We herein describe a phagocytosis assay using the dispersed embryonic cells of Drosophila. It enables us to easily and precisely quantify in vivo phagocytosis levels, and to identify new molecules required for the phagocytosis of apoptotic cells.
The molecular mechanisms underlying the phagocytosis of apoptotic cells need to be elucidated in more detail because of its role in immune and inflammatory intractable diseases. We herein developed an experimental method to investigate phagocytosis quantitatively using the fruit fly Drosophila, in which the gene network controlling engulfment reactions is evolutionally conserved from mammals. In order to accurately detect and count engulfing and un-engulfing phagocytes using whole animals, Drosophila embryos were homogenized to obtain dispersed cells including phagocytes and apoptotic cells. The use of dispersed embryonic cells enables us to measure in vivo phagocytosis levels as if we performed an in vitro phagocytosis assay in which it is possible to observe all phagocytes and apoptotic cells in whole embryos and precisely quantify the level of phagocytosis. We confirmed that this method reproduces those of previous studies that identified the genes required for the phagocytosis of apoptotic cells. This method allows the engulfment of dead cells to be analyzed, and when combined with the powerful genetics of Drosophila, will reveal the complex phagocytic reactions comprised of the migration, recognition, engulfment, and degradation of apoptotic cells by phagocytes.
In metazoan animals, e.g. the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster, and mice and humans, a large number of cells undergo apoptosis during development to shape their bodies and in adulthood to maintain homeostasis1,2. Apoptotic cells need to be rapidly removed because they induce inflammation in the surrounding tissues by releasing immunogenic intracellular materials if not completely removed3. In order to facilitate rapid removal, apoptotic cells present so-called eat-me signals that are recognized by the engulfment receptors of phagocytes, and are eliminated by phagocytosis3,4,5,6. Thus, phagocytosis plays a crucial role in the maintenance of host homeostasis, and hence, elucidating the molecular mechanisms underlying the phagocytosis of apoptotic cells is of importance.
The mechanisms responsible for the phagocytosis of apoptotic cells appear to be evolutionally conserved among species in the nematodes, flies, and mice7. Several phagocytosis assays are currently available to assess the engulfment of apoptotic cells in these model animals. In C. elegans, 131 somatic cells undergo programmed cell death during development, and cell corpses are phagocytosed by neighboring cells, which are non-professional phagocytes8. Thus, counting the number of remaining cell corpses in C. elegans indicates the level of phagocytosis in vivo. By searching for nematode mutants that show an increased number of dead cells, several genes required for phagocytosis have been identified and genetically characterized9,10,11,12.
Ex vivo phagocytosis assays with primary culture phagocytes, generally macrophages, are often utilized in mice. Apoptotic cells are prepared using cell lines such as Jurkat cells, and are mixed with primary phagocytes. After an incubation for several hours, the total numbers of phagocytes and engulfing phagocytes are counted in order to assess the level of phagocytosis. As a sophisticated modification of this method, Nagata's group developed an ex vivo phagocytosis assay with cells expressing a caspase-resistant ICAD (inhibitor of caspase-activated DNase), in which apoptotic cells do not undergo apoptotic DNA fragmentation, but DNA is still cleaved when cells are phagocytosed. When these cells are used as apoptotic targets in a phagocytosis assay, only the DNA of engulfed apoptotic cells is fragmented, and stained by TdT-mediated dUTP nick end labeling (TUNEL). Therefore, the level of apoptotic cell engulfment is measured by counting TUNEL signals in a mixture of phagocytes and apoptotic cells13.
In D. melanogaster, professional phagocytes named hemocytes, Drosophila macrophages, are responsible for the phagocytosis of apoptotic cells14,15. In addition to in vitro phagocytosis assays with culture cell lines, in vivo phagocytosis assays with whole Drosophila embryos are available. Drosophila embryos are a powerful tool for examining the level of apoptotic cell engulfment because many cells undergo apoptosis and are phagocytosed by hemocytes during embryonic development14,15,16. An example of an in vivo phagocytosis assay is the method developed by Franc's group. In their method, hemocytes are detected by the immunostaining of peroxidasin, a hemocyte marker, apoptotic cells are stained using the nuclear dye, 7-amino actinomycin D in whole Drosophila embryos, and the number of double positive cells is counted as a signal of phagocytosis17. Another example of a phagocytosis assay on embryos is based on the concept of Nagata's method described above; however, in vivo phagocytosis is evaluated using the embryos of dCAD (Drosophila caspase-activated DNase) mutant flies18,19. These in vivo phagocytosis assays are useful for directly observing phagocytosis in situ. However, difficulties are associated with excluding any possible bias in the step of counting phagocytosing cells because it is hard to observe all phagocytes and apoptotic cells in whole embryos due to its thickness.
