Here we describe a protocol to visualize the axonal targeting with a florescent protein in adult legs of Drosophila by fixation, mounting, imaging, and post-imaging steps.
The majority of work on the neuronal specification has been carried out in genetically and physiologically tractable models such as C. elegans, Drosophila larvae, and fish, which all engage in undulatory movements (like crawling or swimming) as their primary mode of locomotion. However, a more sophisticated understanding of the individual motor neuron (MN) specification—at least in terms of informing disease therapies—demands an equally tractable system that better models the complex appendage-based locomotion schemes of vertebrates. The adult Drosophila locomotor system in charge of walking meets all of these criteria with ease, since in this model it is possible to study the specification of a small number of easily distinguished leg MNs (approximately 50 MNs per leg) both using a vast array of powerful genetic tools, and in the physiological context of an appendage-based locomotion scheme. Here we describe a protocol to visualize the leg muscle innervation in an adult fly.
Like the vertebrate limb, the Drosophila adult leg is organized into segments. Each fly leg contains 14 muscles, each of which comprises multiple muscle fibers1,2. The cell bodies of the adult leg MNs are located in the T1 (prothoracic), T2 (mesothoracic), and T3 (metathoracic) ganglia on each side of the ventral nerve cord (VNC), a structural analogous to the vertebrate spinal cord (Figure 1). There are approximately 50 MNs in each ganglia, which target muscles in four segments of the ipsilateral leg (coxa, trochanter, femur, and tibia) (Figure 1)3. Importantly, each individual adult leg MN has a unique morphological identity that is highly stereotyped between animals3,4. All these unique MNs are derived from 11 stem cells, called neuroblasts (NBs) producing leg MNs during the larval stages3,4. At the end of the larval stages all the immature postmitotic MNs differentiate during metamorphosis to acquire their specific dendritic arbors and axonal terminal targets that define their unique morphology3,4. Previously we tested the hypothesis that a combinatorial code of transcription factors (TFs) specifies the unique morphology of each Drosophila adult leg MN5. As a model, we used lineage B, one of the 11 NB lineages which produces seven out of the MNs and demonstrated that a combinatorial code of TFs expressed in postmitotic adult leg MNs dictates their individual morphologies. By reprograming the TF code of MNs we have been able to switch MN morphologies in a predictable manner. We call these TFs: mTFs (morphological TFs)5.
One of the most challenging parts of the morphological analyses of adult MNs is to visualize the axons through a thick and auto-fluorescent cuticle with high resolution. We usually label axons with a membrane-tagged GFP that is expressed in MNs with a binary expression system, such as DVglut-Gal4/UAS-mCD8::GFP or DVglut-QF/ QUAS mCD8::GFP, where DVglut is a strong driver expressed in motoneurons6. By combining these tools with other clonal techniques such as mosaic analysis with a repressible marker (MARCM)7, cis-MARCM8, or MARCMbow5, we can restrict the GFP expression to subpopulations of MNs making the phenotypic analysis of axons easier. We have generated a protocol in order to keep leg MN axonal morphology intact for imaging and subsequent 3D reconstruction by addressing specific issues intrinsic to the adult Drosophila leg such as (1) fixation of the internal structures of the adult leg without affecting axon morphology, endogenous fluorescent expression, and leg musculature, (2) mounting of the leg to preserve the overall structure under a coverslip and in the appropriate orientation for imaging, and (3) image processing to obtain the cuticle background as well as axonal fluorescent signal. While this protocol has been detailed for the detection of fluorescent expression in MN axons, it can be applied to visualize other components of leg neuromusculature in arthropods.
1. Leg Dissection and Fixation
2. Leg Mounting
3. Imaging
4. Post Imaging Processing
As shown in Figure 4, this procedure allows excellent imaging of GFP-labeled axons in adult Drosophila legs, together with their terminal arbors. Importantly a clean GFP signal is obtained without any contamination from the fluorescence emitted by the leg cuticle. The signal from the cuticle can then be combined with the GFP signal to identify the positioning of axons in the legs (Figure 4E, Figure 1,and Video 1). Critically, it is important to obtain well-fixed legs. Figure 5 shows examples of a well-fixed (Figure 5A) and a badly-fixed leg (Figure 5B). In the former case the internal structures inside the legs are of a uniform color and the tracheas, which are dark, are visible. A main tracheal tube runs in the center of each leg segment (adjacent to the main nerve trunk) and many thinner ramifications are also visible. In the latter, dark material is present in the tarsus and tibia and the tracheal system is not clearly visible in the femur and coxa: in such cases it is always observed that the signal from fluorescent proteins is degraded being of low intensity or absent altogether. Second, careful dissection of the legs is necessary to obtain all the leg segments (from coxa to tibia) and to avoid mechanical shock to the legs. Third, the legs must be left in mounting medium long enough for it to penetrate the inside of the legs. Sometimes leg segments, especially the femur, appear collapsed — this can be due to lack of penetration of the fixative and/or mounting medium. Finally, one must use high quality microscope objectives, corrected for flatness of field and specially designed for fluorescence and/or apochromatic.
Figure 1: Schema of the adult Drosophila leg motor system. The cell bodies of the adult leg MNs (green) are localized in the cortex (grey) of the thoracic ganglion of the VNC. MNs arborize their dendrites in the leg neuropil (blue) and send their axons into the leg to innervate one of the 14 leg muscles (red). Note that only the T1 legs are schematized. Please click here to view a larger version of this figure.
Figure 2: Procedure to mount legs on microscope slides. Please click here to view a larger version of this figure.
