Your search keyword '"Michael H. Dickinson"' showing total 167 results

1. Imaging neural activity in the ventral nerve cord of behaving adult Drosophila

Author

Chin-Lin Chen, Laura Hermans, Meera C. Viswanathan, Denis Fortun, Florian Aymanns, Michael Unser, Anthony Cammarato, Michael H. Dickinson, and Pavan Ramdya

Subjects

Science

Abstract

The Drosophila ventral nerve cord (VNC) is functionally equivalent to the vertebrate spinal cord. This study reports a 2-photon imaging approach for recording neural activity in the VNC of walking and grooming adult flies.

Published

2018

2. Visual Sensory Signals Dominate Tactile Cues during Docked Feeding in Hummingbirds

Author

Benjamin Goller, Paolo S. Segre, Kevin M. Middleton, Michael H. Dickinson, and Douglas L. Altshuler

Subjects

flight control, visual control, sensorimotor integration, tactile perception, Anna's hummingbird, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Animals living in and interacting with natural environments must monitor and respond to changing conditions and unpredictable situations. Using information from multiple sensory systems allows them to modify their behavior in response to their dynamic environment but also creates the challenge of integrating different, and potentially contradictory, sources of information for behavior control. Understanding how multiple information streams are integrated to produce flexible and reliable behavior is key to understanding how behavior is controlled in natural settings. Natural settings are rarely still, which challenges animals that require precise body position control, like hummingbirds, which hover while feeding from flowers. Tactile feedback, available only once the hummingbird is docked at the flower, could provide additional information to help maintain its position at the flower. To investigate the role of tactile information for hovering control during feeding, we first asked whether hummingbirds physically interact with a feeder once docked. We quantified physical interactions between docked hummingbirds and a feeder placed in front of a stationary background pattern. Force sensors on the feeder measured a complex time course of loading that reflects the wingbeat frequency and bill movement of feeding hummingbirds, and suggests that they sometimes push against the feeder with their bill. Next, we asked whether the measured tactile interactions were used by feeding hummingbirds to maintain position relative to the feeder. We created two experimental scenarios—one in which the feeder was stationary and the visual background moved and the other where the feeder moved laterally in front of a white background. When the visual background pattern moved, docked hummingbirds pushed significantly harder in the direction of horizontal visual motion. When the feeder moved, and the background was stationary, hummingbirds generated aerodynamic force in the opposite direction of the feeder motion. These results suggest that docked hummingbirds are using visual information about the environment to maintain body position and orientation, and not actively tracking the motion of the feeder. The absence of flower tracking behavior in hummingbirds contrasts with the behavior of hawkmoths, and provides evidence that they rely primarily on the visual background rather than flower-based cues while feeding.

Published

2017

3. Flow Structure and Force Generation on Flapping Wings at Low Reynolds Numbers Relevant to the Flight of Tiny Insects

Author

Arvind Santhanakrishnan, Shannon K. Jones, William B. Dickson, Martin Peek, Vishwa T. Kasoju, Michael H. Dickinson, and Laura A. Miller

Subjects

insect flight, aerodynamics, low Reynolds number, flow visualization, immersed boundary method, Thermodynamics, QC310.15-319, Descriptive and experimental mechanics, QC120-168.85

Abstract

In contrast to larger species, little is known about the flight of the smallest flying insects, such as thrips and fairyflies. These tiny animals range from 300 to 1000 microns in length and fly at Reynolds numbers ranging from about 4 to 60. Previous work with numerical and physical models have shown that the aerodynamics of these diminutive insects is significantly different from that of larger animals, but most of these studies have relied on two-dimensional approximations. There can, however, be significant differences between two- and three-dimensional flows, as has been found for larger insects. To better understand the flight of the smallest insects, we have performed a systematic study of the forces and flow structures around a three-dimensional revolving elliptical wing. We used both a dynamically scaled physical model and a three-dimensional computational model at Reynolds numbers ranging from 1 to 130 and angles of attacks ranging from 0° to 90°. The results of the physical and computational models were in good agreement and showed that dimensionless drag, aerodynamic efficiency, and spanwise flow all decrease with decreasing Reynolds number. In addition, both the leading and trailing edge vortices remain attached to the wing over the scales relevant to the smallest flying insects. Overall, these observations suggest that there are drastic differences in the aerodynamics of flight at the scale of the smallest flying animals.

Published

2018

4. Synaptic architecture of leg and wing motor control networks in Drosophila

Author

Ellen Lesser, Anthony W. Azevedo, Jasper S. Phelps, Leila Elabbady, Andrew P. Cook, Brandon Mark, Sumiya Kuroda, Anne Sustar, Anthony J. Moussa, Chris J. Dallmann, Sweta Agrawal, Su-Yee J. Lee, Brandon G. Pratt, Kyobi Skutt-Kakari, Stephan Gerhard, Ran Lu, Nico Kemnitz, Kisuk Lee, Akhilesh Halageri, Manuel Castro, Dodam Ih, Jay Gager, Marwan Tammam, Sven Dorkenwald, Forrest C. Collman, Casey M Schneider-Mizell, Derrick Brittain, Chris S Jordan, H Sebastian Seung, Thomas Macrina, Michael H Dickinson, Wei-Chung Allen Lee, and John C. Tuthill

Subjects

Article

Abstract

Animal movement is controlled by motor neurons (MNs), which project out of the central nervous system to activate muscles. Because individual muscles may be used in many different behaviors, MN activity must be flexibly coordinated by dedicated premotor circuitry, the organization of which remains largely unknown. Here, we use comprehensive reconstruction of neuron anatomy and synaptic connectivity from volumetric electron microscopy (i.e., connectomics) to analyze the wiring logic of motor circuits controlling theDrosophilaleg and wing. We find that both leg and wing premotor networks are organized into modules that link MNs innervating muscles with related functions. However, the connectivity patterns within leg and wing motor modules are distinct. Leg premotor neurons exhibit proportional gradients of synaptic input onto MNs within each module, revealing a novel circuit basis for hierarchical MN recruitment. In comparison, wing premotor neurons lack proportional synaptic connectivity, which may allow muscles to be recruited in different combinations or with different relative timing. By comparing the architecture of distinct limb motor control systems within the same animal, we identify common principles of premotor network organization and specializations that reflect the unique biomechanical constraints and evolutionary origins of leg and wing motor control.

Published

2023

5. The functional organization of descending sensory-motor pathways in Drosophila

Author

Shigehiro Namiki, Michael H Dickinson, Allan M Wong, Wyatt Korff, and Gwyneth M Card

Subjects

descending neuron, sensory-motor, anatomy, split-GAL4, ventral nerve cord, brain, Medicine, Science, Biology (General), QH301-705.5

Abstract

In most animals, the brain controls the body via a set of descending neurons (DNs) that traverse the neck. DN activity activates, maintains or modulates locomotion and other behaviors. Individual DNs have been well-studied in species from insects to primates, but little is known about overall connectivity patterns across the DN population. We systematically investigated DN anatomy in Drosophila melanogaster and created over 100 transgenic lines targeting individual cell types. We identified roughly half of all Drosophila DNs and comprehensively map connectivity between sensory and motor neuropils in the brain and nerve cord, respectively. We find the nerve cord is a layered system of neuropils reflecting the fly’s capability for two largely independent means of locomotion -- walking and flight -- using distinct sets of appendages. Our results reveal the basic functional map of descending pathways in flies and provide tools for systematic interrogation of neural circuits.

Published

2018

6. Transforming representations of movement from body- to world-centric space

Author

Jenny Lu, Amir H. Behbahani, Lydia Hamburg, Elena A. Westeinde, Paul M. Dawson, Cheng Lyu, Gaby Maimon, Michael H. Dickinson, Shaul Druckmann, and Rachel I. Wilson

Subjects

Multidisciplinary

Abstract

When an animal moves through the world, its brain receives a stream of information about the body’s translational velocity from motor commands and sensory feedback signals. These incoming signals are referenced to the body, but ultimately, they must be transformed into world-centric coordinates for navigation. Here we show that this computation occurs in the fan-shaped body in the brain of Drosophila melanogaster. We identify two cell types, PFNd and PFNv, that conjunctively encode translational velocity and heading as a fly walks. In these cells, velocity signals are acquired from locomotor brain regions and are multiplied with heading signals from the compass system. PFNd neurons prefer forward–ipsilateral movement, whereas PFNv neurons prefer backward–contralateral movement, and perturbing PFNd neurons disrupts idiothetic path integration in walking flies. Downstream, PFNd and PFNv neurons converge onto hΔB neurons, with a connectivity pattern that pools together heading and translation direction combinations corresponding to the same movement in world-centric space. This network motif effectively performs a rotation of the brain’s representation of body-centric translational velocity according to the current heading direction. Consistent with our predictions, we observe that hΔB neurons form a representation of translational velocity in world-centric coordinates. By integrating this representation over time, it should be possible for the brain to form a working memory of the path travelled through the environment.

Published

2021

7. Neuromuscular embodiment of feedback control elements in Drosophila flight

Author

Samuel C. Whitehead, Sofia Leone, Theodore Lindsay, Matthew R. Meiselman, Noah J. Cowan, Michael H. Dickinson, Nilay Yapici, David L. Stern, Troy Shirangi, and Itai Cohen

Subjects

Multidisciplinary

Abstract

While insects such as Drosophila are flying, aerodynamic instabilities require that they make millisecond time scale adjustments to their wing motion to stay aloft and on course. These stabilization reflexes can be modeled as a proportional-integral (PI) controller; however, it is unclear how such control might be instantiated in insects at the level of muscles and neurons. Here, we show that the b1 and b2 motor units—prominent components of the fly’s steering muscle system—modulate specific elements of the PI controller: the angular displacement (integral) and angular velocity (proportional), respectively. Moreover, these effects are observed only during the stabilization of pitch. Our results provide evidence for an organizational principle in which each muscle contributes to a specific functional role in flight control, a finding that highlights the power of using top-down behavioral modeling to guide bottom-up cellular manipulation studies.

