A Hemocyte Disturbance Assay to Assess Hemocyte Re-Adhesion to Hematopoietic Pockets

Published: January 31, 2024

Abstract

Source: Petraki, S. et al., Assaying Blood Cell Populations of the Drosophila melanogaster Larva. J. Vis. Exp. (2015)

This video demonstrates the hemocyte disturbance assay, evaluating hemocyte re-adhesion in Drosophila larvae's hematopoietic pockets. Mechanical disturbance releases resident hemocytes, elevating circulating hemocyte counts. Post-recovery, re-adherence of resident hemocytes is confirmed, illustrating reversibility.

Protocol

1. Hemocyte Bleed/Scrape Assay

  1. Preparation of slides:
    1. Option 1 for microscopes without tile scanning function: For each larva to be analyzed, prepare one glass slide with about 5 Pap-pen wells of 2 mm squares each, corresponding to the field viewing area of the microscope; add approximately 5 – 10 µl of S2 media to each (Figure 1A). Keep slides in a moist chamber to prevent wells from drying out.
    2. Option 2 for microscopes with tile scanning function: For each larva to be analyzed, prepare one glass slide with 3 to 4 Pap-pen wells of ~3 – 4 mm squares each; add approximately 15 – 20 µl of S2 media to each well (Figure 1B). Keep slides in a moist chamber to prevent wells from drying out.
      NOTE: The above-recommended number of wells is sufficient for totals of up to 3,000 hemocytes per larva (late 2nd instar larvae, ~2.5 – 3 mm length, transgene labeling the majority of larval blood cells). When assessing larger blood cell numbers, more wells might be needed to avoid overcrowding.
  2. Collection of larvae:
    1. Squirt water into a fly vial containing larvae and flush larvae into a Petri dish, or scoop some food that contains larvae into a Petri dish and dilute with water using a squirt bottle.
    2. Gently pick larvae out of the Petri dish using a paintbrush and place them in water in a cavity dish or on a slide on a cold block.   
      NOTE: Larvae can be kept for a limited time in water or on a cold block; use specimens within 45 min or less to avoid larval death or unwanted effects on hemocytes.
  3. Dissection:
    1. Select larvae under a fluorescence microscope on a cold metal block. Measure sizes and image larvae if desired.
    2. Isolation of circulating hemocytes ("Bleed"):
      1. Once larvae are selected, place one larva in the first Pap-pen well (Figure 1C, 2A).
      2. Use 2 clean needles or dissecting scissors and forceps to make an incision at both the posterior and anterior ends of the larva. To avoid disturbing resident hemocytes, it is best to make these incisions on the ventral side of the larva. For consistent results, make the incisions in the same locations for every larva. For 1st instar larvae, 1 incision (in the ventral anterior) is sufficient.
      3. Allow the larva to bleed for a few seconds without any pressure or physical agitation (Figure 2A).
        NOTE: If working on multiple larvae it is better to make these incisions for each one before proceeding to the next step to avoid keeping larvae on ice too long which could affect the samples' integrity.
      4. Gently lift the larva with the needles or forceps and dip it into the second well to rinse any remaining circulating hemocytes. After that, follow with the release of resident hemocytes.
    3. Isolation of resident hemocytes ("Scrape"):
      1. Gently transfer the larva to the next well (Figure 2C).
      2. Identify the lymph gland of the larva, which typically is located approximately 1/3 from the anterior end of the larva, and which may fluoresce dorsally through the larval body wall. Avoid the lymph gland while releasing resident hemocytes by pinning down the larva with a needle as near as possible to the lymph gland to avoid puncturing (Figure 2C).         
