Preparing Developing Peripheral Olfactory Tissue for Molecular and Immunohistochemical Analysis in Drosophila

Summary

Here, we present a protocol to stage and dissect developing olfactory tissue from Drosophila species. The dissected tissue can later be used for molecular analyses, such as quantitative RT-PCR (Reverse Transcription-Polymerase Chain Reaction) or RNA sequencing (RNAseq), as well as in vivo analyses such as immunohistochemistry or in situ hybridization.

Abstract

The olfactory system of Drosophila is a widely used system in developmental neurobiology, systems neuroscience, as well as neurophysiology, behavior, and behavioral evolution. Drosophila olfactory tissues house the olfactory receptor neurons (ORNs) that detect volatile chemical cues in addition to hydro- and thermo-sensory neurons. In this protocol, we describe the dissection of developing peripheral olfactory tissue of the adult Drosophila species. We first describe how to stage and age Drosophila larvae, followed by the dissection of the antennal disc from early pupal stages, followed by the dissection of the antennae from mid-pupal stages and adults. We also show methods where preparations can be utilized in molecular techniques, such as the RNA extraction for qRT-PCR, RNAseq, or immunohistochemistry. These methods can also be applied to other Drosophila species after species-specific pupal development times are determined, and respective stages are calculated for appropriate aging.

Introduction

The olfactory system of Drosophila is a widely used system in developmental neurobiology, systems neuroscience, as well as neurophysiology, behavior studies, and behavioral evolution^1,2,3,4. Drosophila olfactory tissues house the olfactory receptor neurons (ORNs) that detect volatile chemical cues in addition to hydro- and thermo-sensory neurons^1,5,6. The overall goal of this manuscript is to demonstrate how to stage and dissect developing pupal and adult olfactory tissue in Drosophila species. The rationale for this technique is to generate samples from different pupal stages for molecular and developmental analyses of the peripheral olfactory system, such as RNAseq and quantitative RT-PCR, in addition to in vivo tissue labeling techniques. This technique can be especially useful to identify dynamics of transcriptional profiles in the developing adult olfactory system from non-melanogaster Drosophila species, which do not have all the transgenic reagents for cell type specific labeling and analyses. In this manuscript, we demonstrate how to dissect antennal discs and antennae from pupal and adult Drosophila species. First, we show how to identify Drosophila 0 h of puparium formation (APF, white pupae or prepupae) for developmental staging and species-specific aging. Next, we show how to dissect antennal discs and the third antennal segment; specifically, how to dissociate them from the eye disc and second antennal segment for the tissue purity required for RNAseq or RT-PCRs. The stages in D. melanogaster described in this protocol roughly correspond to the pre-patterned antennal disc (prepupae), the selection of precursors from the antennal disc (8 h APF), the start of the terminal differentiation for ORNs (40 h APF), and adult antenna. Finally, we give examples for a quantitative RT-PCR from adult antennae isolated using the method, and for in vivo immunohistochemistry. This method can be used to generate samples for an RNA/DNA analysis and for immunohistochemistry on developing peripheral olfactory tissues from different Drosophila species.

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Protocol

The following protocol is consistent with the ethics guidelines established by the Duke University Research Ethics Committee.

1. Tissue Preparation and Developmental Staging of Drosophila melanogaster Pupa

1. First, identify how many flies will be necessary for the dissection. For RT-PCR and RNAseq, collect 100 - 200 antennal discs and antennae from individuals which are necessary at prepupal, 8 h APF, 40 h APF, and adult stages. For immunohistochemistry, dissect 10 - 20 individual.
2. Clean all materials, including dissection pads and forceps, using wipes with 70% EtOH. If the dissected material is to be used for RNA extractions, clean everything with RNase neutralizers and make all solutions using either nuclease-free or diethyl pyrocarbonate (DEPC) treated water.
   NOTE: This protocol uses silicone dissection pads instead of glass for the dissections. Silicone pads are friendly to ultra-fine forceps and promote fast and high-quality dissections.
3. Collect pupa at the 0 h APF/prepupal stage.
   1. To ensure the most precise staging, monitor the larvae at 30 min to 1 h intervals.
      NOTE: Wandering third instar larvae in a moderately crowded bottle will likely pupate within a few hours.
   2. Once the larvae become immobile and are surrounded by a very light (almost white) colored pupal case, transfer them into a small 2-in Petri dish with a moist filter paper.
   3. Continue for 1 - 2 h, occasionally monitoring, identifying, and transferring prepupae.
      NOTE: Alternatively, clear a bottle of all pupae and allow the larvae to develop for 2 h. All pupae collected after 2 h will be within a 0 - 2 h APF range.
4. Immediately move to step 3.1 to dissect the prepupal antennal disc for the 0 h APF stage. If the prepupa needs to be aged, collect them into a dish, cover the dish and place a paraffin film around the edges to inhibit dryness, and place the Petri dish at 25 °C.
   NOTE: The pupae can now be aged to eclosion.
5. For pupae collected in a 2 h range, age the prepupae for 2 h less than the desired age in order to ensure that the pupae do not overage.
6. Use ultra-fine forceps (Dumont 55) as the tissue is very small and fragile.