Published

2022

8. Drosophila re-zero their path integrator at the center of a fictive food patch

Author

Michael H. Dickinson, Emily H. Palmer, Amir H. Behbahani, and Román A. Corfas

Subjects

biology, business.industry, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, Odometry, Food, Salient, Integrator, Compass, Path (graph theory), Path integration, Animals, Drosophila, Computer vision, Artificial intelligence, General Agricultural and Biological Sciences, business, Communication channel

Abstract

Summary The ability to keep track of one’s location in space is a critical behavior for animals navigating to and from a salient location, and its computational basis is now beginning to be unraveled. Here, we tracked flies in a ring-shaped channel as they executed bouts of search triggered by optogenetic activation of sugar receptors. Unlike experiments in open field arenas, which produce highly tortuous search trajectories, our geometrically constrained paradigm enabled us to monitor flies’ decisions to move toward or away from the fictive food. Our results suggest that flies use path integration to remember the location of a food site even after it has disappeared, and flies can remember the location of a former food site even after walking around the arena one or more times. To determine the behavioral algorithms underlying Drosophila search, we developed multiple state transition models and found that flies likely accomplish path integration by combining odometry and compass navigation to keep track of their position relative to the fictive food. Our results indicate that whereas flies re-zero their path integrator at food when only one feeding site is present, they adjust their path integrator to a central location between sites when experiencing food at two or more locations. Together, this work provides a simple experimental paradigm and theoretical framework to advance investigations of the neural basis of path integration.

Published

2021

9. Burst muscle performance predicts the speed, acceleration, and turning performance of Anna’s hummingbirds

Author

Paolo S Segre, Roslyn Dakin, Victor B Zordan, Michael H Dickinson, Andrew D Straw, and Douglas L Altshuler

Subjects

biomechanic, flight, hummingbirds, maneuverability, muscle capacity, wing morphology, Medicine, Science, Biology (General), QH301-705.5

Abstract

Despite recent advances in the study of animal flight, the biomechanical determinants of maneuverability are poorly understood. It is thought that maneuverability may be influenced by intrinsic body mass and wing morphology, and by physiological muscle capacity, but this hypothesis has not yet been evaluated because it requires tracking a large number of free flight maneuvers from known individuals. We used an automated tracking system to record flight sequences from 20 Anna's hummingbirds flying solo and in competition in a large chamber. We found that burst muscle capacity predicted most performance metrics. Hummingbirds with higher burst capacity flew with faster velocities, accelerations, and rotations, and they used more demanding complex turns. In contrast, body mass did not predict variation in maneuvering performance, and wing morphology predicted only the use of arcing turns and high centripetal accelerations. Collectively, our results indicate that burst muscle capacity is a key predictor of maneuverability.

Published

2015

10. A population of descending neurons that regulate the flight motor of Drosophila

Author

William J Rowell, Wyatt Korff, Carmen Morrow, Michael H. Dickinson, Shigehiro Namiki, Ivo G. Ros, and Gwyneth M Card

Subjects

education.field_of_study, Wing, Population, Kinematics, Biology, medicine.anatomical_structure, Ventral nerve cord, Wide dynamic range, Trajectory, Neuropil, medicine, Flapping, education, Neuroscience

Abstract

SummaryLike many insect species, Drosophila melanogaster are capable of maintaining a stable flight trajectory for periods lasting up to several hours(1, 2). Because aerodynamic torque is roughly proportional to the fifth power of wing length(3), even small asymmetries in wing size require the maintenance of subtle bilateral differences in flapping motion to maintain a stable path. Flies can even fly straight after losing half of a wing, a feat they accomplish via very large, sustained kinematic changes to the both damaged and intact wings(4). Thus, the neural network responsible for stable flight must be capable of sustaining fine-scaled control over wing motion across a large dynamic range. In this paper, we describe an unusual type of descending neurons (DNg02) that project directly from visual output regions of the brain to the dorsal flight neuropil of the ventral nerve cord. Unlike most descending neurons, which exist as single bilateral pairs with unique morphology, there is a population of at least 15 DNg02 cell pairs with nearly identical shape. By optogenetically activating different numbers of DNg02 cells, we demonstrate that these neurons regulate wingbeat amplitude over a wide dynamic range via a population code. Using 2-photon functional imaging, we show that DNg02 cells are responsive to visual motion during flight in a manner that would make them well suited to continuously regulate bilateral changes in wing kinematics. Collectively, we have identified a critical set of DNs that provide the sensitivity and dynamic range required for flight control.

Published

2021

11. The long-distance flight behavior of Drosophila supports an agent-based model for wind-assisted dispersal in insects

Author

Francesca V Ponce, Floris van Breugel, Katherine J. Leitch, Michael H. Dickinson, and William B. Dickson

Subjects

Agent-based model, Release site, Multidisciplinary, biology, Ground speed, Critical question, Genetic model, Environmental science, Biological dispersal, Body orientation, Atmospheric sciences, biology.organism_classification, Drosophila

Abstract

Despite the ecological importance of long-distance dispersal in insects, its mechanistic basis is poorly understood in genetic model species, in which advanced molecular tools are readily available. One critical question is how insects interact with the wind to detect attractive odor plumes and increase their travel distance as they disperse. To gain insight into dispersal, we conducted release-and-recapture experiments in the Mojave Desert using the fruit fly, Drosophila melanogaster. We deployed chemically baited traps in a 1 km radius ring around the release site, equipped with cameras that captured the arrival times of flies as they landed. In each experiment, we released between 30,000 and 200,000 flies. By repeating the experiments under a variety of conditions, we were able to quantify the influence of wind on flies’ dispersal behavior. Our results confirm that even tiny fruit flies could disperse ∼12 km in a single flight in still air and might travel many times that distance in a moderate wind. The dispersal behavior of the flies is well explained by an agent-based model in which animals maintain a fixed body orientation relative to celestial cues, actively regulate groundspeed along their body axis, and allow the wind to advect them sideways. The model accounts for the observation that flies actively fan out in all directions in still air but are increasingly advected downwind as winds intensify. Our results suggest that dispersing insects may strike a balance between the need to cover large distances while still maintaining the chance of intercepting odor plumes from upwind sources.

Published

2021

12. The long-distance flight behavior of

Author

Katherine J, Leitch, Francesca V, Ponce, William B, Dickson, Floris, van Breugel, and Michael H, Dickinson

Subjects

Drosophila melanogaster, Flight, Animal, Odorants, Animals, Wind, Cues, Biological Sciences, Animal Distribution

Abstract

Despite the ecological importance of long-distance dispersal in insects, its mechanistic basis is poorly understood in genetic model species, in which advanced molecular tools are readily available. One critical question is how insects interact with the wind to detect attractive odor plumes and increase their travel distance as they disperse. To gain insight into dispersal, we conducted release-and-recapture experiments in the Mojave Desert using the fruit fly, Drosophila melanogaster. We deployed chemically baited traps in a 1 km radius ring around the release site, equipped with cameras that captured the arrival times of flies as they landed. In each experiment, we released between 30,000 and 200,000 flies. By repeating the experiments under a variety of conditions, we were able to quantify the influence of wind on flies’ dispersal behavior. Our results confirm that even tiny fruit flies could disperse ∼12 km in a single flight in still air and might travel many times that distance in a moderate wind. The dispersal behavior of the flies is well explained by an agent-based model in which animals maintain a fixed body orientation relative to celestial cues, actively regulate groundspeed along their body axis, and allow the wind to advect them sideways. The model accounts for the observation that flies actively fan out in all directions in still air but are increasingly advected downwind as winds intensify. Our results suggest that dispersing insects may strike a balance between the need to cover large distances while still maintaining the chance of intercepting odor plumes from upwind sources.

Published

2021

13. Drosophila re-zero their path integrator at the center of a fictive food patch

Author

Román A. Corfas, Emily H. Palmer, Michael H. Dickinson, and Amir H. Behbahani

Subjects

biology, Computer science, business.industry, biology.organism_classification, Odometry, Salient, Compass, Integrator, Path (graph theory), Path integration, Computer vision, Artificial intelligence, business, Drosophila, Communication channel

Abstract

SUMMARYThe ability to keep track of one’s location in space is a critical behavior for animals navigating to and from a salient location, and its computational basis is now beginning to be unraveled. Here, we tracked flies in a ring-shaped channel as they executed bouts of search triggered by optogenetic activation of sugar receptors. Unlike experiments in open field arenas, which produce highly tortuous search trajectories, our geometrically constrained paradigm enabled us to monitor flies’ decisions to move toward or away from the fictive food. Our results suggest that flies use path integration to remember the location of a food site even after it has disappeared, and that flies can remember the location of a former food site even after walking around the arena one or more times. To determine the behavioral algorithms underlying Drosophila search, we developed multiple state transition models and found that flies likely accomplish path integration by combining odometry and compass navigation to keep track of their position relative to the fictive food. Our results indicate that whereas flies re-zero their path integrator at food when only one feeding site is present, they adjust their path integrator to a central location between sites when experiencing food at two or more locations. Together, this work provides a simple experimental paradigm and theoretical framework to advance investigations of the neural basis of path integration.

Published

2021

14. A Systematic Nomenclature for the Drosophila Ventral Nerve Cord

Author

Richard S. Mann, James W. Truman, Robert Court, Darren W. Williams, Wyatt Korff, John C. Tuthill, Michael H. Dickinson, David J. Merritt, Julie H. Simpson, Troy R. Shirangi, Jana Börner, Marta Costa, Gwyneth M Card, Shigehiro Namiki, David Shepherd, Andrew M. Seeds, Rod K. Murphey, J. Douglas Armstrong, and Carsten Duch

Subjects

0301 basic medicine, Nervous system, anatomy, tectulum, animal structures, 1.1 Normal biological development and functioning, neuropil, Sensory system, hemilineage, Article, 03 medical and health sciences, 0302 clinical medicine, Terminology as Topic, medicine, Neuropil, Psychology, Animals, Cell Lineage, Invertebrate, ontology, Nomenclature, Neurons, Neurology & Neurosurgery, biology, General Neuroscience, fungi, Neurosciences, Commissure, motorneuron, biology.organism_classification, Neuromere, tract, Ganglia, Invertebrate, 030104 developmental biology, medicine.anatomical_structure, Drosophila melanogaster, Ventral nerve cord, Neurological, Ganglia, commissure, insect, Cognitive Sciences, Nerve Net, Neuroscience, 030217 neurology & neurosurgery, neuromere

Abstract

Drosophila melanogaster is an established model for neuroscience research with relevance in biology and medicine. Until recently, research on the Drosophila brain was hindered by the lack of a complete and uniform nomenclature. Recognizing this, Ito et al. (2014) produced an authoritative nomenclature for the adult insect brain, using Drosophila as the reference. Here, we extend this nomenclature to the adult thoracic and abdominal neuromeres, the ventral nerve cord (VNC), to provide an anatomical description of this major component of the Drosophila nervous system. The VNC is the locus for the reception and integration of sensory information and involved in generating most of the locomotor actions that underlie fly behaviors. The aim is to create a nomenclature, definitions, and spatial boundaries for the Drosophila VNC that are consistent with other insects. The work establishes an anatomical framework that provides a powerful tool for analyzing the functional organization of the VNC.