Figure 3: Imaging procedure. (A) Emission spectra of GFP and of leg cuticle using 488 nm Argon laser excitation, obtained using spectral imaging of sections of legs expressing GFP and of legs of Drosophila that do not express GFP respectively. Note that the fluorescence intensities have not been normalized, e.g., are from raw data using the same parameters (objective, mounting medium, laser power, confocal aperture, gain, offset) as for the leg imaging procedure. Also shown are the detector windows used for imaging the GFP + cuticle fluorescence (detector 1: green) and cuticle (detector 2: pink), based on the GFP vs cuticle background spectra. (B, C) Confocal section of legs labeled with mCD8::GFP under the control of DVGlut-Gal4 obtained from detector 1 (B) and detector 2 (C). (D, E) Saturation marker settings used to image (B, C) respectively (see text for explanation): blue no signal, red saturation. Note that on detector 1 the main nerve tracks are saturated, while on detector 2 some regions of the cuticle are saturated (see arrows). Scale bar = 100 µm. Please click here to view a larger version of this figure.
Figure 4: Processing of images using ImageJ/FIJI. (A) Max projection of the confocal stacks obtained from 498-535 nm detector. (B) Max projection of the confocal stack obtained from 566-652 nm detector. (C) Image with only GFP signal obtained by subtracting (A) from (B). (D) Merged images of (B) and (C). (E) 3-D reconstruction of (C). Scale bar = 100 µm. Please click here to view a larger version of this figure.
Figure 5: Low-power view of dissected legs showing examples of good (A) and bad (B) fixation. Scale bar = 200 µm. Please click here to view a larger version of this figure.
Video 1: Movie of GFP-labeled axons (green) together with cuticle (gray) of a leg. Please click here to view this video. (Right-click to download.)
The cuticle of adult Drosophila and of other arthropods, which contains many dark pigments, is a major obstacle for viewing structures inside their body. In addition, it is strongly auto fluorescent which is made worse by fixation. These two features are very problematic for observations of fluorescent dyes or molecules inside the body of animals with an exoskeleton.
The procedure that we have described and that we routinely use in the lab yields clean and detailed images of axon trajectories and of their terminal endings in adult Drosophila legs. Importantly a clean GFP signal is obtained without any contamination from the fluorescence emitted by the leg cuticle. This feature is mandatory in order to be able to visualize and quantitate three-dimensional features of axon arbors using 3D-imaging programs. In this way data obtained from several legs can be compared. The procedure is easily adapted for observing signals from other fluorescent proteins and could be easily used to image axons in other adult arthropods.
The two critical aspects of the procedure are i) to obtain a strong GFP signal, and ii) proper fixation of the legs. For the latter we routinely obtain good fixation, nevertheless some legs are occasionally not fixed properly. Therefore, the procedure needs to be improved, perhaps by adding agents that promote penetration of reagents (such as dimethylsulfoxide), or other means of fixation (microwave fixation, if it preserves GFP fluorescence), but we have not explored this possibility apart from using a preincubation step in PBS containing Triton (which significantly improved fixation). In order to get a good GFP signal we use a strong DVglut-Gal4 driver (also called OK371-Gal4). It is also necessary to use a good reporter – we use mCD8-GFP and have also obtained good signals with cytoplasmic GFP or mCherry. Regardless, we use reporters that contain several copies of the primary reporter (hexameric) and several copies of LexO or UAS sites.
A limitation of this procedure is that it applies only to fixed tissue. We are currently developing procedures for in vivo observations and are testing various alternatives (mounting and microscopes). One limitation using confocal microscopy is that it is difficult to view through the entire leg: this is because for signals from deep-lying areas the signal from GFP is scattered through the overlying tissue. Alternately a biphoton microscope allows imaging through the thickness of the entire leg.
Finally, other methods use different types of mounting and fixation4,12. The significance and strength of our procedure is that a subtraction step separating true GFP signal from other (mainly cuticular) signals allows excellent 3-dimensional reconstruction and visualization of axons and their terminal arbors.
The authors have nothing to disclose.
We thank Robert Renard for preparing fly food medium. This work was supported by an NIH grant NS070644 to R.S.M. and funding from the ALS Association (#256), FRM (#AJE20170537445) and ATIP-Avenir Program to J.E.
Ethanol absolute | Fisher | E/6550DF/17 | Absolute analytical reagent grade |
nonionic surfactant detergent | Sigma-Aldrich | T8787 | Triton X-100, for molecular biology |
Fine forceps | Sigma-Aldrich | F6521 | Jewelers forceps, Dumont No. 5 |
Glass multi-well plate | Electron Microscopy Sciences | 71563-01 | 9 cavity Pyrex, 100×85 mm |
PFA | Thermofisher | 28908 | Pierc 16% Formaldehyde (w/v), Methanol-free |
Glycerol | Fisher BioReagents | BP 229-1 | Glycerol (Molecular Biology) |
Spacers | Sun Jin Lab Co | IS006 | iSpacer, four wells, around 12 μL working volume per well, 7 mm diameter, 0.18 mm deep |
Square 22×22 mm coverslips | Fisher Scientific | FIS#12-541-B | No.1.5 -0.16 to 0.19mm thick |
Mounting Medium | Vector Laboratories | H-1000 | Vectashield Antifade Mounting Medium |
Confocal microscope | Carl Zeiss | LSM780; objective used LD LCI Plan-Apochromat 25x/0,8 Imm Korr DIC M27 (oil/ silicon/glycerol/water immersion) (420852-9871-000) |
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imaging software | Carl Zeiss | ZEN 2011 | |
3D-Image software | ThermoFisher Scientific | Amira 6.4 | |
ImageJ | National Institutes of Health (NIH) | https://imagej.nih.gov/ij/ | ImageJ/FIJI |