2. Tissue Preparation and Developmental Staging of Pupa from Other Drosophila Species

1. To determine the length of the pupal development in other Drosophila species, place the samples at the optimum temperature, record the dates when prepupae are observed, sort them into a fresh vial, and record the number of days from prepupa to adulthood.
2. Record the ratio of time for pupal development for non-melanogaster species and for melanogaster. Multiply the ratio of the developmental time by the number of hours used for staging melanogaster to obtain the number of hours to age the non-melanogaster species.

3. Dissection of D. melanogaster Pupal Antennal Disc

Note: All the aging times and dissection protocols are described for Drosophila melanogaster. For all other species, a modification of the aging protocol based on species-specific developmental time points will be required, as described above.

1. For pupal antennal disc dissections, collect 50 - 100 0 - 2 h or 6 - 8 h old pupae using a spatula and place them on a dissection pad.
2. Pipette 150 µL of RNA isolation solution into an RNase free 1.5-mL microfuge tube using a 200-µL pipette and place the tube on ice.
3. Dissect the pupae in 150 - 200 µL of 1x PBS (phosphate buffered saline, nuclease-free). Place multiple droplets of PBS (150 - 200 µL per droplet) on the dissection pad.
4. On the dissection pad, place the 0 - 2 h or 6 - 8 h aged pupae (one pupa per drop) to be dissected in one of the 1x PBS droplets. Use forceps in one hand to stabilize the body.
5. For the 0 - 2 h aged pupae, using forceps in the other hand, hold on to the most anterior part (the mouth hooks) of the prepupa and pull it out to expose the brains and the imaginal discs attached to the anterior pupal case.
6. For the 8 h APF pupae, first gently peel off the pupal case from the most anterior quarter of the pupa, exposing the head within the membrane sack that surrounds the body.
   NOTE: The body, at this stage, looks like a degenerating larva.
7. Remove the head at the neck joint.
   NOTE: This ensures that the antennal discs will not be lost, which at this stage are connected primarily to the optic lobes of the brain.
8. Transfer the tissue with the brains and the imaginal discs to another 1x PBS droplet using forceps or a 20-µL pipette.
9. Identify the eye-antennal disc connected to the brain at the optic lobes. Using forceps, disconnect the eye-antennal disc from the brain and the pupal case. Transfer it to a new 1x PBS droplet using forceps or a 20-µL pipette.
   NOTE: The prepupal eye-antennal disc is a flat tissue. However, by the 8 h pupae, the eye discs are rotated cupping the antennal discs, which sits anterior to the central brain.
10. Using forceps, cut the tissue at the site of connection between the eye and the antennal disc. Use a 20-µL pipette to gently transfer the dissected tissue into the RNA isolation solution reagent. Minimize the amount of liquid transferred by pipetting an amount as small as possible.
11. Repeat until all pupae have been dissected.

4. Dissection of D. melanogaster Mid-pupal and Adult Antennae

Note: By 40 h APF, the majority of the metamorphosis is complete, and the adult structures are becoming apparent, but are still white and nondescript. At this developmental time point, the adult antenna has taken its final shape yet still is transparent and the majority of the olfactory receptors, except for a few, have not started expression.

