Drosophila immune priming against Pseudomonas aeruginosa is short-lasting and depends on cellular and humoral immunity

"Traditional" vertebrate innate and adaptive immunity

Defence barriers, such as the physical barrier of the skin or insect cuticle, intestinal mucus or insect peritrophic membrane and the low or high acidity in the gastrointestinal tract are the first lines of defence against invading microorganisms¹. In addition, innate immunity can be elicited as a fast and broad response against pathogens. Specialised immune cells such as macrophages and neutrophils can internalise and digest microbes initiating an inflammatory response at the site of infection or systemically to produce a hostile environment for the intruder. The complement group of proteins can also be activated to fight invading microorganisms^2–5.

Components of the immune system can exhibit further specificity and acquire memory of past infections. This evolutionary step, termed ‘adaptive immunity’, can only be seen in vertebrates and displays antigenic specificity, diversity, immunologic memory and self/non-self recognition. Adaptive immunity depends on innate immune responses such as phagocytosis and inflammation that trigger the utilisation of specific immune response on the invader⁶. Adaptive immunity can produce a variety of immune responses specific to antigenic challenges through a variety of effectors. Cooperation between lymphocytes and antigen presenting cells is the main mechanism of action, according to which naive B lymphocytes expressing a membrane-bound antibody molecule are activated when they bind to their specific antigen and divide quickly into memory B cells and effector B cells that induce humoral immunity⁷. T lymphocytes recognise cell antigens only from major histocompatibility complex molecules and proliferate into memory and effector T cells. T lymphocytes can be subdivided into T helper (TH) and T cytotoxic (TC) cells that are responsible for the tight regulation of the immune response and cytotoxic T lymphocyte activity (CTL)⁸. During a primary immune response, naive T and B lymphocytes become antigenically committed and expand rapidly in a process called clonal selection⁹. Immunologic memory can be attributed to these memory cells, which have long life spans and exhibit a heightened response during secondary exposure.

The immune response of Drosophila melanogaster

Drosophila is the main model organism for studying innate immunity among invertebrate species. Drosophila immune defences include physical barriers¹⁰, homeostatic factors¹¹ and local and systemic immune responses. Three systemic responses have been described in the fly: the humoral response, melanization and the cellular response¹². Similarly to other arthropods, Drosophila contains a circulating hemolymph with blood cells called hemocytes. These can be sub-divided into three cell types with different functions: plasmatocytes, lamellocytes and crystal cells¹². Plasmatocytes, which comprise the majority of mature hemocytes, can clear unwanted cells and pathogens through phagocytosis¹². Lamellocytes can only be observed in larvae where they encapsulate and neutralise larger objects, and crystal cells are involved in the melanization process¹². The synthesis and deposition of melanin in the affected area is thought to play an important role in wound healing, captivation and encapsulation of invading microbes and production of toxic substances for subsequent microbial destruction¹². Coagulation occurs to prevent hemolymph loss but can also trap microorganisms and facilitate their destruction¹³.

The Drosophila fat body is analogous to the mammalian liver where humoral response molecules are produced¹⁴. Bacteria and fungi activate the Toll pathway indirectly via production of a “danger” signal¹⁵. In addition, bacteria and fungi induce the Toll and Imd pathways directly by the recognition of bacterial peptidoglycan and fungal beta-glucan via peptidoglycan recognition proteins and Gram-negative binding protein 3 respectively¹⁶. Upon systemic immune response Toll and Imd pathways induce the NF-κB factors Dif and Rel respectively, which in turn induce the expression of several antimicrobial peptides (AMP)¹⁷. Besides AMPs, plasmatocytes locate and phagocytose bacteria through the help of scavenger receptors Eater and Dscam^18,19. The epithelial barrier also exhibits local immunity where production of reactive oxygen species (ROS) and AMPs provides a defence mechanism in the gut²⁰. In addition to the plasmatocyte-expressed cytokine unpaired 3 (Upd3) induces the JAK/STAT pathway mediating robust responses to bacterial and fungal infection¹²; while the same pathway can be induced upon tissue damage or viral infection^21,22.

Evidence of pathogen specific immunological memory

The aforementioned innate immune responses have not been proven to exhibit adaptive properties such as memory or specificity. However, the classic division between innate and adaptive immunity has recently been brought into question by a number of studies in invertebrate organisms, which challenge the currently defined boundaries of immunological memory²³.

Recent evidence suggests that arthropods can display selected 'specificity' towards particular microorganisms. Pham and colleagues demonstrated that the fruit fly exhibits a specific primed immune response dependent on plasmatocytes²⁴. They tested various pathogens including bacteria and fungi and found that flies mount a prolonged protective response against Streptococcus pneumoniae after being primed with a sub-lethal or heat-killed dose of the bacterium. S. pneumoniae bacteria are killed by the host within 1 day of infection only in primed flies whereas unprimed flies still contained bacteria indicating that survival depends on the elimination rate of S. pneumoniae²⁴. They also found a similar adaptation with the natural fungal pathogen Beauveria bassiana.