Published

2020

15. Genome editing in non-model organisms opens new horizons for comparative physiology

Author

Julian A. T. Dow, Michael H. Dickinson, and Leslie B. Vosshall

Subjects

0106 biological sciences, New horizons, Physiology, 030310 physiology, ved/biology.organism_classification_rank.species, Extinct species, Aquatic Science, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Broad spectrum, Genome editing, CRISPR, Model organism, Physiology, Comparative, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Gene Editing, 0303 health sciences, ved/biology, Comparative physiology, Evolutionary biology, Insect Science, Animal Science and Zoology, CRISPR-Cas Systems

Abstract

For almost 100 years, biologists have made fundamental discoveries using a handful of model organisms that are not representative of the rich diversity found in nature. The advent of CRISPR genome editing now opens up a wide range of new organisms to mechanistic investigation. This increases not only the taxonomic breadth of current research but also the scope of biological problems that are now amenable to study, such as population control of invasive species, management of disease vectors such as mosquitoes, the creation of chimeric animal hosts to grow human organs and even the possibility of resurrecting extinct species such as passenger pigeons and mammoths. Beyond these practical applications, work on non-model organisms enriches our basic understanding of the natural world. This special issue addresses a broad spectrum of biological problems in non-model organisms and highlights the utility of genome editing across levels of complexity from development and physiology to behaviour and evolution.

Published

2020

16. A Systematic Nomenclature for the Drosophila Ventral Nervous System

Author

Richard S. Mann, Marta Costa, Wyatt Korff, Gwyneth M Card, Jana Börner, Robert Court, James W. Truman, Troy R. Shirangi, Andrew M. Seeds, David J. Merritt, John C. Tuthill, Douglas Armstrong, Rod K. Murphey, David Shepherd, Michael H. Dickinson, Julie H. Simpson, Darren William Williams, Carsten Duch, and Shigehiro Namiki

Subjects

Nervous system, Connectomics, biology, fungi, Neuromere, biology.organism_classification, medicine.anatomical_structure, Taxon, medicine, Neuropil, Nomenclature, Drosophila, Neuroscience, Neuroanatomy

Abstract

The fruit fly, Drosophila melanogaster, is an established and powerful model system for neuroscience research with wide relevance in biology and medicine. Until recently, research on the Drosophila brain was hindered by the lack of a complete and uniform nomenclature. Recognising this problem, the Insect Brain Name Working Group produced an authoritative hierarchical nomenclature system for the adult insect brain, using Drosophila melanogaster as the reference framework, with other taxa considered to ensure greater consistency and expandability (Ito et al., 2014). Here, we extend this nomenclature system to the sub-gnathal regions of the adult Drosophila nervous system, thus providing a systematic anatomical description of the ventral nervous system (VNS). This portion of the nervous system includes the thoracic and abdominal neuromeres that were not included in the original work and contains the motor circuits that play essential roles in most fly behaviours.

Published

2020

17. Distinct activity-gated pathways mediate attraction and aversion to CO2 in Drosophila

Author

Ainul Huda, Michael H. Dickinson, and Floris van Breugel

Subjects

0301 basic medicine, Multidisciplinary, biology, Foraging, biology.organism_classification, Attraction, Yeast, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Evolutionary biology, Ethanol metabolism, Adaptation, Drosophila melanogaster, Drosophila, 030217 neurology & neurosurgery, Ionotropic effect

Abstract

Carbon dioxide is produced by many organic processes and is a convenient volatile cue for insects1 that are searching for blood hosts2, flowers3, communal nests4, fruit5 and wildfires6. Although Drosophila melanogaster feed on yeast that produce CO2 and ethanol during fermentation, laboratory experiments7-12 suggest that walking flies avoid CO2. Here we resolve this paradox by showing that both flying and walking Drosophila find CO2 attractive, but only when they are in an active state associated with foraging. Their aversion to CO2 at low-activity levels may be an adaptation to avoid parasites that seek CO2, or to avoid succumbing to respiratory acidosis in the presence of high concentrations of CO2 that exist in nature13,14. In contrast to CO2, flies are attracted to ethanol in all behavioural states, and invest twice the time searching near ethanol compared to CO2. These behavioural differences reflect the fact that ethanol is a unique signature of yeast fermentation, whereas CO2 is generated by many natural processes. Using genetic tools, we determined that the evolutionarily conserved ionotropic co-receptor IR25a is required for CO2 attraction, and that the receptors necessary for CO2 avoidance are not involved in this attraction. Our study lays the foundation for future research to determine the neural circuits that underlie both state- and odorant-dependent decision-making in Drosophila.

Published

2018

18. A Descending Neuron Correlated with the Rapid Steering Maneuvers of Flying Drosophila

Author

Ivo G. Ros, Michael H. Dickinson, and Bettina Schnell

Subjects

0301 basic medicine, Motion Perception, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Motion (physics), 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, medicine, Animals, Nervous System Physiological Phenomena, Sensory cue, Cells, Cultured, Neurons, Behavior, Animal, fungi, Work (physics), Efference copy, Electrophysiology, Drosophila melanogaster, 030104 developmental biology, medicine.anatomical_structure, Flight, Animal, Visual Perception, Reflex, Neuron, General Agricultural and Biological Sciences, Neuroscience, 030217 neurology & neurosurgery

Abstract

To navigate through the world, animals must stabilize their path against disturbances and change direction to avoid obstacles and to search for resources [1 ; 2]. Locomotion is thus guided by sensory cues but also depends on intrinsic processes, such as motivation and physiological state. Flies, for example, turn with the direction of large-field rotatory motion, an optomotor reflex that is thought to help them fly straight [3; 4 ; 5]. Occasionally, however, they execute fast turns, called body saccades, either spontaneously or in response to patterns of visual motion such as expansion [6; 7 ; 8]. These turns can be measured in tethered flying Drosophila [ 3; 4 ; 9], which facilitates the study of underlying neural mechanisms. Whereas there is evidence for an efference copy input to visual interneurons during saccades [10], the circuits that control spontaneous and visually elicited saccades are not well known. Using two-photon calcium imaging and electrophysiological recordings in tethered flying Drosophila, we have identified a descending neuron whose activity is correlated with both spontaneous and visually elicited turns during tethered flight. The cell’s activity in open- and closed-loop experiments suggests that it does not underlie slower compensatory responses to horizontal motion but rather controls rapid changes in flight path. The activity of this neuron can explain some of the behavioral variability observed in response to visual motion and appears sufficient for eliciting turns when artificially activated. This work provides an entry point into studying the circuits underlying the control of rapid steering maneuvers in the fly brain.

Published

2017

19. The effects of target contrast on Drosophila courtship

Author

Michael H. Dickinson and Sweta Agrawal

Subjects

0106 biological sciences, 0303 health sciences, Communication, Courtship display, genetic structures, Physiology, business.industry, 030310 physiology, media_common.quotation_subject, Aquatic Science, Biology, 010603 evolutionary biology, 01 natural sciences, Attraction, Courtship, 03 medical and health sciences, Colored, Insect Science, Animal Science and Zoology, business, Molecular Biology, Sensory cue, Gray (horse), Ecology, Evolution, Behavior and Systematics, media_common

Abstract

Many animals use visual cues like object shape, color, and motion to detect and pursue conspecific mates. Contrast is another possibly informative visual cue, but has not been studied in great detail. In this study, we presented male Drosophila melanogaster with small, fly-sized, moving objects painted either black, white, or grey to test if they use contrast cues to identify mates. We found that males frequently chased grey objects and rarely chased white or black objects. Although males started chasing black objects as often as grey objects, the resulting chases were much shorter. To test whether the attraction to grey objects was mediated via contrast, we fabricated black and grey behavioral chambers. However, wildtype males almost never chased any objects in these darkly colored chambers. To circumvent this limitation, we increased baseline levels of chasing by thermogenetically activating P1 neurons to promote courtship. Males with thermogenetically activated P1 neurons maintained a similar preference for grey objects despite elevated levels of courtship behavior. When placed in a black chamber, males with activated P1 neurons switched their preference and chased black objects more than grey objects. We also tested whether males use contrast cues to orient to particular parts of the female's body during courtship. When presented with moving objects painted two colors, males positioned themselves next to the grey half regardless of whether the other half was painted black or white. These results suggest that males can use contrast to recognize potential mates and to position themselves during courtship.

Published

2019

20. Visual-Olfactory Integration in the Human Disease Vector Mosquito Aedes aegypti

Author

Adrienne L. Fairhall, Clément Vinauger, Omar S. Akbari, Floris van Breugel, Lauren T. Locke, Kennedy K.S. Tobin, Michael H. Dickinson, and Jeffrey A. Riffell

Subjects

0301 basic medicine, Visual perception, genetic structures, Medical and Health Sciences, visual arena, 0302 clinical medicine, Aedes aegypti, Aedes, Visual Objects, Contrast (vision), computer.programming_language, media_common, 0303 health sciences, biology, Biological Sciences, 3. Good health, Smell, medicine.anatomical_structure, Infectious Diseases, sensory integration, Female, Cues, General Agricultural and Biological Sciences, olfaction, vision, media_common.quotation_subject, 1.1 Normal biological development and functioning, Sensory system, Olfaction, Mosquito Vectors, Stimulus (physiology), Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Underpinning research, Ocular, Neuropil, medicine, Animals, Sensory cue, Vision, Ocular, 030304 developmental biology, mosquitoes, Psychology and Cognitive Sciences, Neurosciences, biology.organism_classification, Lobe, Olfactory stimulus, Vector-Borne Diseases, 030104 developmental biology, Antennal lobe, computer, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

SummaryMosquitoes rely on the integration of multiple sensory cues, including olfactory, visual, and thermal stimuli, to detect, identify and locate their hosts [1–4]. Although we increasingly know more about the role of chemosensory behaviours in mediating mosquito-host interactions [1], the role of visual cues remains comparatively less studied [3], and how the combination of olfactory and visual information is integrated in the mosquito brain remains unknown. In the present study, we used a tethered-flight LED arena, which allowed for quantitative control over the stimuli, to show that CO2exposure affects target-tracking responses, but not responses to large-field visual stimuli. In addition, we show that CO2modulates behavioural responses to visual objects in a time-dependent manner. To gain insight into the neural basis of this olfactory and visual coupling, we conducted two-photon microscopy experiments in a new GCaMP6s-expressing mosquito line. Imaging revealed that the majority of ROIs in the lobula region of the optic lobe exhibited strong responses to small-field stimuli, but showed little response to a large-field stimulus. Approximately 20% of the neurons we imaged were modulated when an attractive odour preceded the visual stimulus; these same neurons also elicited a small response when the odour was presented alone. By contrast, imaging in the antennal lobe revealed no modulation when visual stimuli were presented before or after the olfactory stimulus. Together, our results are the first to reveal the dynamics of olfactory modulation in visually evoked behaviours of mosquitoes, and suggest that coupling between these sensory systems is asymmetrical and time-dependent.