        NOTE: During normal development, the maturation of lymph gland hemocytes is delayed compared to larval hemocytes, and fluorescent reporters of differentiated hemocytes may not show a signal in the lymph glands of young larvae. In these instances, less attention needs to be paid to the lymph gland as no contamination of differentiated fluorescently-labeled larval hemocytes by lymph gland hemocytes is expected.
      3. Release resident blood cells in a dissection process of scraping and/or jabbing. Use one needlepoint to effectively pin down the larva near the lymph gland (see above) or other body areas as needed. Use another needle to jab at the clusters of hemocytes that are visible through the larval body wall (Figure 2C, E), aiming to separate the hemocytes. Hemocytes can also be released in a scraping motion. However, tearing the epidermis early may release big clusters of blood cells, which could make automated counting more challenging.
        NOTE: Depending on the age and genotype of the larva, the number of total hemocytes will vary. Distribute the release process described above over several wells to avoid overcrowding of some wells with blood cells, which could make single-cell image analysis more difficult.
      4. If few hemocytes remain in the final carcass, count these hemocytes by observation through the microscope and use of a manual tally counter (Figure 2E). To facilitate counting, place the carcass on a clean area of the same slide and spread it as thinly as possible to reduce the number of optical planes.
      5. Once the dissection is complete, wait between 5 – 10 min for the cells to settle (but not necessarily adhere) before imaging the wells. Incubate the slide in a moist chamber to avoid drying, and avoid rough handling of the slides, which could disturb the settled hemocytes.
        NOTE: When determining hemocyte counts, released cells are not fixed and the cells must be imaged shortly after dissection, preferably within 30 min after release from the larva. Depending on the volume of the medium and cell properties, the vast majority of cells will have settled within 5 – 10 min, which should be confirmed by focusing through the optical planes of the medium in the well. However, only a fraction of blood cells will have adhered to the slide surface by this time, a fact that needs to be considered if modifying this protocol for cell fixation-based approaches.
  4. Quantification:
    1. Take images of the settled hemocytes under a fluorescent microscope (Figure 2B, D, F). Follow with quantification of hemocytes using ImageJ software.
    2. Prepare the image for ImageJ cell counting algorithm:
      1. Open the image of the well using ImageJ: File → Open → (locate file and select).
      2. Ensure that the image(s) is 8-bit or 16-bit. Adjust the threshold for the image by selecting Image then click Adjust and select Threshold. Observe the "Threshold window" (Figure 3A).
      3. Check the "Dark Background" option. Select "Red" and increase the Lower Threshold Level (see black arrow) until each cell in the image is marked with a red dot (cells that are not being covered will be seen in grayscale; Figure 3B). As the Lower Threshold is increased some cells will become unmarked. This can be the indicator of how far to set the Lower Threshold.
        NOTE: Occasionally clusters of cells cannot be resolved and would be counted as one by the particle counter. In such cases, the number of cells in a cluster can be estimated by examining the image (zoom in if needed) and manual counting using a tally counter. Alternatively, the Lower Threshold can be increased to resolve clusters of cells; any unmarked cells resulting from this manipulation can then be counted using a tally counter.
    3. Analyze cell number using ImageJ:
      1. Launch the Particle Analyzer to count the cells (Figure 3C). Select Analyze and click on Analyze Particle. Optionally select "Overlay Outlines" to see the particles the algorithm counts (Figure 3D). Alternatively, set a limit to the size or pixel area of a unit (e.g., cell, clump of cells, etc.) for the algorithm to count.
      2. Click OK. Observe a summary window with the count (Figure 3E).