Protection against other bacteria was not observed by priming with S. pneumonia. Conversely, other heat-killed bacteria – known to be strong immune activators - did not exert a protective response against S. pneumoniae. Immune pathway mutants demonstrated that immune priming is due to the activation of the Toll pathway but not due to the expression of AMPs. These findings illustrate the selective adaptability of the immune system through the activation of Toll pathway and plasmatocytes. However it is important to note that not all pathogens respond in the same way. In this report, we use the example of Pseudomonas aeruginosa, a gram-negative bacterium that induces the Imd and the Toll pathways, as well as the cellular immune response.

Immune priming with P. aeruginosa

Previous studies show that live P. aeruginosa infection with the low-in-virulence CF5 strain primes the immune system and helps to protect Drosophila from subsequent lethal infection with the virulent PA14 strain (UCBPP-PA14)²⁵. This protection is evident 6, 12 and 24 hours post immune priming and involves the activation of both the Imd and the Toll pathway²⁵. Here we assess the duration of this protective response and the involvement of humoral and cellular immune responses. We find that immune priming with heat-killed P. aeruginosa CF5 confers protection for less than 7 days and that the Imd and the Toll pathways, as well as phagocytosis, contribute to host protection at 2 and 5 days respectively post-immune priming.

Fly strains

Wild type Oregon R and Eater mutant flies were a gift from Christine Kocks¹⁸. Canton S (CS) was obtained from Bloomington stock Center. Imd¹, Rel^E20 and Dif¹ mutant flies were a gift from Bruno Lemaitre.

Bacterial strains and infection assays

P. aeruginosa strains PA14 and CF5 are previously described human isolates²⁵. For inoculation with live CF5 cells flies were pricked with a needle previously dipped into a solution of 3 x 10⁸ CF5 cells/ml or in PBS as a control as previously described^25,26. For CF5 colony forming units (CFUs) enumeration, 3 flies per time point, in triplicates, were ground and plated every two days. Using the injection method 9.2 nl of a bacterial solution was introduced into the fly thorax to prime or infect the flies and host survival was measured every hour as previously described^25,26. 9.2 nl of a solution containing 3 x 10⁸ heat-killed CF5 cells/ml or the equivalent volume of PBS was injected to prime flies with heat-killed P. aeruginosa. Primed flies were subsequently injected with 9.2 nl of a live bacteria solution containing 3 x 10⁷ PA14 cells/ml.

Statistical analysis

Fly survival kinetics were analyzed using the MedCalc software (www.medcalc.org/). Survival curve analyses were performed using the Logrank test of the Kaplan-Meier survival analysis²⁷. The supplementary data tables (Table S1–Table S7) accompanying this work provides the actual number of flies per experiment and individual results used for analysis.

Specific responses to different microbes

Collectively our data indicate that low-in-virulence P. aeruginosa can prime the Drosophila humoral and cellular immune responses against a subsequent lethal infection with a more virulent strain. Nevertheless, unlike priming with S. pneumoniae or B. Bassiana, this is not a long-lasting effect. It is thus pivotal that future studies assess in detail the differences in the immune responses among many different microbes and in time points that last for many days rather than hours as is customary. Long-term responses to single or repeated challenges of the immune system might pinpoint novel aspects of immunological memory. One aspect of immune responses that might be related to immunologic memory in invertebrates is specificity. A recent breakthrough in the specificity of immune responses in insects came with the discovery of the multi-variable gene Dscam²⁸. Dong and his team found that different immune elicitors in the mosquito direct the production of pathogen-specific splice variants of the Down Syndrome Cell Adhesion Molecule receptor necessary for the protection of the host from infection with Plasmodium. Though no experiments were done to test the duration of this specific response, this work illustrates the adaptability of the insect immune system. There are additional examples of specific immune responses in invertebrates such as the snail Biomphalaria glabrata, in which fibrinogen related proteins (FREPS) exhibit a high rate of diversification at a genomic level, and the expression profiles of the scavenger receptor cysteine-rich proteins in the sea urchin, although how these proteins respond to re-challenge is not known^29,30. Protection against a secondary infection is also seen in the mealworm beetle, Tenebrio molitor³¹. Prolonged protection was observed when initial exposure to lipopolysaccharides (LPS) before infection with spores of the entomopathogenic fungus Metarhizium anisopliae occurred. This was attributed to a long-lasting antimicrobial response of the LPS-challenged larva, which provided a survival advantage when it was exposed to fungal infection. Thus invertebrate hosts can be further studied to understand the parameters of long-lasting immune responses and their relation to immune specificity and memory.

In conclusion, the area of immunological memory remains elusive in the invertebrate world and only recently have small steps been made to investigate this aspect of the immune system. Specific responses can occur against particular pathogens. Generalisations on the defence mechanisms do not represent the true complexity of the immune system. Therefore, the immune system of invertebrates is still a field that can advance our understanding of how organisms defend themselves from intruders.