The Fruit Fly, Drosophila, as a Tool to Unravel Locomotor Circuits

Editorial

29 August 2023

Editorial: The fruit fly, Drosophila, as a tool to unravel locomotor circuits

Wolfgang Stein

3,808 views

0 citations

Editors

Wolfgang Stein

Illinois State University

Tomoko Ohyama

McGill University

Impact

The neuromuscular system of fly larvae. (A) A side view photo of a third instar larva. (B) GFP-labeled body-wall muscles in a third instar larva. (C) A schematic of the larval motor system. Motor neurons (magenta) locate in the CNS and innervate body-wall muscles. The segmental layout of the larval CNS from the lateral (D) and dorsal (E) view. (F) Motor neurons and muscles in a hemisegment. Cyan boxes present longitudinal muscles, and yellow boxes present transverse muscles. Blue neurons (L-MN: motor neurons targeting longitudinal muscles) innervate longitudinal muscles. Orange neurons innervate transverse muscles (T-MN: motor neurons targeting transverse muscles). Discs in the VNC indicate the cell body of motor neurons, and sprayed regions indicate the dendritic regions of motor neurons. The demarcation of dendrites between L-MN and T-MN exhibits the myotopic map. (G) Neurons involved in motor control. Tn, the n-th thoracic segment; An, the n-th abdominal segment; TM, transverse muscles; LM, longitudinal muscles; CNS, the central nervous system; SEZ, the subesophageal zone; VNC, the ventral nerve cord; A, anterior; P, posterior; D, dorsal; V, ventral; R, right; L, left; L-MN, motor neurons targeting longitudinal muscles; T-MN, motor neurons innervating transverse muscles; SB, segment boundary; AC, anterior commissure; PC, posterior commissure; SN, sensory neuron; IN, interneuron. Source images of (A) and (B): Kohsaka et al., 2019.

Review

17 August 2023

Linking neural circuits to the mechanics of animal behavior in Drosophila larval locomotion

Hiroshi Kohsaka

5,827 views

5 citations

First abdominal segment proprioceptor output synapses are distributed along the proximal and distal axon. (A) Diagrams of larval body plan, of proprioceptive neuron somata and dendrites at the larval body wall (adapted from Cheng et al., 2010; Vaadia et al., 2019), and of views of the larval CNS. The same six proprioceptive neurons are present in each abdominal hemisegment (here, A1 left). They project to neuropil segment A1 in the CNS, highlighted in pink. (B) Transverse view of reconstructed skeletons (axonal projections) in A1 of the larval connectome: proprioceptive neurons (blue), chordotonal neurons (gray), and class IV multidendritic neurons (black). Dashed pink lines demarcate the “central domain” of proprioceptive outputs. Dashed gray line: midline. (C) Three views of output synapses in the CNS made by each left side proprioceptor. Gray lines: neuron skeletons. Spheres: output synapse locations. Top subpanels: left side views; middle subpanels: top-down views; bottom-subpanels: transverse views, looking from the tail toward the head. Gray mesh: outline of larval CNS. Pink mesh: outline of A1 left side region of neuropil. (D) Distribution of output synapses along the mediolateral axis for left side A1 neurons shown in (C). Proportion of that neuron’s outputs made in 1 μm bins along the X-axis of the connectome. Views in (B,C) generated using CATMAID (Saalfeld et al., 2009). In (A): scale bars = 50 μm; (B,C): scale bars = 10 μm; scale bars equal for all axes. Throughout, dashed vertical lines: midline. D, dorsal; V, ventral; A, anterior; P, posterior; L, left side; T3, A1, A2, body segment abbreviations.

Original Research

26 July 2023

Distinctive features of the central synaptic organization of Drosophila larval proprioceptors

Marie R. Greaney

, 1 more and

Ellie S. Heckscher

7,032 views

1 citations

Loss of ARCA-associated DNA repair gene expression affects motor behaviors. (A) Total distance moved and (B) speed while moving in open field arena. Data is normalized against appropriate genetic background control (RNAi/Control). (C) Area Under the Curve for % of flies that remained on the platform during 10 s of island assay performance. Data is normalized against the appropriate control condition (RNAi/Control). (D) Displays normalized activity counts as measured with the DAM system, data normalized against control condition for Light Period (LP) and Dark Period (DP) (RNAi/Control) in the respective period. ***p < 0.001, **p < 0.01, and *p < 0.05. Age of flies: 4 days old. For information on genotypes, and n see section “2. Materials and methods”.