Published

2019

21. Diverse food-sensing neurons trigger idiothetic local search in Drosophila

Author

Tarun Sharma, Michael H. Dickinson, and Román A. Corfas

Subjects

0301 basic medicine, Future studies, Sensory Receptor Cells, Foraging, Sensory system, Optogenetics, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Path integration, Animals, Local search (optimization), Drosophila, biology, business.industry, fungi, biology.organism_classification, 030104 developmental biology, Drosophila melanogaster, Food, Exploratory Behavior, Idiothetic, Female, Cues, General Agricultural and Biological Sciences, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Foraging animals may benefit from remembering the location of a newly discovered food patch while continuing to explore nearby [1, 2]. For example, after encountering a drop of yeast or sugar, hungry flies often perform a local search [3, 4]. That is, rather than remaining on the food or simply walking away, flies execute a series of exploratory excursions during which they repeatedly depart and return to the resource. Fruit flies, Drosophila melanogaster, can perform this food-centered search behavior in the absence of external landmarks, instead relying on internal (idiothetic) cues [5]. This path-integration behavior may represent a deeply conserved navigational capacity in insects [6, 7], but its underlying neural basis remains unknown. Here, we used optogenetic activation to screen candidate cell classes and found that local searches can be initiated by diverse sensory neurons. Optogenetically induced searches resemble those triggered by actual food, are modulated by starvation state, and exhibit key features of path integration. Flies perform tightly centered searches around the fictive food site, even within a constrained maze, and they can return to the fictive food site after long excursions. Together, these results suggest that flies enact local searches in response to a wide variety of food-associated cues and that these sensory pathways may converge upon a common neural system for navigation. Using a virtual reality system, we demonstrate that local searches can be optogenetically induced in tethered flies walking on a spherical treadmill, laying the groundwork for future studies to image the brain during path integration. VIDEO ABSTRACT.

Published

2019

22. The effects of target contrast on

Author

Sweta, Agrawal and Michael H, Dickinson

Subjects

Male, Neurons, Drosophila melanogaster, Courtship, Visual Perception, Animals, Cues, Vision, Ocular

Abstract

Many animals use visual cues such as object shape, color and motion to detect and pursue conspecific mates. Contrast is another possibly informative visual cue, but has not been studied in great detail. In this study, we presented male

Published

2019

23. Celestial navigation in

Author

Timothy L, Warren, Ysabel M, Giraldo, and Michael H, Dickinson

Subjects

Drosophila melanogaster, Phototaxis, Animals, Review, Cues, Orientation, Spatial, Spatial Navigation

Abstract

Many casual observers typecast Drosophila melanogaster as a stationary pest that lurks around fruit and wine. However, the omnipresent fruit fly, which thrives even in desert habitats, likely established and maintained its cosmopolitan status via migration over large spatial scales. To perform long-distance dispersal, flies must actively maintain a straight compass heading through the use of external orientation cues, such as those derived from the sky. In this Review, we address how D. melanogaster accomplishes long-distance navigation using celestial cues. We focus on behavioral and physiological studies indicating that fruit flies can navigate both to a pattern of linearly polarized light and to the position of the sun – the same cues utilized by more heralded insect navigators such as monarch butterflies and desert ants. In both cases, fruit flies perform menotaxis, selecting seemingly arbitrary headings that they then maintain over time. We discuss how the fly's nervous system detects and processes this sensory information to direct the steering maneuvers that underlie navigation. In particular, we highlight recent findings that compass neurons in the central complex, a set of midline neuropils, are essential for navigation. Taken together, these results suggest that fruit flies share an ancient, latent capacity for celestial navigation with other insects. Furthermore, they illustrate the potential of D. melanogaster to help us to elucidate both the cellular basis of navigation and mechanisms of directed dispersal on a landscape scale.

Published

2019

24. Anatomical Reconstruction and Functional Imaging Reveal an Ordered Array of Skylight Polarization Detectors inDrosophila

Author

Peter T. Weir, Michael H. Dickinson, Christiane Bleul, Miriam J. Henze, Franziska Baumann-Klausener, and Thomas Labhart

Subjects

0301 basic medicine, Linearly polarized light, Biology, 03 medical and health sciences, Optics, Compass, Animals, Compound Eye, Arthropod, Vision, Ocular, business.industry, General Neuroscience, Detector, Articles, Anatomy, Compound eye, biology.organism_classification, Skylight, Polarization (waves), Functional imaging, Drosophila melanogaster, 030104 developmental biology, Visual Perception, Photoreceptor Cells, Invertebrate, sense organs, business, Spatial Navigation

Abstract

Many insects exploit skylight polarization as a compass cue for orientation and navigation. In the fruit fly,Drosophila melanogaster, photoreceptors R7 and R8 in the dorsal rim area (DRA) of the compound eye are specialized to detect the electric vector (e-vector) of linearly polarized light. These photoreceptors are arranged in stacked pairs with identical fields of view and spectral sensitivities, but mutually orthogonal microvillar orientations. As in larger flies, we found that the microvillar orientation of the distal photoreceptor R7 changes in a fan-like fashion along the DRA. This anatomical arrangement suggests that the DRA constitutes a detector for skylight polarization, in which different e-vectors maximally excite different positions in the array. To test our hypothesis, we measured responses to polarized light of varying e-vector angles in the terminals of R7/8 cells using genetically encoded calcium indicators. Our data confirm a progression of preferred e-vector angles from anterior to posterior in the DRA, and a strict orthogonality between the e-vector preferences of paired R7/8 cells. We observed decreased activity in photoreceptors in response to flashes of light polarized orthogonally to their preferred e-vector angle, suggesting reciprocal inhibition between photoreceptors in the same medullar column, which may serve to increase polarization contrast. Together, our results indicate that the polarization-vision system relies on a spatial map of preferred e-vector angles at the earliest stage of sensory processing.SIGNIFICANCE STATEMENTThe fly's visual system is an influential model system for studying neural computation, and much is known about its anatomy, physiology, and development. The circuits underlying motion processing have received the most attention, but researchers are increasingly investigating other functions, such as color perception and object recognition. In this work, we investigate the early neural processing of a somewhat exotic sense, called polarization vision. Because skylight is polarized in an orientation that is rigidly determined by the position of the sun, this cue provides compass information. Behavioral experiments have shown that many species use the polarization pattern in the sky to direct locomotion. Here we describe the input stage of the fly's polarization-vision system.

Published

2016

25. Algorithms for Olfactory Search across Species

Author

Justus V. Verhagen, Keeley L. Baker, Michael H. Dickinson, Matthieu Louis, David H. Gire, Marie P. Suver, Teresa M Findley, Katherine I. Nagel, and Matthew C. Smear

Subjects

0301 basic medicine, olfactory navigation, Computer science, active sensing, Turbulent airflow, Olfaction, Environment, Medical and Health Sciences, memory, 03 medical and health sciences, Species Specificity, Memory, Animals, Humans, olfactory search, Olfactory navigation, Neurology & Neurosurgery, General Neuroscience, Symposium and Mini-Symposium, turbulence, Psychology and Cognitive Sciences, Sampling (statistics), Active sensing, Smell, 030104 developmental biology, Odor, Odorants, Algorithm, Algorithms, olfaction

Abstract

Localizing the sources of stimuli is essential. Most organisms cannot eat, mate, or escape without knowing where the relevant stimuli originate. For many, if not most, animals, olfaction plays an essential role in search. While microorganismal chemotaxis is relatively well understood, in larger animals the algorithms and mechanisms of olfactory search remain mysterious. In this symposium, we will present recent advances in our understanding of olfactory search in flies and rodents. Despite their different sizes and behaviors, both species must solve similar problems, including meeting the challenges of turbulent airflow, sampling the environment to optimize olfactory information, and incorporating odor information into broader navigational systems.

Published

2018

26. Diverse food-sensing neurons trigger idiothetic local search in Drosophila

Author

Michael H. Dickinson and Román A. Corfas

Subjects

0303 health sciences, biology, business.industry, Computer science, fungi, Foraging, Sensory system, Optogenetics, biology.organism_classification, 03 medical and health sciences, 0302 clinical medicine, Local search (optimization), Idiothetic, Drosophila melanogaster, business, Neuroscience, Drosophila, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Resources are often sparsely clustered in nature. Thus, foraging animals may benefit from remembering the location of a newly discovered food patch while continuing to explore nearby [1, 2]. For example, after encountering a drop of yeast or sugar, hungry flies often perform a local search consisting of frequent departures and returns to the food site [3, 4]. Fruit flies, Drosophila melanogaster, can perform this food-centered search behavior in the absence of external stimuli or landmarks, instead relying solely on internal (idiothetic) cues to keep track of their location [5]. This path integration behavior may represent a deeply conserved navigational capacity in insects [6, 7], but the neural pathways underlying food-triggered searches remain unknown. Here, we used optogenetic activation to screen candidate cell classes and found that local searches can be initiated by diverse sensory neurons including sugar-sensors, water-sensors, olfactory-receptor neurons, as well as hunger-signaling neurons of the central nervous system. Optogenetically-induced searches resemble those triggered by actual food and are modulated by starvation state. Furthermore, search trajectories exhibit key features of path integration: searches remain tightly centered around the fictive-food site, even during long periods without reinforcement, and flies re-center their searches when they encounter a new fictive-food site. Flies can even perform elaborate local searches within a constrained maze. Together, these results suggest that flies enact local searches in response to a wide variety of food-associated cues, and that these sensory pathways may converge upon a common neural system for path integration. Optogenetically induced local searches in Drosophila can now serve as a tractable system for the study of spatial memory and navigation in insects.

