Assessing the Cellular Immune Response of the Fruit Fly, Drosophila melanogaster, Using an In Vivo Phagocytosis Assay

Innate immune defenses form the first line of defense against pathogenic microbes. These responses can be functionally divided into humoral and cellular innate immunity, both of which are mediated by germline-encoded pattern recognition receptors (PRRs) that sense pathogen-associated molecular patterns (PAMPs)¹. Many of the signaling pathways and effector mechanisms of innate immunity are conserved in mammals and invertebrates, such as the nematode, Caenorhabditis elegans, and the fruit fly, Drosophila melanogaster². The fruit fly has emerged as a powerful system to study host defense against infectious microorganisms³. Drosophila is genetically tractable, easily and inexpensively reared in laboratories, and has a short generation time. Furthermore, the fruit fly exhibits highly efficient defenses against an array of microbes, enabling the examination of host immunity against viral, bacterial, fungal, or parasitic pathogens.

Drosophila immunologists have historically utilized forward genetic screens, genome-wide RNA-mediated interference (RNAi) screening of insect cell lines, and pre-existing mutant fly strains to examine innate immunity – leading to the identification and characterization of several evolutionarily conserved humoral immune pathways^4,5,6,7,8. The humoral innate immune response is, arguably, the best characterized immune defense in fruit flies. Following infection, the humoral response leads to the production and systemic release of antimicrobial peptide (AMP) molecules into the hemolymph, the blood equivalent in insects. AMPs are produced by highly conserved Toll and Imd signaling pathways. The Toll pathway is homologous to mammalian TLR/IL-1R receptor signaling, and the Imd pathway is homologous to mammalian Tumor necrosis factor-alpha signaling. In Drosophila, Toll signaling is induced by gram-positive bacteria, fungi, and Drosophila X virus^6,9,10 and Imd signaling is induced by gram-negative bacteria^11,12.

Cellular immunity, comprised of encapsulation, melanization, and phagocytosis of invasive pathogens, carried out by specialized blood cells called hemocytes¹³. There are three classes of hemocytes in the fruit fly: crystal cells, lamellocytes, and plasmatocytes¹³. Crystal cells, which make up 5% of the circulating hemocytes in larvae, release proPhenoloxidase (proPO) enzymes leading to the melanization of pathogens and host tissues at wound sites. Lamellocytes, which are not normally found in healthy embryos or larvae, are adherent cells that encapsulate foreign objects. These cells are induced upon pupariation or when parasitizing wasp eggs are deposited in larvae. Phagocytic plasmatocytes, which make up 95% of circulating hemocytes in larvae and all remaining hemocytes in adults, play a role in tissue remodeling during development and, notably, serve as the main effector cell of Drosophila cellular immunity.

Phagocytosis an immediate and crucial line of innate immune defense; microbes that breach the host epithelial barrier are quickly engulfed and eliminated by phagocytic blood cells (For a comprehensive review of cell biology of phagocytosis see reference ¹⁴). This process is initiated when germline-encoded pattern recognition receptors (PRRs) on hemocytes recognize pathogen associated molecular patterns (PAMPs) of microbes. Once bound to their targets, PRRs initiate signaling cascades that lead to the formation of pseudopods through actin cytoskeleton remodeling. The pseudopods surround the microbe, which is subsequently engulfed and internalized into a nascent organelle, the phagosome. Microbes are destroyed as the phagosome undergoes the process of phagosome maturation when the phagosome is trafficked towards the interior of the hemocyte and acidifies through a series of interactions with lysosomes. In vitro and cell biology studies in mammalian primary cells have been instrumental in identifying and characterizing factors that regulate phagocytosis, such as the mammalian Fc-gamma receptor and C3b receptors^15,16. Nevertheless, the ability to execute large-scale screens or in vivo studies are limited in mammalian systems.

Here we present an in vivo assay for phagocytosis in adult fruit flies, which is based on a procedure first introduced by the laboratory of David Schneider in 2000¹⁷. The Schneider lab showed that sessile hemocytes clustered along the abdominal dorsal vessel readily phagocytose polystyrene beads and bacteria. To visualize phagocytosis, flies are injected with fluorescently labeled particles (such as E. coli labeled with fluorescein isothiocyanate (E. coli-FITC)), incubated for 30 minutes to allow hemocytes time to engulf the particles, and then injected with trypan blue, which quenches the fluorescence of particles not phagocytosed during the incubation period. Fly dorsal vessels are then imaged using an inverted fluorescent microscope. This seminal paper, using a relatively simple experiment, demonstrated that hemocytes phagocytose bacteria and latex beads, that bacterial phagocytosis can be inhibited by pre-injecting flies with latex beads, and that flies without both cellular and humoral immune responses are susceptible even to E. coli. The assay presented in this report builds on the work of the Schneider lab to quantify in vivo phagocytosis by measuring the fluorescence intensity of particles engulfed by dorsal vessel associated hemocytes.

Similar to the approach taken in mammalian systems, Drosophila geneticists initially used genome-wide in vitro RNAi screens to identify genes required for the cellular immune response^{18,19,20,21,22,23}. However, the development of the adult in vivo phagocytosis assay enabled follow-up experiments to be readily carried out in whole animals, thus allowing researchers to verify the biological the role of factors identified in in vitro studies. Such was the case with the transmembrane receptor Eater, which was first identified as a bacterial receptor in an RNAi screen using S2 cells²⁴ and then later shown to mediate Escherichia coli (E. coli), Enterococcus faecalis, and Staphylococcus aureus (S. aureus) phagocytosis in adults²⁵.

Our lab employed the in vivo phagocytosis assay in forward genetic screens and genome-wide association studies (using the Drosophila Genetic Reference Panel (DGRP)) to identify novel genes that regulate phagocytosis in adult hemocytes. These studies led to the characterization the receptors PGRP-SC1A and PGRP-SA²⁶, the intracellular vesicle trafficking protein Rab14²⁷, the glutamate transporter Polyphemus²⁸, and RNA-binding protein Fox-1²⁹.

We anticipate that future screens incorporating the in vivo phagocytosis could lead to the identification of additional genes that are important for the cellular immune response in Drosophila. Screens using fully-sequenced inbred lines, such as the DGRP or the Drosophila Synthetic Population Resource (DSPR), can identify natural variants affecting phagocytosis or hemocyte development. Furthermore, the technique could be adopted in other species of Drosophila or used to screen new community resources, such as the collection of 250 Drosophila species maintained by the National Drosophila Species Stock Center (NDSSC) at Cornell. These experiments can be carried out using fluorescently-labeled bacterial or fungal-wall bioparticles that are available commercially or may be performed using any number of bacterial or fungal species – provided that the microbe expresses fluorescent markers.