Original Research

05 July 2023

Ataxia-associated DNA repair genes protect the Drosophila mushroom body and locomotor function against glutamate signaling-associated damage

Ilse Eidhof

, 2 more and

Annette Schenck

5,031 views

0 citations

Review

01 July 2021

The Drosophila Larval Locomotor Circuit Provides a Model to Understand Neural Circuit Development and Function

Iain Hunter

, 2 more and

Richard A. Baines

It is difficult to answer important questions in neuroscience, such as: “how do neural circuits generate behaviour?,” because research is limited by the complexity and inaccessibility of the mammalian nervous system. Invertebrate model organisms offer simpler networks that are easier to manipulate. As a result, much of what we know about the development of neural circuits is derived from work in crustaceans, nematode worms and arguably most of all, the fruit fly, Drosophila melanogaster. This review aims to demonstrate the utility of the Drosophila larval locomotor network as a model circuit, to those who do not usually use the fly in their work. This utility is explored first by discussion of the relatively complete connectome associated with one identified interneuron of the locomotor circuit, A27h, and relating it to similar circuits in mammals. Next, it is developed by examining its application to study two important areas of neuroscience research: critical periods of development and interindividual variability in neural circuits. In summary, this article highlights the potential to use the larval locomotor network as a “generic” model circuit, to provide insight into mammalian circuit development and function.

10,051 views

22 citations

Misinnervation of leg muscles strongly alters walking behaviour. (A) Scheme of leg print assay. Arrow marks a leg print. (B) Scheme of stereotyped foot print patterns (colour-coded, e.g., R1 = right prothoracic leg, green). Dotted line indicates body midline. Stippled double-headed arrow (magenta), step length of mesothoracic leg. Black double-headed arrow, length of metathoracic tarsus print. (C–J) Bright-field images of tarsus prints on carbon soot-coated glass slides. (C) Leg print pattern of ShGFP control flies. Prints of right legs are labelled from medial to lateral: R1, R3, and R2. (D,E) Side mutant walking phenotypes vary from dragging R3 at an unusual inner-most position (weak phenotype, arrow in D) to being completely unable to walk (strong phenotype, E). (F,G) Overexpressing Side flies show some minor stumble (weak phenotype, arrow in F) or more obvious dragging phenotypes (strong phenotype, arrow in G). (H) Downregulation of Side using RNAi driven by Mef2-Gal4 results in no obvious phenotypes. (I,J) Enhancing RNAi by Dicer leads to clearly visible prolonged prints of the third leg (J). (K,L) Statistical analysis of leg print assays. (K) Approximately 30% of side mutants (n = 29) are not able to walk across the glass slide. Both loss and gain of Side function as well the downregulation of Side result in various percentages, in altered successions in the T1-T3-T2 print pattern. (L) Overexpressing Side flies exhibit a shortened step length of the mesothoracic legs (T2-T2), while downregulation of Side using RNAi results in an increased step length compared to controls. (M) Results of the climbing assay. Downregulation, loss, or gain of Side leads to a reduced climbing ability of adult flies compared to controls. Data are total number (K) or means ± SD (L+M), Fisher exact test (K), one-way ANOVA (L+M): ***P < 0.001, **P < 0.01, *P < 0.5; ns, not significant; n, number of males. Genotypes: w;+;ShGFP, w;+;sideC137, ShGFP/sideI1563, ShGFP, w;+;Mef2-Gal4, ShGFP/UAS-Side29A, w;UAS-Side-RNAi/+;Mef2-Gal4/+;w;UAS-Side-RNAi/+;Mef2-Gal4/UAS-Dicer.

Original Research

03 June 2021

Misregulation of Drosophila Sidestep Leads to Uncontrolled Wiring of the Adult Neuromuscular System and Severe Locomotion Defects

Jaqueline C. Kinold

, 1 more and

Hermann Aberle

5,835 views

3 citations