Published

2018

27. Multifunctional Wing Motor Control of Song and Flight

Author

Anna Prudnikova, Michael H. Dickinson, Theodore H. Lindsay, Balázs Érdi, Angela O’Sullivan, and Anne C. von Philipsborn

Subjects

0301 basic medicine, Functional role, Male, animal structures, Context (language use), Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Neuronal control, Motor system, Animals, Wings, Animal, Set (psychology), Wing, Muscles, Motor control, Animal Communication, 030104 developmental biology, nervous system, Flight, Animal, behavior and behavior mechanisms, Drosophila, General Agricultural and Biological Sciences, Neuroscience, Neuromuscular activity, 030217 neurology & neurosurgery, psychological phenomena and processes

Abstract

Multifunctional motor systems produce distinct output patterns that are dependent on behavioral context, posing a challenge to underlying neuronal control. Flies use their wings for flight and the production of a patterned acoustic signal, the male courtship song, employing in both cases a small set of wing muscles and corresponding motor neurons. We took first steps toward elucidating the neuronal control mechanisms of this multifunctional motor system by live imaging of muscle ensemble activity patterns during song and flight, and we established the functional role of a comprehensive set of wing muscle motor neurons by silencing experiments. Song and flight rely on distinct configurations of neuromuscular activity, with most, but not all, flight muscles and their corresponding motor neurons contributing to song and shaping its acoustic parameters. The two behaviors are exclusive, and the neuronal command for flight overrides the command for song. The neuromodulator octopamine is a candidate for selectively stabilizing flight, but not song motor patterns.

Published

2018

28. The functional organization of descending sensory-motor pathways in Drosophila

Author

Gwyneth M Card, Allan M. Wong, Wyatt Korff, Michael H. Dickinson, and Shigehiro Namiki

Subjects

Nervous system, 0301 basic medicine, Cell type, anatomy, QH301-705.5, brain, Science, Population, Sensory system, sensory-motor, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, ventral nerve cord, biology.animal, Neuropil, medicine, Biological neural network, descending neuron, Biology (General), education, Drosophila, education.field_of_study, General Immunology and Microbiology, biology, General Neuroscience, fungi, Vertebrate, General Medicine, Spinal cord, biology.organism_classification, 030104 developmental biology, medicine.anatomical_structure, Ventral nerve cord, Medicine, split-GAL4, Drosophila melanogaster, Neuroscience, Drosophila Protein

Abstract

SUMMARYIn most animals, the brain controls the body via a set of descending neurons (DNs) that traverse the neck and terminate in post-cranial regions of the nervous system. This critical neural population is thought to activate, maintain and modulate locomotion and other behaviors. Although individual members of this cell class have been well-studied across species ranging from insects to primates, little is known about the overall connectivity pattern of DNs as a population. We undertook a systematic anatomical investigation of descending neurons in the fruit fly,Drosophila melanogaster, and created a collection of over 100 transgenic lines targeting individual cell types. Our methods allowed us to describe the morphology of roughly half of an estimated 400 DNs and create a comprehensive map of connectivity between the sensory neuropils in the brain and the motor neuropils in the ventral nerve cord. Like the vertebrate spinal cord, our results show that the fly nerve cord is a highly organized, layered system of neuropils, an organization that reflects the fact that insects are capable of two largely independent means of locomotion – walking and fight – using distinct sets of appendages. Our results reveal the basic functional map of descending pathways in flies and provide tools for systematic interrogation of sensory-motor circuits.

Published

2018

29. Flow Structure and Force Generation on Flapping Wings at Low Reynolds Numbers Relevant to the Flight of Tiny Insects

Author

Michael H. Dickinson, Shannon Jones, Arvind Santhanakrishnan, Martin Y. Peek, Vishwa T. Kasoju, William B. Dickson, and Laura Miller

Subjects

030110 physiology, 0106 biological sciences, 0301 basic medicine, Flow visualization, insect flight, low Reynolds number, lcsh:Thermodynamics, 010603 evolutionary biology, 01 natural sciences, Insect flight, 03 medical and health sciences, symbols.namesake, immersed boundary method, lcsh:QC310.15-319, Trailing edge, flow visualization, lcsh:QC120-168.85, Fluid Flow and Transfer Processes, Physics, Wing, Mechanical Engineering, Reynolds number, Aerodynamics, Mechanics, Condensed Matter Physics, Drag, symbols, Flapping, lcsh:Descriptive and experimental mechanics, aerodynamics

Abstract

In contrast to larger species, little is known about the flight of the smallest flying insects, such as thrips and fairyflies. These tiny animals range from 300 to 1000 microns in length and fly at Reynolds numbers ranging from about 4 to 60. Previous work with numerical and physical models have shown that the aerodynamics of these diminutive insects is significantly different from that of larger animals, but most of these studies have relied on two-dimensional approximations. There can, however, be significant differences between two- and three-dimensional flows, as has been found for larger insects. To better understand the flight of the smallest insects, we have performed a systematic study of the forces and flow structures around a three-dimensional revolving elliptical wing. We used both a dynamically scaled physical model and a three-dimensional computational model at Reynolds numbers ranging from 1 to 130 and angles of attacks ranging from 0&deg, to 90&deg, The results of the physical and computational models were in good agreement and showed that dimensionless drag, aerodynamic efficiency, and spanwise flow all decrease with decreasing Reynolds number. In addition, both the leading and trailing edge vortices remain attached to the wing over the scales relevant to the smallest flying insects. Overall, these observations suggest that there are drastic differences in the aerodynamics of flight at the scale of the smallest flying animals.

Published

2018

30. Author response: The functional organization of descending sensory-motor pathways in Drosophila

Author

Gwyneth M Card, Wyatt Korff, Allan M. Wong, Shigehiro Namiki, and Michael H. Dickinson

Subjects

Sensory motor, Functional organization, Biology, Drosophila (subgenus), biology.organism_classification, Neuroscience

Published

2018

31. Sun navigation requires compass neurons in Drosophila

Author

Ivo G. Ros, Peter T. Weir, Katherine J. Leitch, Michael H. Dickinson, Timothy L. Warren, and Ysabel Milton Giraldo

Subjects

0301 basic medicine, animal structures, Computer science, Biology, Stimulus (physiology), Flight simulator, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Orientation, Compass, Phototaxis, Animals, Computer vision, Orientation, Spatial, 030304 developmental biology, Neurons, 0303 health sciences, Landmark, business.industry, Brain, Solar compass, 030104 developmental biology, Drosophila melanogaster, Sunlight, Artificial intelligence, Cues, General Agricultural and Biological Sciences, Visual landmarks, business, 030217 neurology & neurosurgery

Abstract

Despite their small brains, insects can navigate over long distances by orienting using visual landmarks [1], skylight polarization [2, 3, 4, 5, 6, 7, 8, 9], and sun position [3, 4, 6, 10]. Although Drosophila are not generally renowned for their navigational abilities, mark-and-recapture experiments in Death Valley revealed that they can fly nearly 15 km in a single evening [11]. To accomplish such feats on available energy reserves [12], flies would have to maintain relatively straight headings, relying on celestial cues [13]. Cues such as sun position and polarized light are likely integrated throughout the sensory-motor pathway [14], including the highly conserved central complex [4, 15, 16]. Recently, a group of Drosophila central complex cells (E-PG neurons) have been shown to function as an internal compass [17, 18, 19], similar to mammalian head-direction cells [20]. Using an array of genetic tools, we set out to test whether flies can navigate using the sun and to identify the role of E-PG cells in this behavior. Using a flight simulator, we found that Drosophila adopt arbitrary headings with respect to a simulated sun, thus performing menotaxis, and individuals remember their heading preference between successive flights—even over several hours. Imaging experiments performed on flying animals revealed that the E-PG cells track sun stimulus motion. When these neurons are silenced, flies no longer adopt and maintain arbitrary headings relative to the sun stimulus but instead exhibit frontal phototaxis. Thus, without the compass system, flies lose the ability to execute menotaxis and revert to a simpler, reflexive behavior.

Published

2018

32. History dependence in insect flight decisions during odor tracking

Author

Michael H. Dickinson, Floris van Breugel, Richard Pang, Adrienne L. Fairhall, and Jeffrey A. Riffell

Subjects

0301 basic medicine, Atmospheric Science, Physiology, Wind, Disease Vectors, Animal flight, Tracking (particle physics), Mosquitoes, Sexual Behavior, Animal, 0302 clinical medicine, Aedes, Medicine and Health Sciences, lcsh:QH301-705.5, Mathematics, Behavior, Animal, Ecology, Organic Compounds, Drosophila Melanogaster, Eukaryota, Contrast (statistics), Animal Models, Plume, Insects, Smell, Chemistry, Variable (computer science), Infectious Diseases, Memory, Short-Term, Experimental Organism Systems, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Drosophila, Biological system, Flight (Biology), Algorithms, Research Article, Arthropoda, Decision Making, Research and Analysis Methods, Models, Biological, Insect flight, 03 medical and health sciences, Cellular and Molecular Neuroscience, Meteorology, Model Organisms, Genetics, Animals, Learning, Computer Simulation, Information gain, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Probability, Ethanol, Biological Locomotion, Organic Chemistry, Organisms, Chemical Compounds, Biology and Life Sciences, Invertebrates, Insect Vectors, Species Interactions, 030104 developmental biology, Odor, lcsh:Biology (General), Alcohols, Flight, Animal, Odorants, Earth Sciences, Linear Models, Insect Flight, 030217 neurology & neurosurgery

Abstract

Natural decision-making often involves extended decision sequences in response to variable stimuli with complex structure. As an example, many animals follow odor plumes to locate food sources or mates, but turbulence breaks up the advected odor signal into intermittent filaments and puffs. This scenario provides an opportunity to ask how animals use sparse, instantaneous, and stochastic signal encounters to generate goal-oriented behavioral sequences. Here we examined the trajectories of flying fruit flies (Drosophila melanogaster) and mosquitoes (Aedes aegypti) navigating in controlled plumes of attractive odorants. While it is known that mean odor-triggered flight responses are dominated by upwind turns, individual responses are highly variable. We asked whether deviations from mean responses depended on specific features of odor encounters, and found that odor-triggered turns were slightly but significantly modulated by two features of odor encounters. First, encounters with higher concentrations triggered stronger upwind turns. Second, encounters occurring later in a sequence triggered weaker upwind turns. To contextualize the latter history dependence theoretically, we examined trajectories simulated from three normative tracking strategies. We found that neither a purely reactive strategy nor a strategy in which the tracker learned the plume centerline over time captured the observed history dependence. In contrast, “infotaxis”, in which flight decisions maximized expected information gain about source location, exhibited a history dependence aligned in sign with the data, though much larger in magnitude. These findings suggest that while true plume tracking is dominated by a reactive odor response it might also involve a history-dependent modulation of responses consistent with the accumulation of information about a source over multi-encounter timescales. This suggests that short-term memory processes modulating decision sequences may play a role in natural plume tracking., Author summary Many important behaviors require animals to make extended decision sequences in response to complex stimuli. In this study we investigated the sequences of navigational decisions made by fruit flies and mosquitoes while tracking odor plumes, which are generally subject to turbulence. By examining video-taped 3D trajectories of these insects flying in a wind tunnel containing an attractive odor plume, we asked what features of encounters with the plume influenced odor-triggered flight decisions. Most notably, we found that although the average response was dominated by a reflexive upwind turn, its strength was modulated by the history of prior plume encounters throughout the trajectory. While no theoretical strategy we simulated captured all aspects of the data, the algebraic sign of the history dependence was only recapitulated in a model where a simulated tracking agent maximizes information about the position of the plume source. This suggests that real odor tracking may involve short-term memory processes over multi-encounter timescales that are consistent with the accumulation of information about source location.