1. For pupal antennal dissections, collect 50 - 100 prepupae as described in step 1 and age them for 40 h at 25 °C.
2. Pipet 150 µL of RNA isolation solution into an RNase free 1.5-mL microcentrifuge tube using a 200-µL pipet and place the tube on ice.
3. On the dissection pad, place the pupa to be dissected into one of the 1x PBS droplets. Use forceps in one hand to stabilize the body. Using forceps in the other hand, gently peel off the pupal case from the most anterior quarter of the pupa, exposing the head within the membrane sack that surrounds the body.
4. Using forceps, carefully cut off the head from the rest of the pupal body by holding the body with one set of forceps and ripping the head off at the neck joint with another set of forceps. Gently transfer the head into another 1x PBS droplet using forceps. Pipette up and down to clean out the contents of the head (the brain, etc.) to obtain a clear membrane that used to surround the developing Drosophila head.
   NOTE: At 40 - 50 h APF, the antennae are connected to the anterior-most section of the membrane. They will become apparent for dissection when the contents of the head are cleared with pipetting.
5. Using forceps, disconnect the pupal antennae from the membrane. Disconnect the 2^nd segment of the antenna from the 3^rd using forceps to slice at the segmental joint, as only the 3^rd segment will house the olfactory receptor neurons.
6. Use a 20-µL pipette to gently transfer the dissected tissue into the RNA isolation solution reagent. Minimize the amount of liquid transferred by pipetting an amount as small as possible. Repeat until all pupae have been dissected.
7. For adult antennal dissections, collect approximately 50 adults and age them for a week post-eclosion.
   NOTE: The expression of olfactory receptor genes and other genes peak a week after eclosion. The adults are aged for a week to ensure biologically relevant genes with low abundance transcripts to rise above the detection threshold.
8. For RNA extractions, dissect flies while they are still alive on a CO₂ pad. Treat the CO₂ pad with RNase inhibitors. For confocal imaging, dissect the flies on a dissection pad in 1x PBS or PBS + 0.2% Triton.
9. First, put the adults to sleep on the CO₂ station pad under the dissection scope. On the CO₂ station pad, using forceps in one hand to stabilize the body, use forceps in the other hand to gently pull/pinch out the third antennal segment from the second.
10. Transfer the antennae into an RNA isolation solution, using forceps to place the antennae directly into the liquid. Repeat until all adults have been dissected.
    NOTE: Ensure that the antennae are submerged in RNA isolation solution. The antennae may become stuck on the side of the tube. This will cause an increased degradation of the RNA, reducing RNA quality and quantity.
11. Directly proceed to the RNA extraction or place the tube at -80 °C for long-term storage.

5. RNA Isolation from Dissected Tissues

1. Remove all samples from the -80 °C storage and thaw them on ice.
2. Briefly spin (5 - 6 s, ~6,000 x g) each sample to collect the material at the bottom of the tube.
3. Grind each sample using an autoclaved plastic pestle and an electric motor for 10 s on ice.
4. Repeat steps 5.2 and 5.3 4.
5. Perform the RNA extraction using commercially available kits and following the manufacturer's protocols for an optimal yield.
6. Perform qRT-PCR using commercially available reagents and specific primers against genes of interest and following the manufacturer's protocols.
   1. Carry out all PCR reactions using the following conditions: 95 °C denaturation for 10 min followed by 40 cycles of 95 °C for 15 s, 55 °C for 30 s, and 60 °C for 30 s.
      NOTE: Primer pairs for DIP and dpr genes are listed in Table 1, and primers for olfactory receptor genes are listed in Hueston CE et al.⁸.

6. Fixation of the Pupal Antennal Discs and Antennae for Immunohistochemistry

NOTE: Fix the tissues in batches from 10 - 20 individuals to ensure the tissues are fixed for the same amount of time. Minimize the amount of time the samples stay in PBT (PBS with detergent) prior to transferring them to a fixative to maximize the integrity of the tissues.