In order to overcome this limitation, we developed a new phagocytosis assay in Drosophila embryos. In our method, in order to easily count phagocytosing hemocytes, whole embryos are homogenized to prepare dispersed embryonic cells. Phagocytes are detected by the immunostaining of a phagocyte marker, and apoptotic cells are detected by TUNEL with these dispersed embryonic cells. The use of dispersed embryonic cells enables us to measure in vivo phagocytosis levels as if we performed an in vitro phagocytosis assay that precisely quantifies the level of phagocytosis. All genotypes of flies may be employed in this assay if they develop to stage 16 of embryos20, the developmental stage at which apoptotic cell clearance by phagocytosis is the most abundant. This method has the advantage of assessing the level of phagocytosis quantitatively, and, thus, may contribute to the identification of new molecules involved in the phagocytosis of apoptotic cells in vivo.
1. Preparation
2. Stage 16 Embryo Collection
3. Preparation of Embryonic Cells
4. Staining of Hemocytes
5. Stain Apoptotic Cells by TUNEL
6. Measure the Level of Phagocytosis of Apoptotic Cells
In order to examine the phagocytosis of apoptotic cells, Drosophila embryos of developmental stage 16 were collected and prepared as dispersed cells. Hemocytes, Drosophila macrophages, were stained by immunocytochemistry for the hemocyte marker "Croquemort"17,22 using a specific antibody19,21, and apoptotic cells were stained by TUNEL in dispersed embryonic cells (Figure 1A). Croquemort, a Drosophila CD36-related receptor, is specifically expressed on all embryonic hemocytes22, and has been shown genetically to be involved in the clearance of apoptotic cells in Drosophila embryos17. Croquemort-positive cells have purple signals in the small granules of their cells. TUNEL-positive cells show a brown signal in whole corpuses. TUNEL-positive cells are smaller than other cells, and some are inside Croquemort-positive cells, which are considered to be phagocytosed dead cells. Between 2 and 10% Croquemort-positive cells and 1 – 5% TUNEL-positive cells are normally observed in all embryonic cells.
In Drosophila, there are two signaling pathways for the engulfment of apoptotic cells. Two phagocytosis receptors for the corresponding pathways, Draper and integrin αPS3βν, independently recognize dead cells19,21,23,24,25. Draper is a transmembrane protein which possesses atypical epidermal growth factor (EGF)-like sequences in the extracellular region and the two phosphorylatable motifs NPxY and YxxL in the intracellular portion26. Integrin αPS3βν is also a transmembrane receptor consisting of a heterodimer of α and β subunits25. Figure 1B shows the ratio of phagocytosing hemocytes to total hemocytes in wild-type or drpr or Itgbn single mutant embryos. By counting all Croquemort-positive cells (total hemocytes) and Croquemort- and TUNEL-double positive cells (phagocytosing hemocytes), we calculated the phagocytic index as the number of phagocytosing hemocytes to the total number of hemocytes. The phagocytic index was lower in the drpr or Itgbn mutant than in the wild type, while the numbers of hemocytes and apoptotic cells were similar (Figure 1C-D), indicating that these two genes are required for apoptotic cell engulfment, as previously reported.
When an anti-Croquemort antibody is not available or mutant lines with altered Croquemort expression are examined, we need to select another option to detect hemocytes. Embryos with a GAL4 driver controlled by a hemocyte-specific promoter (srpHemo-GAL4), and the GFP gene controlled by an upstream activation sequence (UAS) including the GAL4-binding site (UAS-EGFP), have GFP-labeled hemocytes27, which enables us to detect hemocytes using anti-GFP. Figure 2A shows an image obtained after detecting hemocytes and apoptotic cells with immunostaining using an anti-GFP antibody, and TUNEL in embryonic cells with srpHemo-GAL4UAS-EGFP. While an anti-Croquemort antibody stains small granules in cells, an anti-GFP antibody stains whole hemocytes. Similar to Figure 1A, 2 – 6% GFP-positive cells and 1 – 5% TUNEL-positive cells are observed in all embryonic cells. Some TUNEL-positive cells are detected inside GFP-positive cells, which are considered to be phagocytosed dead cells. RNAi-mediated knockdown is easily applied to assess any genes for their involvement in phagocytosis by crossing flies with the UAS-dsRNA of the candidate genes with srpHemo-GAL4UAS-EGFP. The RNAi-mediated knockdown of drpr or Itgbn reduced the phagocytic index (Figure 2B), whereas the numbers of hemocytes and apoptotic cells in embryonic cells was comparable (Figure 2C-2D), indicating again that these phagocytosis receptors are involved in the phagocytosis of apoptotic cells. Similar phagocytic indexes are obtained from both hemocyte detection methods, suggesting that both are compatible.
