual system reduces input variability by rapidly adjusting its sensitivity to local contrast conditions. We exhaustively map functional properties of neurons in the motion detection circuit and find that local responses are compressed by surround contrast. The compressive signal is fast, integrates spatially, and derives from neural feedback. Training convolutional neural networks on estimating the velocity of natural stimuli shows that this dynamic signal compression can close the performance gap between model and organism. Overall, our work represents a comprehensive mechanistic account of how neural systems attain the robustness to carry out survival-critical tasks in challenging real-world environments.

Published

2020

2. A combinatorial code of transcription factors specifies subtypes of visual motion-sensing neurons in Drosophila

Author

Aicha Haji Ali, Nikolai Hörmann, Jesús Pujol-Martí, Christian Mayer, Tabea Schilling, Alexander Borst, and Etienne Serbe

Subjects

Code (set theory), Sensory Receptor Cells, Motion Perception, Motion vision, Dendrite, medicine, Melanogaster, Animals, Drosophila Proteins, Visual Pathways, Combinatorial code, Axon, Molecular Biology, Transcription factor, Neurons, biology, Neuronal subtypes, Dendrites, biology.organism_classification, Dendrite development, Visual motion, medicine.anatomical_structure, Drosophila, Grain, Axon guidance, Neuroscience, Transcription Factors, Research Article, Developmental Biology

Abstract

Direction-selective T4/T5 neurons exist in four subtypes, each tuned to visual motion along one of the four cardinal directions. Along with their directional tuning, neurons of each T4/T5 subtype orient their dendrites and project their axons in a subtype-specific manner. Directional tuning, thus, appears strictly linked to morphology in T4/T5 neurons. How the four T4/T5 subtypes acquire their distinct morphologies during development remains largely unknown. Here, we investigated when and how the dendrites of the four T4/T5 subtypes acquire their specific orientations, and profiled the transcriptomes of all T4/T5 neurons during this process. This revealed a simple and stable combinatorial code of transcription factors defining the four T4/T5 subtypes during their development. Changing the combination of transcription factors of specific T4/T5 subtypes resulted in predictable and complete conversions of subtype-specific properties, i.e. dendrite orientation and matching axon projection pattern. Therefore, a combinatorial code of transcription factors coordinates the development of dendrite and axon morphologies to generate anatomical specializations that differentiate subtypes of T4/T5 motion-sensing neurons., Summary: Morphological and transcriptomic analyses allowed the identification of a combinatorial code of transcription factors that controls the development of subtype-specific morphologies in motion-detecting neurons of the Drosophila visual system.

Published

2020

3. Asymmetry of Drosophila ON and OFF motion detectors enhances real-world velocity estimation

Author

Matthias Meier, Aljoscha Leonhardt, Etienne Serbe, Georg Ammer, Armin Bahl, and Alexander Borst

Subjects

0301 basic medicine, Brightness, media_common.quotation_subject, Models, Neurological, Motion Perception, Biology, Asymmetry, Motion (physics), 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, Motion estimation, Biological neural network, Animals, Computer Simulation, Visual Pathways, media_common, Communication, business.industry, General Neuroscience, Detector, Motion detection, 030104 developmental biology, Drosophila, Female, Photoreceptor Cells, Invertebrate, business, Biological system, Neuroscience, 030217 neurology & neurosurgery

Abstract

The reliable estimation of motion across varied surroundings represents a survival-critical task for sighted animals. How neural circuits have adapted to the particular demands of natural environments, however, is not well understood. We explored this question in the visual system of Drosophila melanogaster. Here, as in many mammalian retinas, motion is computed in parallel streams for brightness increments (ON) and decrements (OFF). When genetically isolated, ON and OFF pathways proved equally capable of accurately matching walking responses to realistic motion. To our surprise, detailed characterization of their functional tuning properties through in vivo calcium imaging and electrophysiology revealed stark differences in temporal tuning between ON and OFF channels. We trained an in silico motion estimation model on natural scenes and discovered that our optimized detector exhibited differences similar to those of the biological system. Thus, functional ON-OFF asymmetries in fly visual circuitry may reflect ON-OFF asymmetries in natural environments.

