Infection Dynamics and Immune Response in a Newly Described Drosophila-Trypanosomatid Association

Trypanosomatid parasites are significant causes of human disease and are ubiquitous in insects. Despite the importance of Drosophila melanogaster as a model of infection and immunity and a long awareness that trypanosomatid infection is common in the genus, no trypanosomatid parasites naturally infecting Drosophila have been characterized. Here, we establish a new model of trypanosomatid infection in Drosophila-Jaenimonas drosophilae, gen. et sp. nov. As far as we are aware, this is the first Drosophila-parasitic trypanosomatid to be cultured and characterized. Through experimental infections, we find that Drosophila falleni, the natural host, is highly susceptible to infection, leading to a substantial decrease in host fecundity. J. drosophilae has a broad host range, readily infecting a number of Drosophila species, including D. melanogaster, with oral infection of D. melanogaster larvae resulting in the induction of numerous immune genes. When injected into adult hemolymph, J. drosophilae kills D. melanogaster, although interestingly, neither the Imd nor the Toll pathway is induced and Imd mutants do not show increased susceptibility to infection. In contrast, mutants deficient in drosocrystallin, a major component of the peritrophic matrix, are more severely infected during oral infection, suggesting that the peritrophic matrix plays an important role in mediating trypanosomatid infection in Drosophila. This work demonstrates that the J. drosophilae-Drosophila system can be a powerful model to uncover the effects of trypanosomatids in their insect hosts. IMPORTANCE Trypanosomatid parasites are ubiquitous in insects and are significant causes of disease when vectored to humans by blood-feeding insects. In recent decades, Drosophila has emerged as the predominant insect model of infection and immunity and is also known to be infected by trypanosomatids at high rates in the wild. Despite this, there has been almost no work on their trypanosomatid parasites, in part because Drosophila-specific trypanosomatids have been resistant to culturing. Here, we present the first isolation and detailed characterization of a trypanosomatid from Drosophila, finding that it represents a new genus and species, Jaenimonas drosophilae. Using this parasite, we conducted a series of experiments that revealed many of the unknown aspects of trypanosomatid infection in Drosophila, including host range, transmission biology, dynamics of infection, and host immune response. Taken together, this work establishes J. drosophilae as a powerful new opportunity to study trypanosomatid infections in insects.

The melanization reaction in Drosophila: More than black or white

Jan Paul Dudzic

The melanization reaction is a rapid and important immune mechanism in arthropods. It results in the production of melanin at the site of injury and around invading microbes. The enzymes responsible for melanogenesis are phenoloxidases (PO), which catalyze the oxidation of phenols to quinones, which then polymerize into melanin. A by-product of melanogenesis are cytotoxic compounds that can pose a threat to the host organism itself due to their unspecific effects. Melanogenesis is therefore tightly regulated: POs are produced in an inactive form as prophenoloxidases (PPOs), which get activated by the sequential cleavage of an extracellular serine protease (SP) cascade. The aims of this PhD thesis were to better understand the melanization reaction in Drosophila melanogaster, at both the effector and the regulation levels. D. melanogaster has three PPO genes. We generated for the first time a mutant for the third PPO gene, PPO3, and analyzed its function. We demonstrated that PPO3 has an important role in the melanotic encapsulation reaction, a defense mechanism against parasitization. Additionally, we extended our knowledge about the other PPOs, PPO1 and PPO2. We confirmed their role in the defense against septic infections and ascribed a new role for PPO2 in the melanotic encapsulation. The use of single or combined mutations allowed us to show that each PPO mutant has a specific phenotype, and that knocking out two of three genes is required to abolish a particular function completely. Thus, Drosophila PPOs have partially overlapping functions to optimize melanization. Finally, we demonstrated that PPO3 is the result of a gene duplication of PPO2, restricted to a subgroup of Drosophila, and likely evolved as an additional defense mechanism in the cellular encapsulation process, probably due to the evolutionary pressure from parasitoid wasps. In the second part of this thesis, we re-addressed the roles and functions of three SPs involved in the melanization process. We developed a novel screening method for defects in melanization by infecting flies with a low-dose of S. aureus. We found that only one of the three SPs, Sp7, is involved in survival upon septic infections. Additionally, we demonstrated that the melanization reaction resulting in the clearance of systemic infections is regulated by extracellular components of the Toll pathway. While a connection between the SPs regulating the melanization and the Toll pathway was found in other insects, our study provides the first demonstration in D. melanogaster. We also present evidence of a disconnect between the melanin production at wound sites and the melanization reaction resulting in the clearance of infections, indicating a role of cytotoxic compounds in the killing of microbes. Finally, we ascribed a new role to Hayan, another SP implicated in melanization. Hayan is dispensable for the clearance of septic infections, but is important for wound melanization. We also demonstrated that Hayan plays an important role in the activation of the Toll pathway. Hayan, together with the SP Persephone, is necessary to activate Toll after infection. We propose that both Hayan and Persephone are the result of a recent gene duplication event. This can explain why they still have overlapping functions, but these genes also show signs of early sub-functionalization. Collectively, our work provides important insights on both melanization and the activation of the Toll pathway.

