The Role of Even-Skipped in Drosophila Larval Somatosensory Circuit Assembly

In embryos, eve expression is required for proper medial-lateral and anterior-posterior neurite positioning of EL interneurons. A–C, Images and quantification of stage 15 embryos with EL interneurons extending axons across the midline. A, B, In control and EL eve mutants, ELs extend across the midline. Two abdominal segments are shown with midline noted as an arrowhead. Anterior is up and scale bars are 10 μm. Below each image is an illustration of the phenotype. C, For this quantification, n = number of hemisegments with EL processes crossing the midline over the total number of hemisegments scored. D–F, Images and quantification of stage 16 embryos with defects in medial-lateral positioning of EL neurites in EL eve mutants. D, In control, ELs project toward the anterior mainly along the intermediate fascicle. E, In EL eve mutants, ELs project in additional fascicles (arrows; L = lateral fascicle, I = intermediate, M = medial). F, For this quantification, n = number of hemisegments scored. G–I, Images and quantification of stage 17 embryos, with defects in anterior-posterior positioning of EL neurites in EL eve mutants. G, In control, ELs extend neurites to the next anterior segment. H, In EL eve mutants, neurites do not extend to the next segment (arrow). I, For this quantification, n = number of hemisegments with processes reaching the next segment over the total number of hemisegments scored; chi-squared test, ****p < 0.0001. Genotypes: control 1 is EL-GAL4/UAS-myr-GFP; control 2 is UAS-FLP, act5C-FRT.stop-GAL4;;EL-GAL4/UAS-myr-GFP. EL eve mutant (1) is UAS-FLP, act5C-FRT.stop-GAL4; ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; EL-GAL4/UAS-myr-GFP.

In larvae, Eve(–) ELs have excessive branching off the main neurite and diminished axon extension. A, Quantification of labeled neurons. In all genotypes, the most numerous type of singly-labeled neurons are local, late-born ELs. n = total number of singly-labeled neurons for each genotype. B, C, Images of singly-labeled ELs. Drosophila neurons are pseudo-unipolar. B, In control, dendrites are located ipsilateral to the soma. On the contralateral side, axons turn to the anterior and form branches where output synapses are found (Heckscher et al., 2015). C, In EL eve mutants, there is excessive branching off the main neurite (arrowheads), and the axon is less extended (arrow). Anterior is up with a scale bar of 5 μm. Dashed line indicates midline. D–G, Quantifications of neuron morphology. For each plot, the x-axis is the radius of a concentric circle centered on the EL soma. The y-axis is number of times a singly-labeled EL intersects a circle. Median (dark line) and range (lighter bars) are shown. F, Control is black; red and orange lines are EL eve mutants (1) and (2), respectively. Wilcoxon test, ***p < 0.0001. Genotypes: control is 11F02-GAL4/UAS-MCFO. EL eve mutant (1) is ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; 11F02-GAL4/UAS-MCFO. EL eve mutant (2) is ΔEL, Df(2R)eve/ΔEL, eve(3); 11F02-GAL4/UAS-MCFO.

Eve(–) ELs have mispositioned dorsal-ventral dendrites. A, B, Images of singly-labeled ELs in side view. A, In control, ELs have ipsilateral dendrites that project dorsally. B, In EL eve mutants, many branches project ventrally. These are the same neurons as in Figure 3B,C, except here dorsal is up. C, D, Quantification of dendrite orientation. The number of branches pointing dorsally or ventrally is plotted with each dot representing a single neuron. Bars show average, and whiskers show standard deviation. ANOVA with Dunnett’s multiple comparison; *p < 0.05 and ****p < 0.0001.

Eve(–) ELs do not derepress molecular markers. A–D, Images of marker gene expression in ELs. A, C, In control, ELs lack expression of ventral motor neuron maker, HB9 (A’) and an interneuron marker En (A’’). ELs express both Eagle (C’) and Collier (C’’). B, D, In EL eve mutants, there is no change in marker gene expression. Representative segments of stage 16 embryos. Anterior is up with a scale bar of 5 μm. Arrowhead shows midline. Area containing EL neurons is circled. n = number of hemisegments scored. Each row shows separate image channels of the same co-stained stained embryo. Genotypes: control is wild-type and EL eve mutant(1) is ΔEL, Df(2R)eve/ΔEL, Df(2R)eve.

In EL eve mutants, there are no changes in sensory neurons axonal trajectories. A, B, Illustration of sensory inputs onto ELs. A, Late-born ELs get direct input from proprioceptors and indirect input via the Jaam CNS interneurons. B, Early-born ELs get direct input from mechanoreceptors (chordotonals) and indirect input via the Basin CNS interneurons. C–F, Illustrations of sensory neuron-to-interneuron wiring in different genetic conditions. C, In wild-type, sensory neuron axons (green) and interneuron dendrites (blue) are in close enough proximity they can form synaptic contacts. D, When sensory neuron axons are genetically mispositioned, interneurons grow in response, and the two cell types continue to form synaptic contacts. E, F, When EL interneuron dendrites are mispositioned because of lack of Eve, sensory neurons might or might not change position in response. G, H, Images of vibration and proprioceptive sensory neurons arbors. G, H, Axonal positions are similar in control and EL eve mutants for both vibration sensitive and proprioceptive sensory neurons. Single hemisegments of an L1 larval CNS are shown with dorsal up. Eve-expressing motor neurons are shown as solid circles with a diameter of five microns. Positions of Fas2(+) fascicles are shown as dashed circles. To the left of each image is a schematic of the axon position relative to landmarks. n = the number of hemisegments scored. Genotypes: control in G is iav-GAL4/UAS-myr-GFP. EL eve mutant in G is ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; iav-GAL4/UAS-myr-GFP. Control in H is 0165-GAL4/UAS-myr-GFP. EL eve mutant in H is ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; 0165-GAL4/UAS-myr-GFP.

