The manifold structure of limb coordination in walking Drosophila

DeAngelis, Brian D; Zavatone-Veth, Jacob A.; Clark, Damon A.

doi:10.7554/elife.46409

Cited by 110 publications

(180 citation statements)

References 108 publications

(195 reference statements)

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“…Eventually, mirror image patterns are possible with phase coupling among contralateral legs deviating from phase values of 0.5. Patterns recently described as non-canonical by DeAngelis et al (2019) can be observed, too (e.g. Fig 3C).…”

Section: Discussionmentioning

confidence: 52%

“…As has been shown neuroWalknet is able to produce footfall patterns that include "tripod" patterns, "tetrapod" patterns, "pentapod" patterns as well as various stable intermediate patterns. These patterns form a continuous multitude as has been observed in stick insects (Graham 1972) and in Drosophila (Wosnitza et al 2013;DeAngelis et al 2019) and to some extent in cockroaches (e.g. Hughes 1952;Bender et al 2011).…”

Section: Discussionmentioning

confidence: 67%

“…This suggests that there is a continuum of intermediate stable stepping patterns observed in probably all insects, at least in cockroaches and in stick insects, both representing the group of hemimetabolic insects, as well as in Drosophila (Wosnitza et al 2013), representing a holometabolic insect. Recently, this view has been strongly supported by an excellent study of DeAngelis et al (2019).…”

Section: A Continuum Of Walking Behaviormentioning

confidence: 88%

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Decentralized Control of Insect Walking – a simple neural network explains a wide range of behavioral and neurophysiological results

Schilling

Cruse

2019

Preprint

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AbstractControl of walking with six or more legs in an unpredictable environment is a challenging task, as many degrees of freedom have to be coordinated. Generally, solutions are proposed that rely on (sensory-modulated) CPGs, mainly based on data from neurophysiological studies. Here, we are introducing a sensor based controller operating on artificial neurons, being applied to a (simulated) hexapod robot with a morphology adapted to Carausius morosus. We show that such a decentralized solution leads to adaptive behavior when facing uncertain environments which we demonstrate for a large range of behaviors – slow and fast walking, forward and backward walking, negotiation of curves and walking on a treadmill with various treatment of individual legs. This approach can as well account for these neurophysiological results without relying on explicit CPG-like structures, but can be complemented with these for very fast walking.

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Section: Discussionmentioning

confidence: 52%

Section: Discussionmentioning

confidence: 67%

Section: A Continuum Of Walking Behaviormentioning

confidence: 88%

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Decentralized Control of Insect Walking – a simple neural network explains a wide range of behavioral and neurophysiological results

Schilling

Cruse

2019

Preprint

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“…Critically, high resolution analyses of walking gait in freely walking flies revealed that BPN-TeTx flies were not uncoordinated ( Figure S7) but instead walked slowly as a result of an increased step period, specifically due to an increased stance duration ( Figure 7E). Previous work has shown that flies typically vary walking speed by varying stance duration (DeAngelis et al, 2019;Wosnitza et al, 2013). Therefore, the gait of BPN silenced flies resembles that of slow walking flies.…”

Section: Bpn Activity Reciprocally Regulates Straight Forward Walkingmentioning

confidence: 97%

Two brain pathways initiate distinct forward walking programs inDrosophila

Bidaye¹,

Laturney²,

Chang³

et al. 2019

Preprint

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An animal at rest or engaged in stationary behaviors can instantaneously initiate goaldirected walking. How descending brain inputs trigger rapid transitions from a non-walking state to an appropriate walking state is unclear. Here, we identify two specific neuronal classes in the Drosophila brain that drive two distinct forward walking programs in a context-specific manner.The first class, named P9, consists of descending neurons that drive forward walking with ipsilateral turning. P9 receives inputs from central courtship-promoting neurons and visual projection neurons and is necessary for a male to track a female during courtship. The second class comprises novel, higher order neurons, named BPN, that drives straight, forward walking. BPN is required for high velocity walking and is active during long, fast, straight walking bouts. Thus, this study reveals separate brain pathways for object-directed steering and fast straight walking, providing insight into how the brain initiates different walking programs.Raw and processed data along with custom Matlab analysis scripts will be made available upon request. Design files for custom parts will be available upon request.Ache, J.M., Haupt, S.S., and Dürr, V. (2015). A direct descending pathway informing locomotor networks about tactile sensor movement.

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“…Here, we use in vivo calcium imaging, whole-cell patch clamp electrophysiology, and optogenetics during walking behavior to investigate motor control of the Drosophila tibia (Figure 1A). The femur-tibia joint of a walking fly flexes and extends 10-20 times per second, reaching swing speeds of several thousand degrees per second (DeAngelis et al, 2019;Gowda et al, 2018;Mendes et al, 2013;Strauss and Heisenberg, 1990;Wosnitza et al, 2013). Flies also use their legs to target other body parts during grooming (Hampel et al, 2015;Seeds et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

A size principle for leg motor control inDrosophila

Azevedo

Dickinson

Gurung

et al. 2019

Preprint

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To move the body, the brain must precisely coordinate patterns of activity among diverse populations of motor neurons. In many species, including vertebrates, the motor neurons innervating a given muscle fire in a specific order that is determined by a gradient of cellular size and electrical excitability. This hierarchy allows premotor circuits to recruit motor neurons of increasing force capacity in a task-dependent manner. However, it remains unclear whether such a size principle also applies to species with more compact motor systems, such as the fruit fly, Drosophila melanogaster, which has just 53 motor neurons per leg. Using in vivo calcium imaging and electrophysiology, we found that genetically-identified motor neurons controlling flexion of the fly tibia exhibit a gradient of anatomical, physiological, and functional properties consistent with the size principle. Large, fast motor neurons control high force, ballistic movements while small, slow motor neurons control low force, postural movements. Intermediate neurons fall between these two extremes. In behaving flies, motor neurons are recruited in order from slow to fast. This hierarchical organization suggests that slow and fast motor neurons control distinct motor regimes. Indeed, we find that optogenetic manipulation of each motor neuron type has distinct effects on the behavior of walking flies.

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The manifold structure of limb coordination in walking Drosophila

Cited by 110 publications

References 108 publications

Decentralized Control of Insect Walking – a simple neural network explains a wide range of behavioral and neurophysiological results

Decentralized Control of Insect Walking – a simple neural network explains a wide range of behavioral and neurophysiological results

Two brain pathways initiate distinct forward walking programs inDrosophila

A size principle for leg motor control inDrosophila

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