1. Collect the dissected antennal discs or pupal antennae in a 200-µL PCR tube containing 200 µL of 0.2% PBT on ice to maintain tissue integrity, and to avoid the sample from sticking to the wall of 200-µL PCR tubes which will lead to an incomplete fixation.
   Note: Pupal antennae and antennal discs can be difficult to see as they are quite translucent. It is advisable to use a dissection scope for all washing steps to prevent any loss of tissue. Alternatively, 96-well Terasaki plates may be used for the fixation and staining to best track the tissue.
2. Fix the dissected antennal disc and antennal samples from pupae in approximately 200 µL of 4% PFA (Paraformaldehyde) for 30 min at room temperature. For this and subsequent steps, keep the tubes with the samples on a nutator to properly mix the samples in the solution. Progress to step 6.7.
3. For the adult antenna, dissect the entire head first and fix it in approximately 200 µL of 4% PFA (paraformaldehyde) for 1 h at room temperature.
4. Wash 3x with 200 µL of 0.2% PBT for 10 min each. Keep the samples on the nutator during the incubation.
5. Go back to the dissection microscope for a finer dissection of the second antennal segment from the fixed heads. Using forceps to stabilize the head, gently pull/pinch out the third antennal segment from the second.
6. Transfer the dissected third antennal segments into approximately 200 µL of 4% PFA (paraformaldehyde) and fix them for 30 min at room temperature.
7. Wash 3x with 200 µL of 0.2% PBT for 10 min each. Keep the samples on the nutator during the incubation.
8. Store the samples at 4 °C or continue directly with whole mount immunohistochemistry.
   Note: The efficiency of staining might change when the antibody is being used. This method should be appropriate for less abundant protein tags or weaker antibodies. However, at times, it might require an optimization of the protocol (either the identity or amount of the fixative or the time of fixation).

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Results

The dissected developing olfactory tissue can be used for RNA extraction followed by RT-PCR to assess gene expression or can be taken through immunohistochemistry protocols to determine its expression pattern, and the sub-cellular localization of genes of interest. In this section, we present representative results from either protocol. Figure 1 is the representative quantitative RT-PCR showing the transcription of cell surface receptor and olfactory receptor...

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Discussion

This protocol is a useful resource for labs interested in identifying the genetic and transcriptional programs operating in developing Drosophila olfactory tissue, as well as a comparative analysis of these programs across Drosophila species. It is especially useful if systems-level transcriptional profiles from different developmental stages are needed as a primer for future studies. The protocol described here demonstrates how to stage and isolate developing olfactory tissue from Drosophila t...

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Materials

Name	Company	Catalog Number	Comments
10X Phosphate-buffered Saline	Gibco	70011-044	Dilute to 1X in RNase free water
CO2 tank	Air Gas	CD R200
Two sharp forceps (Dumont #55)	Fine Science Tools	11255-20
Trizol	Invitrogen	15596-026	RNA isolation solutions
Dissecting Microscope
Small bucket with ice
P20 and P200 micropipettes and tips
1.7 mL Microfuge tubes			Purchase nuclease free for best results
0.2 mL PCR tubes
Paraformaldehyde powder	Polysciences	380
10% Triton X-100	Teknova	T1105	Dilute to 0.2% v/v in 1X PBS
2" petri dishes
55mm filter paper	Whatman	1001-055	Wet with water and place in a petri dish to keep pupae moist
25 C incubator
deionized H2O			Purchase nuclease free or treat with DEPC
Sylgard 184 Silicone Elastomer Kit	Dow Corning		to be used for making dissection pads from Terizaki plate covers.
MicroWell Mini Trays with lids	Nunc	438733	Lids can be used to make silicone dissection pads
Rabbit anti-GFP antibody	MBL international corpor	PM005	primary antibody
Mouse anti RAT CD2	AbD seroTec	MCA154RHDL	primary antibody
ADL195 (anti lamin, mouse)	Dev studies hydoma ban	ADL195-s	primary antibody
Alexa Fluor® 488 goat anti-rabbit IgG (H+L)	invitrogen	A11008	Secondary antibody
Cy3 Goat Anti-Mouse IgG	Jackson ImmunoResearch	115-166-003	Secondary antibody
Triton X-100, Protein Grade Detergent, 10% Solution, Sterile-Filtered	CALBIOCHEM	648463	detergent
Lab Rotator	Thermo scientific		Rotator
Nuclease Free Water	Growcells.com	NUPW-0125	Water
Light-Duty Tissue Wipers	VWR	82003-822	For cleaning dissection supplies
Superscript II	invitrogen	18064014	Reverse Transcriptase
QIAshredder (50)	RNA extraction	QIAGEN	79654
Oligo(dT)12-18 Primer	RT	life technologies	18418012
RNeasy MinElute Cleanup Kit (50)	RNA extraction	QIAGEN	74204
FASTSTART UNIV SG MASTER (5 ML)(500 RXN)	qPCR	Roche	04913850001
FASTSTART ESSENTIAL GREEN DNA MASTER	qPCR	Roche	06402712001
LIGHTCYCLER 480 - MULTIWELL PLATE 96	qPCR	Roche	04729692001
NEBNext High-Fidelity 2X PCR Master Mix	qPCR	NEB	M0541S