EL interneurons require eve expression to encode somatosensory stimuli. A, Illustration of the semi-restrained preparation and stimulus protocol. Fluorescence in the CNS (gray lobed structure with two white lines representing neuropil) is recorded before, during, and after a sound is played from a speaker. B, C, Quantifications of EL calcium signals. B, In control, EL have small amplitude, dynamic calcium signals before sound onset, which corresponds to periods of self-movement. There are large amplitude changes in EL calcium signal on sound/vibration stimuli. ΔF/F is the change in fluorescence over baseline. C, In EL eve mutants, ELs do not respond to stimuli. Averages (dark line) and SEM (light line) are shown. Scale for both is shown as an inset. n = number of larvae recorded. D, E, Images from representative recordings of calcium signals in ELs. Fluorescence images are shown in pseudo-color with white/red as high fluorescence intensity and blue as low. Anterior is up with a scale bar of 100 μm. Dashed lines show the outline of the nerve cord. In D, asterisk denotes region of nerve cord neuropile (central region) with increased fluorescence. In E, > points to mouth hooks. Genotypes: control is UAS-FLP, act5C-FRT.stop-GAL4; ΔEL, Df(2R)eve/+; EL-GAL4/UAS-GCaMP6m. EL eve mutant is UAS-FLP, act5C-FRT.stop-GAL4; ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; EL-GAL4/UAS-GCaMP6m.

In Eve(–) ELs, output synapses are anatomically repositioned. A, B, Images of tagged presynaptic active zones. Eve labels ELs (“ELs” in A) but not in EL eve mutants (* in B). A’, In control, labeled active zones (BRP) are clustered around the central intermediate Fas2(+) fascicles (CI). B’, In EL eve mutants, BRP signal is diffuse throughout the entire neuropile. A–A’’ are the same CNS and B–B’’ are the same CNS. A’’, B’’ are a magnifications of the neuropile from one hemisegment in A’ or B’, respectively. Images are overlaid with lines showing medial (M), intermediate (I), and lateral (L) zones. Images show the CNS in cross section with dorsal up. Arrow denotes midline. Neuropile is outlined by a dashed circle. Scale bar: 10 μm. C, D, Quantifications of BRP signal distribution. n = number of hemisegments with BRP signal above background within a given region/total number of hemisegments scored. Zones scored were medial (M), intermediate (I), and lateral (L) as shown in A’’, B’’. Genotype: control is UAS-FLP, act5C-FRT.stop-GAL4; ΔEL, Df(2R)eve/+; EL-GAL4/UAS-FLP, BRP-frt-stop-frt-V5-2A-LexA. EL eve mutant is UAS-FLP, act5C-FRT.stop-GAL4; ΔEL, Df(2R)eve/ΔEL, Df(2R)eve; EL-GAL4/UAS-FLP, BRP-frt-stop-frt-V5-2A-LexA.

In EL eve mutants, there are defects in spontaneously-occurring crawling behavior. A–C, Images and quantification of larva crawling. A, B, Images of control and EL eve mutants during forward crawling. Images are frames (0.66-s intervals) from representative behavioral recordings. Anterior is up and scale bar is 150 μm. C. Quantification of crawling speed is calculated as centroid movement over time. Each dot represents the average data for one larva. Bars represent average of all data points, and whiskers show SEM. One-way ANOVA with Dunnett’s multiple comparison; **p < 0.01, ****p < 0.0001. D–F, Images of left-right asymmetrical body posture. D, In control, larvae crawl left-right symmetrically. E, When ELs are genetically ablated during embryogenesis, larvae crawl with left-right asymmetrical body posture. F, In EL eve mutants, when Eve is removed from ELs, but the EL neurons remain, larvae crawl with a significantly severe left-right asymmetrical body posture. Images are single representative frames from behavioral recordings showing body shape with anterior up and scale bar of 40 μm. F is overlaid to show how angles are calculated. G, H, Quantification of left-right body asymmetry. Asymmetry is measured as tail-to-centroid and head-to-centroid angles during crawling. Each dot represents the average data for one larva. Data for No ELs replotted from Heckscher et al. (2015), with permission. Bars represent average of all data points, and whiskers show SEM ANOVA with Dunnett’s multiple comparison test; **p < 0.01, Genotypes: Control is wildtype (+/+); no EL is UAS-RPR, UAS-HID/+;; EL-GAL4/+; refer to Figure 1D for naming of mutant allele genotypes used in this experiment.