Published

2018

33. Imaging neural activity in the ventral nerve cord of behaving adult Drosophila

Author

Michael Unser, Chin Lin Chen, Pavan Ramdya, Denis Fortun, Laura Hermans, Meera C. Viswanathan, Anthony Cammarato, and Michael H. Dickinson

Subjects

Nervous system, 0303 health sciences, Cord, biology, Vertebrate, biology.organism_classification, Functional imaging, 03 medical and health sciences, Neural activity, 0302 clinical medicine, medicine.anatomical_structure, biology.animal, Ventral nerve cord, medicine, Biological neural network, Drosophila melanogaster, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

To understand neural circuits that control limbs, one must measure their activity during behavior. Until now this goal has been challenging, because the portion of the nervous system that contains limb premotor and motor circuits is largely inaccessible to large-scale recording techniques in intact, moving animals – a constraint that is true for both vertebrate and invertebrate models. Here, we introduce a method for 2-photon functional imaging from the ventral nerve cord of behaving adultDrosophila melanogaster. We use this method to reveal patterns of activity across nerve cord populations during grooming and walking and to uncover the functional encoding of moonwalker ascending neurons (MANs), moonwalker descending neurons (MDNs), and a novel class of locomotion-associated descending neurons. This new approach enables the direct investigation of circuits associated with complex limb movements.

Published

2018

34. Flying

Author

Timothy L, Warren, Peter T, Weir, and Michael H, Dickinson

Subjects

Drosophila melanogaster, Light, Memory, Flight, Animal, Animals, Cues, Orientation, Spatial

Abstract

Animals must use external cues to maintain a straight course over long distances. In this study, we investigated how the fruit fly

Published

2018

35. FlyingDrosophilamaintain arbitrary but stable headings relative to the angle of polarized light

Author

Peter T. Weir, Michael H. Dickinson, and Timothy L. Warren

Subjects

0301 basic medicine, Physics, Physiology, business.industry, Linearly polarized light, fungi, Angular velocity, Aquatic Science, Polarization (waves), Flight simulator, Solar compass, 03 medical and health sciences, Light intensity, 030104 developmental biology, 0302 clinical medicine, Optics, Amplitude, Insect Science, Proportional navigation, Animal Science and Zoology, business, Molecular Biology, 030217 neurology & neurosurgery, Ecology, Evolution, Behavior and Systematics

Abstract

Animals must use external cues to maintain a straight course over long distances. In this study, we investigated how the fruit fly, Drosophila melanogaster, selects and maintains a flight heading relative to the axis of linearly polarized light, a visual cue produced by the atmospheric scattering of sunlight. To track flies’ headings over extended periods, we used a flight simulator that coupled the angular velocity of dorsally presented polarized light to the stroke amplitude difference of the animal's wings. In the simulator, most flies actively maintained a stable heading relative to the axis of polarized light for the duration of 15 minute flights. We found that individuals selected arbitrary, unpredictable headings relative to the polarization axis, which demonstrates that Drosophila can perform proportional navigation using a polarized light pattern. When flies flew in two consecutive bouts separated by a 5 minute gap, the two flight headings were correlated, suggesting individuals retain a memory of their chosen heading. We found that adding a polarized light pattern to a light intensity gradient enhanced flies’ orientation ability, suggesting Drosophila use a combination of cues to navigate. For both polarized light and intensity cues, flies’ capacity to maintain a stable heading gradually increased over several minutes from the onset of flight. Our findings are consistent with a model in which each individual initially orients haphazardly but then settles on a heading which is maintained via a self-reinforcing process. This may be a general dispersal strategy for animals with no target destination.

Published

2018

36. Antennal Mechanosensory Neurons Mediate Wing Motor Reflexes in FlyingDrosophila

Author

Akira Mamiya and Michael H. Dickinson

Subjects

Arthropod Antennae, Biology, Insect flight, Tonic (physiology), Calcium imaging, Reflex, medicine, Animals, Wings, Animal, Vision, Ocular, Feedback, Physiological, Motor Neurons, Wing, Mechanosensation, General Neuroscience, fungi, Articles, Anatomy, biology.organism_classification, Drosophila melanogaster, medicine.anatomical_structure, Flight, Animal, Neuron, Mechanoreceptors, Neuroscience

Abstract

Although many behavioral studies have shown the importance of antennal mechanosensation in various aspects of insect flight control, the identities of the mechanosensory neurons responsible for these functions are still unknown. One candidate is the Johnston's organ (JO) neurons that are located in the second antennal segment and detect phasic and tonic rotations of the third antennal segment relative to the second segment. To investigate how different classes of JO neurons respond to different types of antennal movement during flight, we combined 2-photon calcium imaging with a machine vision system to simultaneously record JO neuron activity and the antennal movement from tethered flying fruit flies (Drosophila melanogaster). We found that most classes of JO neurons respond strongly to antennal oscillation at the wing beat frequency, but not to the tonic deflections of the antennae. To study how flies use input from the JO neurons during flight, we genetically ablated specific classes of JO neurons and examined their effect on the wing motion. Tethered flies flying in the dark require JO neurons to generate slow antiphasic oscillation of the left and right wing stroke amplitudes. However, JO neurons are not necessary for this antiphasic oscillation when visual feedback is available, indicating that there are multiple pathways for generating antiphasic movement of the wings. Collectively, our results are consistent with a model in which flying flies use JO neurons to detect increases in the wing-induced airflow and that JO neurons are involved in a response that decreases contralateral wing stoke amplitude.

Published

2015

37. Distinct activity-gated pathways mediate attraction and aversion to CO

Author

Floris, van Breugel, Ainul, Huda, and Michael H, Dickinson

Subjects

Male, Ethanol, Decision Making, Feeding Behavior, Walking, Carbon Dioxide, Receptors, Ionotropic Glutamate, Article, Drosophila melanogaster, Flight, Animal, Yeasts, Fermentation, Neural Pathways, Odorants, Avoidance Learning, Animals, Drosophila Proteins, Female

Abstract

Carbon dioxide is produced by many organic processes, and is a convenient volatile cue for insects1 searching for blood hosts2, flowers3, communal nests4, fruit5, and wildfires6. Curiously, although Drosophila melanogaster feed on yeast that produce CO2 and ethanol during fermentation, laboratory experiments suggest that walking flies avoid CO27–12. Here, we resolve this paradox by showing that both flying and walking Drosophila find CO2 attractive, but only when in an active state associated with foraging. Aversion at low activity levels may be an adaptation to avoid CO2-seeking-parasites, or succumbing to respiratory acidosis in the presence of high concentrations of CO2 that exist in nature13,14. In contrast to CO2, flies are attracted to ethanol in all behavioral states, and invest twice the time searching near ethanol compared to CO2. These behavioral differences reflect the fact that whereas CO2 is generated by many natural processes, ethanol is a unique signature of yeast fermentation. Using genetic tools, we determined that the evolutionarily ancient ionotropic co-receptor IR25a is required for CO2 attraction, and that the receptors necessary for CO2 avoidance are not involved. Our study lays the foundation for future research to determine the neural circuits underlying both state- and odorant- dependent decision making in Drosophila.

Published

2017

38. Superhydrophobic diving flies (Ephydra hians) and the hypersaline waters of Mono Lake

Author

Floris van Breugel and Michael H. Dickinson

Subjects

0301 basic medicine, Ecological niche, Kosmotropic, Multidisciplinary, Cuticle, Seta, 02 engineering and technology, Biology, 021001 nanoscience & nanotechnology, Ephydra hians, Salinity, 03 medical and health sciences, 030104 developmental biology, Botany, Extreme environment, Wetting, 0210 nano-technology

Abstract

The remarkable alkali fly, Ephydra hians , deliberately crawls into the alkaline waters of Mono Lake to feed and lay eggs. These diving flies are protected by an air bubble that forms around their superhydrophobic cuticle upon entering the lake. To study the physical mechanisms underlying this process we measured the work required for flies to enter and leave various aqueous solutions. Our measurements show that it is more difficult for the flies to escape from Mono Lake water than from fresh water, due to the high concentration of Na 2 CO 3 which causes water to penetrate and thus wet their setose cuticle. Other less kosmotropic salts do not have this effect, suggesting that the phenomenon is governed by Hofmeister effects as well as specific interactions between ion pairs. These effects likely create a small negative charge at the air–water interface, generating an electric double layer that facilitates wetting. Compared with six other species of flies, alkali flies are better able to resist wetting in a 0.5 M Na 2 CO 3 solution. This trait arises from a combination of factors including a denser layer of setae on their cuticle and the prevalence of smaller cuticular hydrocarbons compared with other species. Although superbly adapted to resisting wetting, alkali flies are vulnerable to getting stuck in natural and artificial oils, including dimethicone, a common ingredient in sunscreen and other cosmetics. Mono Lake’s alkali flies are a compelling example of how the evolution of picoscale physical and chemical changes can allow an animal to occupy an entirely new ecological niche.