2. Hemocyte Disturbance Assay

  1. To disturb hemocytes, select larvae and place them in a 2 ml microcentrifuge tube with approximately 0.5 g of glass beads (212 – 600 µm) and add 0.5 ml water.
  2. Vortex the tube, by hand, at speed 10 for 1 min.
  3. Retrieve the larvae from the glass beads by spilling the contents of the microcentrifuge tube into a Petri dish and picking out the larvae with a paintbrush.
  4. For the recovery phase, place larvae in previously prepared Petri dishes with small amounts of fly food. Allow the larvae to re-establish their hemocyte pattern for a period of 45 min or as desired.       
    NOTE: Discard any larvae that have stopped moving, as they have died in the process. However, we typically see little damage after 1 minute of vortexing.
  5. After the recovery period, continue with the Bleed/Scrape Assay as described above in Section 1.

Representative Results

Figure 1
Figure 1. Hemocyte Bleed/Scrape and Disturbance Assay setup and schematic. (A) Single Image Slide Setup: five 2mm squares for imaging with a 5X objective. (B) Tile Scan Slide Setup: four 3 mm squares for imaging bleed/scrapes of ≤2.5 mm larvae with a tile scan microscope. Recommended objectives for imaging are 5X or 10X. (C) Bleed/Scrape Assay schematic and resulting quantifications using ImageJ. (D) In the Disturbance Assay, the hemocyte pattern is mechanically disrupted by vortexing larvae with glass beads. Larvae are allowed to recover over a period of 45 min during which hemocytes re-adhere to the Hematopoietic Pockets. The adhesive properties of hemocytes can be assessed by this method, quantifying the percentage of hemocytes in circulation after disturbance.

Figure 2
Figure 2. Bleed/Scrape Assay to release circulating and resident hemocytes. (A) To bleed a larva, ventral incisions at the posterior and anterior ends of the larva are made (scissors symbol). (B) Hemocytes in circulation will flow out of the incisions and settle on the surface of the slide. (C) The lymph gland (LG) is located and pinned down, without puncturing it. Resident hemocytes are released by jabbing and/or scraping the larva with a needle. (D) Resident hemocytes on the slide. (E, F) The Scrape process is repeated until all resident hemocytes are released. The larval carcass containing the intact lymph gland is left behind. 

Figure 3
Figure 3. Automated quantification of hemocytes using ImageJ. (A, B) After opening a hemocyte image file in ImageJ, the Lower Threshold level is adjusted to account for all the cells in the image. (C, D) Analyze Particles requires setting the cell pixel size, circularity, and the result readout format (e.g., Overlay Outlines). (E) A summary window displaying the number of hemocytes. 

Offenlegungen

The authors have nothing to disclose.

Materials

6cm/9cm Petri dishes One for each genotype to be evaluated
Water squirt bottle
Metal spoon/spatula
Thin paintbrush e.g. a "liner"
Glass cavity dish
PAP pen: Super PAP PEN IM3580 Beckman Coulter
Glass slides Each slide will have 5 or more PAP PEN squares drawn on them. Size of squares depends on the imaging objective and magnification of the microscope camera; e.g. 2mm squares.
Moist chamber This will be used to prevent slides and wells from drying out: sealed container with wet paper towels lining the sides/bottom
Schneider's Drosophila cell culture media Invitrogen
Cold block This is a metal block (a.k.a. heating block) chilled in bucket containing ice; preferably black-colored or other dark, non-reflective color
Two 1ml syringes with needles (27G ½) Becton Dickinson For dissections.
Optional: Surgical spring scissors (cutting edge 2mm) Fine Science Tools
Glass beads, 212-600 micron Sigma
2 ml Eppendorf tubes Eppendorf One per genotype evaluating
Vortex Mixer Fisher Scientific
Transgenic Drosophila larvae with fluorescently marked hemocytes. Suitable transgenes include: HmlΔ-DsRed (Makhijani et al., 2011), MSNF9mo-mCherry (Tokusumi et al., 2009), BcF6-CFP and -GFP (Gajewski et al., 2007), or HmlΔ-GAL4 (Sinenko and Mathey-Prevot, 2004), Pxn-GAL4 (Stramer et al., 2005), He-GAL4 (Zettervall et al., 2004), Crq-GAL4 (by H. Agaisse (Stramer et al., 2005)), or eater-GAL4 (Tokusumi et al., 2009) combined with UAS-GFP or other fluorescent protein transgenes.
Fluorescence dissecting microscope Leica Here: Leica M205, optional with camera, imaging software and measuring module
Inverted fluorescence microscope with camera attachment Leica or Keyence With or without tile scanning function (eg. Leica DMI series, Keyence BIOREVO BZ-9000 series)

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A Hemocyte Disturbance Assay to Assess Hemocyte Re-Adhesion to Hematopoietic Pockets. J. Vis. Exp. (Pending Publication), e21920, doi: (2024).

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