Published

2016

4. Comprehensive Characterization of the Major Presynaptic Elements to the Drosophila OFF Motion Detector

Author

Matthias Meier, Aljoscha Leonhardt, Etienne Serbe, and Alexander Borst

Subjects

0301 basic medicine, Brightness, Sensory Receptor Cells, Neuroscience(all), CD8 Antigens, Green Fluorescent Proteins, Motion Perception, Presynaptic Terminals, Action Potentials, Biology, Motion (physics), Animals, Genetically Modified, 03 medical and health sciences, Calcium imaging, Animals, Visual Pathways, Neurons, Motion detector, General Neuroscience, Functional specialization, Motion detection, Expression (mathematics), Characterization (materials science), Microscopy, Electron, 030104 developmental biology, Calcium, Drosophila, Visual Fields, Biological system, Neuroscience, Algorithms

Abstract

Estimating motion is a fundamental task for the visual system of sighted animals. In Drosophila, direction-selective T4 and T5 cells respond to moving brightness increments (ON) and decrements (OFF), respectively. Current algorithmic models of the circuit are based on the interaction of two differentially filtered signals. However, electron microscopy studies have shown that T5 cells receive their major input from four classes of neurons: Tm1, Tm2, Tm4, and Tm9. Using two-photon calcium imaging, we demonstrate that T5 is the first direction-selective stage within the OFF pathway. The four cells provide an array of spatiotemporal filters to T5. Silencing their synaptic output in various combinations, we find that all input elements are involved in OFF motion detection to varying degrees. Our comprehensive survey challenges the simplified view of how neural systems compute the direction of motion and suggests that an intricate interplay of many signals results in direction selectivity.

Published

2016

5. Optogenetic and Pharmacologic Dissection of Feedforward Inhibition inDrosophilaMotion Vision

Author

Etienne Serbe, Alex S. Mauss, Alexander Borst, and Matthias Meier

Subjects

Retina, Null (radio), General Neuroscience, Motion Perception, Neural Inhibition, Articles, Mecamylamine, Optogenetics, Biology, Inhibitory postsynaptic potential, Luminance, Electrophysiology, Feedforward inhibition, medicine.anatomical_structure, Excitatory postsynaptic potential, medicine, Animals, Picrotoxin, Drosophila, Female, Visual Pathways, Neuroscience, Photic Stimulation, Vision, Ocular

Abstract

Visual systems extract directional motion information from spatiotemporal luminance changes on the retina. An algorithmic model, the Reichardt detector, accounts for this by multiplying adjacent inputs after asymmetric temporal filtering. The outputs of two mirror-symmetrical units tuned to opposite directions are thought to be subtracted on the dendrites of wide-field motion-sensitive lobula plate tangential cells by antagonistic transmitter systems. InDrosophila, small-field T4/T5 cells carry visual motion information to the tangential cells that are depolarized during preferred and hyperpolarized during null direction motion. While preferred direction input is likely provided by excitation from T4/T5 terminals, the origin of null direction inhibition is unclear. Probing the connectivity between T4/T5 and tangential cells inDrosophilausing a combination of optogenetics, electrophysiology, and pharmacology, we found a direct excitatory as well as an indirect inhibitory component. This suggests that the null direction response is caused by feedforward inhibition via yet unidentified neurons.

Published

2014

6. A directional tuning map of Drosophila elementary motion detectors

Author

Aljoscha Leonhardt, Dierk F. Reiff, Matthias Meier, Georg Ammer, Juergen Haag, Etienne Serbe, Barry J. Dickson, Gerald M. Rubin, Armin Bahl, Alexander Borst, Tabea Schilling, Aljoscha Nern, Matthew S. Maisak, and Elisabeth Hopp

Subjects

Parallel processing (psychology), Brightness, Multidisciplinary, business.industry, Polarity (physics), media_common.quotation_subject, Detector, Biology, Lobe, Optics, medicine.anatomical_structure, Optical recording, medicine, Contrast (vision), business, Biological system, Cardinal direction, media_common