Published

2017

39. Drosophila have distinct activity-gated pathways that mediate attraction and aversion to CO2

Author

Floris van Breugel, Michael H. Dickinson, and Ainul Huda

Subjects

biology, Evolutionary biology, Foraging, Fermentation, Drosophila melanogaster, Adaptation, biology.organism_classification, Attraction, Drosophila, Yeast, Ionotropic effect

Abstract

Carbon dioxide is a volatile and broad signal of many organic processes, and serves as a convenient cue for insects in search of blood hosts1–6, flowers7, decaying matter8–11, communal nests12, fruit13, and wildfires14. Curiously, although Drosophila melanogaster feed on yeast that produce CO2 and ethanol during fermentation, laboratory experiments suggest that flies actively avoid CO215–25. Here, we resolve this paradox by showing that both flying and walking fruit flies do actually find CO2 attractive, but only when they are in an active state associated with foraging. Aversion at low activity levels may be an adaptation to avoid CO2-seeking-parasites, or succumbing to respiratory acidosis in the presence of high concentrations of CO2 that are occasionally found in nature26,27. In contrast to CO2, flies are attracted to ethanol in all behavioral states, and invest twice as much time searching near ethanol compared to CO2. These behavioral differences reflect the fact that whereas CO2 is a generated by many natural processes, ethanol is a unique signature of yeast fermentation. Using genetic tools, we determined that the evolutionarily ancient ionotropic co-receptor IR25a is required for both CO2 and ethanol attraction, and that the receptors previously identified for CO2 avoidance are not involved. Our study lays the foundation for future research to determine the neural circuits underlying both state- and odorant-dependent decision making in Drosophila.

Published

2017

40. Superhydrophobic diving flies (

Author

Floris, van Breugel and Michael H, Dickinson

Subjects

Lakes, Salinity, Animal Shells, Surface Properties, Diptera, Static Electricity, Carbonates, Wettability, Animals, Biological Sciences, Adaptation, Physiological, Biomechanical Phenomena, Extreme Environments

Abstract

Superhydrophobic surfaces have been of key academic and commercial interest since the discovery of the so-called lotus effect in 1977. The effect of different ions on complex superhydrophobic biological systems, however, has received little attention. By bringing together ecology, biomechanics, physics, and chemistry our study provides insight into the ion-specific effects of wetting in the presence of sodium carbonate and its large-scale consequences. By comparing the surface structure and chemistry of the alkali fly—an important food source for migrating birds—to other species we show that their uniquely hydrophobic properties arise from very small physical and chemical changes, thereby connecting picoscale physics with globally important ecological impacts.

Published

2017

41. Modulation of Host Learning in Aedes aegypti Mosquitoes

Author

Jay Z. Parrish, Gabriella H. Wolff, Clément Vinauger, Michael H. Dickinson, Chloé Lahondère, Omar S. Akbari, Jessica E. Liaw, Jeffrey A. Riffell, and Lauren T. Locke

Subjects

0301 basic medicine, Dopamine, Conditioning, Classical, Insect, Medical and Health Sciences, 0302 clinical medicine, Aedes aegypti, Aedes, CRISPR, media_common, 0303 health sciences, education.field_of_study, biology, Ecology, Vertebrate, Biological Sciences, 3. Good health, medicine.anatomical_structure, Infectious Diseases, disease vector, neuromodulation, Female, Olfactory Learning, General Agricultural and Biological Sciences, media_common.quotation_subject, Population, Zoology, mosquito, aversive conditioning, Basic Behavioral and Social Science, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, biology.animal, parasitic diseases, Behavioral and Social Science, medicine, Avoidance Learning, olfactory learning, Animals, Humans, education, 030304 developmental biology, Host (biology), fungi, Psychology and Cognitive Sciences, Neurosciences, Feeding Behavior, biology.organism_classification, Olfactory Perception, Classical, Rats, Vector-Borne Diseases, 030104 developmental biology, Biting, Odorants, Antennal lobe, Neuroscience, Chickens, 030217 neurology & neurosurgery, Conditioning, Developmental Biology

Abstract

How mosquitoes determine which individuals to bite has important epidemiological consequences. This choice is not random; most mosquitoes specialize in one or a few vertebrate host species, and some individuals in a host population are preferred over others. Mosquitoes will also blood feed from other hosts when their preferred is no longer abundant, but the mechanisms mediating these shifts between hosts, and preferences for certain individuals within a host species, remain unclear. Here, we show that olfactory learning may contribute to Aedes aegypti mosquito biting preferences and host shifts. Training and testing to scents of humans and other host species showed that mosquitoes can aversively learn the scent of specific humans and single odorants and learn to avoid the scent of rats (but not chickens). Using pharmacological interventions, RNAi, and CRISPR gene editing, we found that modification of the dopamine-1 receptor suppressed their learning abilities. We further show through combined electrophysiological and behavioral recordings from tethered flying mosquitoes that these odors evoke changes in both behavior and antennal lobe (AL) neuronal responses and that dopamine strongly modulates odor-evoked responses in AL neurons. Not only do these results provide direct experimental evidence that olfactory learning in mosquitoes canplay an epidemiological role, but collectively, they also provide neuroanatomical and functional demonstration of the role of dopamine in mediating this learning-induced plasticity, for the first time in a disease vector insect.

Published

2017

42. Idiothetic Path Integration in the Fruit Fly Drosophila melanogaster

Author

Irene S. Kim and Michael H. Dickinson

Subjects

0301 basic medicine, Foraging, Olfactory cues, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Specialization (functional), Path integration, Animals, Drosophila, Local search (constraint satisfaction), Communication, biology, business.industry, Ecology, fungi, Feeding Behavior, Olfactory Perception, biology.organism_classification, Drosophila melanogaster, 030104 developmental biology, Food, Exploratory Behavior, Visual Perception, Idiothetic, Cues, General Agricultural and Biological Sciences, business, 030217 neurology & neurosurgery

Abstract

After discovering a small drop of food, hungry flies exhibit a peculiar behavior in which they repeatedly stray from, but then return to, the newly discovered resource. To study this behavior in more detail, we tracked hungry Drosophila as they explored a large arena, focusing on the question of how flies remain near the food. To determine whether flies use external stimuli, we individually eliminated visual, olfactory, and pheromonal cues. In all cases, flies still exhibited a centralized search behavior, suggesting that none of these cues are absolutely required for navigation back to the food. To simultaneously eliminate visual and olfactory cues associated with the position of the food, we constructed an apparatus in which the food could be rapidly translated from the center of the arena. Flies continued to search around the original location, even after the food was moved to a new position. A random search model based on measured locomotor statistics could not reproduce the centered nature of the animal's trajectory. We conclude that this behavior is best explained by a form of path integration in which the flies use idiothetic cues to search near the location of the food. We argue that the use of path integration to perform a centered local search is not a specialization of Drosophila but rather represents an ancient behavioral mode that is homologous to the more elaborate foraging strategies of central place foragers such as ants.

Published

2017

43. A Systematic Nomenclature for theDrosophilaVentral Nervous System

Author

David Shepherd, Richard S. Mann, David J. Merritt, Carsten Duch, Andrew M. Seeds, James W. Truman, Rod K. Murphey, John C. Tuthill, Shigehiro Namiki, Robert Court, Darren W. Williams, Troy R. Shirangi, Michael H. Dickinson, Jana Börner, Julie A. Simpson, James Douglas Armstrong, Gwyneth M Card, Marta Costa, and Wyatt Korff

Subjects

Nervous system, 0303 health sciences, biology, media_common.quotation_subject, fungi, Adult insect, Anatomy, Insect, biology.organism_classification, Neuromere, 3. Good health, 03 medical and health sciences, 0302 clinical medicine, Taxon, medicine.anatomical_structure, medicine, Drosophila melanogaster, Drosophila (subgenus), Neuroscience, Nomenclature, 030217 neurology & neurosurgery, 030304 developmental biology, media_common

Abstract

The fruit fly,Drosophila melanogaster, is an established and powerful model system for neuroscience research with wide relevance in biology and medicine. Until recently, research on theDrosophilabrain was hindered by the lack of a complete and uniform nomenclature. Recognising this problem, the Insect Brain Name Working Group produced an authoritative hierarchical nomenclature system for the adult insect brain, usingDrosophila melanogasteras the reference framework, with other taxa considered to ensure greater consistency and expandability (Ito et al., 2014). Here, we extend this nomenclature system to the sub-gnathal regions of the adultDrosophilanervous system, thus providing a systematic anatomical description of the ventral nervous system (VNS). This portion of the nervous system includes the thoracic and abdominal neuromeres that were not included in the original work and contains the motor circuits that play essential roles in most fly behaviours.

Published

2017

44. Flies compensate for unilateral wing damage through modular adjustments of wing and body kinematics

Author

Michael H. Dickinson, Florian T. Muijres, Johan M. Melis, Michael John Elzinga, and Nicole A. Iwasaki

Subjects

030110 physiology, 0301 basic medicine, animal structures, Flapping flight, Flight control, Biomedical Engineering, Biophysics, Bioengineering, Kinematics, Biochemistry, Body roll, Biomaterials, 03 medical and health sciences, Aerodynamics, Washout (aeronautics), Torque, Biomechanics, Experimental Zoology, Physics, Wing, business.industry, fungi, Structural engineering, Articles, Experimentele Zoologie, WIAS, Flapping, Drosophila, business, Biotechnology

Abstract

Using high-speed videography, we investigated how fruit flies compensate for unilateral wing damage, in which loss of area on one wing compromises both weight support and roll torque equilibrium. Our results show that flies control for unilateral damage by rolling their body towards the damaged wing and by adjusting the kinematics of both the intact and damaged wings. To compensate for the reduction in vertical lift force due to damage, flies elevate wingbeat frequency. Because this rise in frequency increases the flapping velocity of both wings, it has the undesired consequence of further increasing roll torque. To compensate for this effect, flies increase the stroke amplitude and advance the timing of pronation and supination of the damaged wing, while making the opposite adjustments on the intact wing. The resulting increase in force on the damaged wing and decrease in force on the intact wing function to maintain zero net roll torque. However, the bilaterally asymmetrical pattern of wing motion generates a finite lateral force, which flies balance by maintaining a constant body roll angle. Based on these results and additional experiments using a dynamically scaled robotic fly, we propose a simple bioinspired control algorithm for asymmetric wing damage.