Figure 1: Staining of Embryonic Cells by an Anti-Croquemort Antibody and TUNEL. (A) Bright field images of dispersed embryonic cells from the w1118 strain by immunostaining with an anti-Croquemort antibody and TUNEL. Magnified views of representative positively or negatively stained cells (top 4 panels) and a low-power field (bottom panel) are shown. Scale bars, 5 µm (top); 50 µm (bottom). (B) The ratio of Croquemort-positive hemocytes with the TUNEL signal to all Croquemort-positive hemocytes in the drpr or Itgbn mutant was analyzed with dispersed embryonic cells. (C) The ratio of Croquemort-positive hemocytes to all cells in the drpr or Itgbn mutant was analyzed with dispersed embryonic cells. (D) The ratio of TUNEL-positive apoptotic cells to all cells in the drpr or Itgbn mutant was analyzed with dispersed embryonic cells. Genotypes; w1118(wild-type control), drprΔ5 (drpr mutant), and Itgbn2 (integrin βν mutant). Data were representative of three independent experiments and analyzed by the Student's t-test. Approximately 300 Croquemort-positive hemocytes were observed in each experiment, and values represent the mean±S.D. of three microscopic fields. *; p <0.05, n.s.; difference not significant. Please click here to view a larger version of this figure.
Figure 2: Staining of Embryonic Cells by Anti-GFP and TUNEL. (A) Bright field images of dispersed embryonic cells from the srpHemo-GAL4UAS-EGFP/+ strain by immunostaining with an anti-GFP antibody and TUNEL. Magnified views of representative positively or negatively stained cells (top 4 panels) and a low-power field (bottom panel) are shown. Scale bars = 5 µm (top); 50 µm (bottom). (B) The ratio of GFP-positive hemocytes with the TUNEL signal to all GFP-positive hemocytes in RNAi-mediated knockdown flies of drpr or Itgbn was analyzed with dispersed embryonic cells. (C) The ratio of GFP-positive hemocytes to all cells in RNAi-mediated knockdown flies of drpr or Itgbn was analyzed with dispersed embryonic cells. (D) The ratio of TUNEL-positive apoptotic cells to all cells in RNAi-mediated knockdown flies of drpr or Itgbn was analyzed with dispersed embryonic cells. Genotypes; RNAi – : y w/w; srpHemo-GAL4 UAS-EGFP/+, RNAi drpr: y w/w; srpHemo-GAL4 UAS-EGFP/+; UAS-drpr-IR/+, RNAi Itgbn: y w/w; srpHemo-GAL4 UAS-EGFP/+; UAS-Itgbn-IR/+. Data were representative of three independent experiments and analyzed by the Student's t-test. Approximately 300 GFP-positive hemocytes were observed in each experiment, and values represent the mean±S.D. of three microscopic fields. *; p <0.05, n.s.; difference not significant. Please click here to view a larger version of this figure.
We herein described a phagocytosis assay using Drosophila embryos. By using dispersed embryonic cells to measure phagocytosis quantitatively, hemocytes, Drosophila professional phagocytes, are immunostained for the hemocyte marker Croquemort or srpHemo-driven GFP, and apoptotic cells are detected by TUNEL in this protocol. The level of phagocytosis is expressed as a phagocytic index by counting the total number of hemocytes and phagocytosing hemocytes. The use of dispersed embryonic cells enables us to observe all phagocytes and apoptotic cells in whole embryos and to precisely quantify the level of phagocytosis. In addition, our method detects hemocytes and apoptotic cells with dyes that are observable under a light microscope, not a fluorescence microscope. This facilitates the assessment of phagocytosis levels because it is possible to observe hemocytes and apoptotic cells simultaneously without changing any filter.