Abstract

The extraction of directional motion information from changing retinal images is one of the earliest and most important processing steps in any visual system. In the fly optic lobe, two parallel processing streams have been anatomically described, leading from two first-order interneurons, L1 and L2, via T4 and T5 cells onto large, wide-field motion-sensitive interneurons of the lobula plate. Therefore, T4 and T5 cells are thought to have a pivotal role in motion processing; however, owing to their small size, it is difficult to obtain electrical recordings of T4 and T5 cells, leaving their visual response properties largely unknown. We circumvent this problem by means of optical recording from these cells in Drosophila, using the genetically encoded calcium indicator GCaMP5 (ref. 2). Here we find that specific subpopulations of T4 and T5 cells are directionally tuned to one of the four cardinal directions; that is, front-to-back, back-to-front, upwards and downwards. Depending on their preferred direction, T4 and T5 cells terminate in specific sublayers of the lobula plate. T4 and T5 functionally segregate with respect to contrast polarity: whereas T4 cells selectively respond to moving brightness increments (ON edges), T5 cells only respond to moving brightness decrements (OFF edges). When the output from T4 or T5 cells is blocked, the responses of postsynaptic lobula plate neurons to moving ON (T4 block) or OFF edges (T5 block) are selectively compromised. The same effects are seen in turning responses of tethered walking flies. Thus, starting with L1 and L2, the visual input is split into separate ON and OFF pathways, and motion along all four cardinal directions is computed separately within each pathway. The output of these eight different motion detectors is then sorted such that ON (T4) and OFF (T5) motion detectors with the same directional tuning converge in the same layer of the lobula plate, jointly providing the input to downstream circuits and motion-driven behaviours.

Published

2013

7. Neural circuit components of the Drosophila OFF motion vision pathway

Author

Etienne Serbe, Matthew S. Maisak, Juergen Haag, Matthias Meier, Alexander Borst, and Barry J. Dickson

Subjects

Neurons, Cell type, biology, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Detector, Motion Perception, Motion vision, Anatomy, Visual system, biology.organism_classification, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Visual motion, Drosophila melanogaster, Melanogaster, Directionality, Animals, Calcium, Visual Pathways, Motion perception, General Agricultural and Biological Sciences, Neuroscience

Abstract

Summary Background Detecting the direction of visual motion is an essential task of the early visual system. The Reichardt detector has been proven to be a faithful description of the underlying computation in insects. A series of recent studies addressed the neural implementation of the Reichardt detector in Drosophila revealing the overall layout in parallel ON and OFF channels, its input neurons from the lamina (L1→ON, and L2→OFF), and the respective output neurons to the lobula plate (ON→T4, and OFF→T5). While anatomical studies showed that T4 cells receive input from L1 via Mi1 and Tm3 cells, the neurons connecting L2 to T5 cells have not been identified so far. It is, however, known that L2 contacts, among others, two neurons, called Tm2 and L4, which show a pronounced directionality in their wiring. Results We characterized the visual response properties of both Tm2 and L4 neurons via Ca 2+ imaging. We found that Tm2 and L4 cells respond with an increase in activity to moving OFF edges in a direction-unselective manner. To investigate their participation in motion vision, we blocked their output while recording from downstream tangential cells in the lobula plate. Silencing of Tm2 and L4 completely abolishes the response to moving OFF edges. Conclusions Our results demonstrate that both cell types are essential components of the Drosophila OFF motion vision pathway, prior to the computation of directionality in the dendrites of T5 cells.

Published

2013

8. Neural Mechanisms for Drosophila Contrast Vision

Author

Matthias Meier, Alexander Borst, Armin Bahl, Georg Ammer, and Etienne Serbe

Subjects

General Neuroscience, media_common.quotation_subject, Neuroscience(all), Functional specialization, Illusion, Motion detection, Biology, Visual system, Visual processing, Animals, Genetically Modified, Contrast Sensitivity, Lateral inhibition, Psychophysics, Contrast (vision), Animals, Drosophila, Female, Visual Pathways, Neuroscience, Photic Stimulation, media_common

Abstract

SummarySpatial contrast, the difference in adjacent luminance values, provides information about objects, textures, and motion and supports diverse visual behaviors. Contrast computation is therefore an essential element of visual processing. The underlying mechanisms, however, are poorly understood. In human psychophysics, contrast illusions are means to explore such computations, but humans offer limited experimental access. Via behavioral experiments in Drosophila, we find that flies are also susceptible to contrast illusions. Using genetic silencing techniques, electrophysiology, and modeling, we systematically dissect the mechanisms and neuronal correlates underlying the behavior. Our results indicate that spatial contrast computation involves lateral inhibition within the same pathway that computes motion of luminance increments (ON pathway). Yet motion-blind flies, in which we silenced downstream motion-sensitive neurons needed for optomotor behavior, have fully intact contrast responses. In conclusion, spatial contrast and motion cues are first computed by overlapping neuronal circuits which subsequently feed into parallel visual processing streams.