Published

2017

45. Hovering Flight in the HoneybeeApis mellifera: Kinematic Mechanisms for Varying Aerodynamic Forces

Author

Jason T. Vance, Michael H. Dickinson, William B. Dickson, Stephen P. Roberts, and Douglas L. Altshuler

Subjects

Wing, Physiology, Angle of attack, Acoustics, Video Recording, Kinematics, Bees, Models, Theoretical, Biology, Rotation, Helium, Biochemistry, Biomechanical Phenomena, Oxygen, Aerodynamic force, Amplitude, Flight, Animal, Orientation (geometry), Animals, Wings, Animal, Animal Science and Zoology, Wing loading

Abstract

During hovering flight, animals can increase the wing velocity and therefore the net aerodynamic force per stroke by increasing wingbeat frequency, wing stroke amplitude, or both. The magnitude and orientation of aerodynamic forces are also influenced by the geometric angle of attack, timing of wing rotation, wing contact, and pattern of deviation from the primary stroke plane. Most of the kinematic data available for flying animals are average values for wing stroke amplitude and wingbeat frequency because these features are relatively easy to measure, but it is frequently suggested that the more subtle and difficult-to-measure features of wing kinematics can explain variation in force production for different flight behaviors. Here, we test this hypothesis with multicamera high-speed recording and digitization of wing kinematics of honeybees (Apis mellifera) hovering and ascending in air and hovering in a hypodense gas (heliox: 21% O2, 79% He). Bees employed low stroke amplitudes (86.7° ± 7.9°) and high wingbeat frequencies (226.8 ± 12.8 Hz) when hovering in air. When ascending in air or hovering in heliox, bees increased stroke amplitude by 30%-45%, which yielded a much higher wing tip velocity relative to that during simple hovering in air. Across the three flight conditions, there were no statistical differences in the amplitude of wing stroke deviation, minimum and stroke-averaged geometric angle of attack, maximum wing rotation velocity, or even wingbeat frequency. We employed a quasi-steady aerodynamic model to estimate the effects of wing tip velocity and geometric angle of attack on lift and drag. Lift forces were sensitive to variation in wing tip velocity, whereas drag was sensitive to both variation in wing tip velocity and angle of attack. Bees utilized kinematic patterns that did not maximize lift production but rather maintained lift-to-drag ratio. Thus, our data indicate that, at least for honeybees, the overall time course of wing angles is generally preserved and modulation of wing tip velocity is sufficient to perform a diverse set of vertical flight behaviors.

Published

2014

46. Reverse Engineering Animal Vision with Virtual Reality and Genetics

Author

John R. Stowers, Maximilian Hofbauer, Axel Schmid, Anton Fuhrmann, Michael H. Dickinson, Martin Streinzer, and Andrew Straw

Subjects

0106 biological sciences, Reverse engineering, 0303 health sciences, General Computer Science, Multimedia, Process (engineering), Computer science, Virtual reality, Computer-mediated reality, computer.software_genre, 010603 evolutionary biology, 01 natural sciences, Visualization, 03 medical and health sciences, Human–computer interaction, Augmented reality, computer, 030304 developmental biology

Abstract

Neuroscientists are using virtual reality systems, combined with other advances such as new molecular genetic tools and brain-recording technologies, to reveal how neuronal circuits process and act on visual information. The Web extra at http://youtu.be/e_BxdbNidyQ is an overview video showing the FlyVR system in operation, including four example experiments.

Published

2014

47. Central complex neurons exhibit behaviorally gated responses to visual motion inDrosophila

Author

Bettina Schnell, Peter T. Weir, and Michael H. Dickinson

Subjects

Physiology, Action Potentials, Context (language use), Sensory system, Optic Flow, Retina, Motion (physics), Calcium imaging, medicine, Animals, Set (psychology), Neurons, Communication, biology, business.industry, General Neuroscience, Sensory Gating, biology.organism_classification, Visual motion, Ganglia, Invertebrate, Drosophila melanogaster, medicine.anatomical_structure, Evoked Potentials, Visual, Calcium, business, Neuroscience, Locomotion

Abstract

Sensory systems provide abundant information about the environment surrounding an animal, but only a small fraction of that information is relevant for any given task. One example of this requirement for context-dependent filtering of a sensory stream is the role that optic flow plays in guiding locomotion. Flying animals, which do not have access to a direct measure of ground speed, rely on optic flow to regulate their forward velocity. This observation suggests that progressive optic flow, the pattern of front-to-back motion on the retina created by forward motion, should be especially salient to an animal while it is in flight, but less important while it is standing still. We recorded the activity of cells in the central complex of Drosophila melanogaster during quiescence and tethered flight using both calcium imaging and whole cell patch-clamp techniques. We observed a genetically identified set of neurons in the fan-shaped body that are unresponsive to visual motion while the animal is quiescent. During flight their baseline activity increases, and they respond to front-to-back motion with changes relative to this baseline. The results provide an example of how nervous systems selectively respond to complex sensory stimuli depending on the current behavioral state of the animal.

Published

2014

48. Flies Regulate Wing Motion via Active Control of a Dual-Function Gyroscope

Author

Alysha M. de Souza, B. H. Dickerson, Michael H. Dickinson, and Ainul Huda

Subjects

0301 basic medicine, animal structures, Motion (geometry), Biology, Rotation, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Motion, 03 medical and health sciences, 0302 clinical medicine, Control theory, law, Animals, Wings, Animal, Dual function, Wing, Gyroscope, Active control, Biomechanical Phenomena, Drosophila melanogaster, 030104 developmental biology, Flight, Animal, Control system, Halteres, Female, General Agricultural and Biological Sciences, Mechanoreceptors, 030217 neurology & neurosurgery

Abstract

Flies execute their remarkable aerial maneuvers using a set of wing steering muscles, which are activated at specific phases of the stroke cycle [1, 2, 3]. The activation phase of these muscles—which determines their biomechanical output [4, 5, 6]—arises via feedback from mechanoreceptors at the base of the wings and structures unique to flies called halteres [7, 8, 9]. Evolved from the hindwings, the tiny halteres oscillate at the same frequency as the wings, although they serve no aerodynamic function [10] and are thought to act as gyroscopes [10, 11, 12, 13, 14, 15]. Like the wings, halteres possess minute control muscles whose activity is modified by descending visual input [16], raising the possibility that flies control wing motion by adjusting the motor output of their halteres, although this hypothesis has never been directly tested. Here, using genetic techniques possible in Drosophila melanogaster, we tested the hypothesis that visual input during flight modulates haltere muscle activity and that this, in turn, alters the mechanosensory feedback that regulates the wing steering muscles. Our results suggest that rather than acting solely as a gyroscope to detect body rotation, halteres also function as an adjustable clock to set the spike timing of wing motor neurons, a specialized capability that evolved from the generic flight circuitry of their four-winged ancestors. In addition to demonstrating how the efferent control loop of a sensory structure regulates wing motion, our results provide insight into the selective scenario that gave rise to the evolution of halteres.

Published

2019

49. The Function and Organization of the Motor System Controlling Flight Maneuvers in Flies

Author

Theodore H. Lindsay, Michael H. Dickinson, and Anne Sustar

Subjects

0301 basic medicine, Functional features, media_common.quotation_subject, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Motion, 0302 clinical medicine, Control theory, Motor system, Animals, Wings, Animal, Function (engineering), media_common, Wing, Muscles, Motor control, Visual motion, Biomechanical Phenomena, 030104 developmental biology, Flight, Animal, Calcium, Drosophila, Female, General Agricultural and Biological Sciences, Actuator, 030217 neurology & neurosurgery

Abstract

Animals face the daunting task of controlling their limbs using a small set of highly constrained actuators. This problem is particularly demanding for insects such as Drosophila, which must adjust wing motion for both quick voluntary maneuvers and slow compensatory reflexes using only a dozen pairs of muscles. To identify strategies by which animals execute precise actions using sparse motor networks, we imaged the activity of a complete ensemble of wing control muscles in intact, flying flies. Our experiments uncovered a remarkably efficient logic in which each of the four skeletal elements at the base of the wing are equipped with both large phasically active muscles capable of executing large changes and smaller tonically active muscles specialized for continuous fine-scaled adjustments. Based on the responses to a broad panel of visual motion stimuli, we have developed a model by which the motor array regulates aerodynamically functional features of wing motion. VIDEO ABSTRACT.

Published

2016

50. An Array of Descending Visual Interneurons Encoding Self-Motion in Drosophila

Author

Michael H. Dickinson, Marie P. Suver, Steve Safarik, Nicole A. Iwasaki, and Ainul Huda

Subjects

0301 basic medicine, genetic structures, Interneuron, Journal Club, Sensory system, Discrete set, Biology, Efferent Pathways, 03 medical and health sciences, Interneurons, Encoding (memory), Orientation, Motor system, medicine, Self motion, Animals, Visual Pathways, General Neuroscience, fungi, Physiological responses, 030104 developmental biology, medicine.anatomical_structure, Ventral nerve cord, Flight, Animal, Visual Perception, Drosophila, Neuroscience, Psychomotor Performance

Abstract

The means by which brains transform sensory information into coherent motor actions is poorly understood. In flies, a relatively small set of descending interneurons are responsible for conveying sensory information and higher-order commands from the brain to motor circuits in the ventral nerve cord. Here, we describe three pairs of genetically identified descending interneurons that integrate information from wide-field visual interneurons and project directly to motor centers controlling flight behavior. We measured the physiological responses of these three cells during flight and found that they respond maximally to visual movement corresponding to rotation around three distinct body axes. After characterizing the tuning properties of an array of nine putative upstream visual interneurons, we show that simple linear combinations of their outputs can predict the responses of the three descending cells. Last, we developed a machine vision-tracking system that allows us to monitor multiple motor systems simultaneously and found that each visual descending interneuron class is correlated with a discrete set of motor programs.SIGNIFICANCE STATEMENTMost animals possess specialized sensory systems for encoding body rotation, which they use for stabilizing posture and regulating motor actions. In flies and other insects, the visual system contains an array of specialized neurons that integrate local optic flow to estimate body rotation during locomotion. However, the manner in which the output of these cells is transformed by the downstream neurons that innervate motor centers is poorly understood. We have identified a set of three visual descending neurons that integrate the output of nine large-field visual interneurons and project directly to flight motor centers. Our results provide new insight into how the sensory information that encodes body motion is transformed into a code that is appropriate for motor actions.

Published

2016