The following points are critical for staining embryonic cells. In the fixation step of embryonic cells, fresh PFA prepared within two weeks needs to be used. In the immunostaining of Croquemort, the incubation of cells with anti-Croquemort needs to be performed at 4 °C. In TUNEL staining, the incubation of cells with DAB needs to be performed by carefully checking under a microscope to avoid excessive staining. TUNEL visualizes fragmented DNA by detecting 3'-OH, which is abundant in apoptotic cells. However, normal cells also have 3'-OH in the 3'-terminal of DNA, but at a lower level than that in apoptotic cells. Therefore, an incubation of cells with DAB for too long will stain not only apoptotic cells, but also normal cells. The observation of cells every 15 or 30 s during DAB staining is recommended to prevent this.
In this protocol, although quantification of the level of phagocytosis is fast and precise, some information such as the site of engulfment or distribution of hemocytes is lost. We previously showed that this assay and an in situ phagocytosis assay using whole embryos produced similar results in terms of the phagocytic index21. Therefore, we recommend performing an in situ phagocytosis assay in parallel in order to accurately interpret the results obtained in some cases.
Drosophila have another professional phagocyte, glial cells, in the central nervous system. Although we do not describe how to assess the phagocytosis of apoptotic neurons by glial cells in embryos in this protocol, the same protocol is applied to quantify the level of engulfment as that reported by Kuraishi et al., EMBO.J21. Likewise, this assay suggests that TUNEL positive cells in Drosophila embryos are likely to be phagocytosed by non-professional phagocytes. Phagocytosis by those unidentified phagocytes with unknown engulfment receptors might explain the result (Figure 1D) that the total number of apoptotic cells in embryonic cells seems not to be increased in a phagocytosis gene mutant.
In conclusion, this protocol has successfully led to the discovery of genes required for the phagocytosis of apoptotic cells by professional phagocytes.24,25,28. Based on the evolutionary conservation of the molecular mechanisms underlying phagocytosis7, revealing gene functions in Drosophila embryos that involve complex phagocytosis reactions may provide meaningful insights into the phagocytic clearance of dead cells, which is related to inflammatory disorders and autoimmune diseases in mammals29.
The authors have nothing to disclose.
We are grateful to Kaz Nagaosa and Akiko Shiratsuchi for their advice.
whole swine serum | MP Biomedicals | 55993 | For bloking |
Treff micro test tube(easy fit) Dnase, Rnase free tube, 1.5 mL | TreffLab | 96. 4625. 9. 01 | For homogenization |
pellet mixer 1.5 mL | TreffLab | 96. 7339. 9. 03 | For homogenization |
Collagenase | Sigma-Aldrich | C-0130 | For preparation of embryonic cells |
Trypsin | Thermo Fisher SCIENTIFIC | 27250-018 | For preparation of embryonic cells |
Kpl Anti-Rat IgG (H+L) Ab MSA, AP | KPL | 475-1612 | secondary antibody for stainig hemocytes with an anti-Croquemort antibody |
5-bromo-4-chloro- 3-indolyl-phosphate |
Roche | 11383221001 | BCIP, For staining of hemocytes |
nitro blue tetrazolium | Roche | 11383213001 | NBT, For staining of hemocytes |
Anti-Croquemort antibody | described previously in Manaka et al, J. Biol. Chem., 279, 48466-48476 | ||
Anti-GFP from mouse IgG1κ (clones 7.1 and 13.1) |
Roche | 11814460001 | For staining of hemocytes |
Goat Anti-Mouse IgG-AP Conjugate | Bio-Rad | 170-6520 | secondary antibody for stainig hemocytes with an anti-Croquemort antibody |
Apop Tag Peroxidase In Situ Apoptosis Detection Kit | Millipore | S7100 | For staining of apoptoitc cells. This kit includes Equilibration buffer, Reaction buffer, STOP/Wash buffer, TdT enzyme, and Anti-Digoxigenin-Peroxidase. |
3,3'-diaminobenzidine tetrahydrichloride |
nacalai tesque | 11009-41 | DAB, For staining of apoptoitc cells |
Table of Fly Strains | |||
Name | Company | Catalog Number | コメント |
w1118 | Control flies, described in Freeman et al., Neuron, 38, 567-580 | ||
drprΔ5 | drpr mutant, described in Freeman et al, Neuron, 38, 567-580 | ||
Itgbn2 | Itgbn mutant, described in Devenport et al., Development, 131, 5405-5415 | ||
srpHemoGAL4 UAS-EGFP | described in Brückner et al., Dev. Cell., 7, 73-84 | ||
UAS-drpr-IR | VDRC | 4833 | – |
UAS-Itgbn-IR | NIG-fly | 1762R-1 | – |