EPFL2018

The double-edged toxins

Mario Gonzalo Garcia Arraez

Many insect species are associated with endosymbiotic bacteria which have the particularity of living within host tissues. Endosymbionts benefit from this stable and nutritious environment, while providing ecological advantages to their host, such as protection against parasites or thermal tolerance. Spiroplasma poulsonii is an endosymbiotic bacterium that infects natural populations of Drosophila melanogaster. Spiroplasma poulsonii lacks a cell wall, a fact that renders it invisible to the host immune system and allows it to thrive in the host hemolymph. It invades the female germline by co-opting the hostâs yolk transport and uptake machinery, which ensures its vertical transmission. Its efficient transmission is associated with a phenotype called male-killing, whereby infected male embryos die during their early development while infected females survive. The mechanisms that ensure the stability of Drosophila-Spiroplasma symbiosis are increasingly well understood, but the bacterial genes involved remain poorly known because of the intractability of Spiroplasma. This project aims at better characterizing the Drosophila-Spiroplasma interaction, with particular focus on the bacterial side. In the first part, I developed a method to cultivate Spiroplasma poulsonii in vitro by optimizing a commercially available medium. This culture method allowed comparing the transcriptome of in vitro grown versus host-grown Spiroplasma, enabling us to identify putative genes involved in the interaction with the host. Interestingly, inside its insect host, S. poulsonii up-regulates genes coding for toxins of the Ribosomal Inactivating Protein (RIP) family. RIPs were previously known for their role in host protection against macro-parasites, such as wasps and nematodes. Their up-regulation in unparasitized hosts compared to culture was thus peculiar, raising the question what effect these RIPs have on host biology. Thus, in the second part, I studied the function of S. poulsonii RIPs in the absence of parasites. I showed that two of them are constantly expressed within the host and provide evidence that these toxins shorten host life span and increase embryonic mortality. Interestingly, the expression of RIPs was more toxic to male embryos than females, suggesting that RIPs contribute to S. poulsonii-induced male-killing. Last, I studied the D. melanogaster response to RIPs, and how the host mitigates the deleterious effects of these toxins by up-regulating the cytosolic chaperone Heat-Shock-Protein 70B (HSP70B). This protein carries out essential functions in protein homeostasis under normal and stressful conditions such as folding, refolding, or increasing the half-life of proteins. Interestingly, up-regulation of Hsp70B in the presence of RIPs results in an increased lifespan and in a better tolerance to heat stress, which may be ecologically advantageous. Altogether, this work illustrates how Spiroplasma-derived RIP toxins can differentially affect Drosophila depending on the ecological context, ranging from beneficial upon parasite infection or heat shock to detrimental in the absence of such environmental pressures.

EPFL2018

Invasive and indigenous microbiota impact intestinal stem cell activity through multiple pathways in Drosophila

Nichole Broderick, Sveta Chakrabarti, Bruno Lemaitre

Gut homeostasis is controlled by both immune and developmental mechanisms, and its disruption can lead to inflammatory disorders or cancerous lesions of the intestine. While the impact of bacteria on the mucosal immune system is beginning to be precisely understood, little is known about the effects of bacteria on gut epithelium renewal. Here, we addressed how both infectious and indigenous bacteria modulate stem cell activity in Drosophila. We show that the increased epithelium renewal observed upon some bacterial infections is a consequence of the oxidative burst, a major defense of the Drosophila gut. Additionally, we provide evidence that the JAK-STAT (Janus kinase-signal transducers and activators of transcription) and JNK (c-Jun NH(2) terminal kinase) pathways are both required for bacteria-induced stem cell proliferation. Similarly, we demonstrate that indigenous gut microbiota activate the same, albeit reduced, program at basal levels. Altered control of gut microbiota in immune-deficient or aged flies correlates with increased epithelium renewal. Finally, we show that epithelium renewal is an essential component of Drosophila defense against oral bacterial infection. Altogether, these results indicate that gut homeostasis is achieved by a complex interregulation of the immune response, gut microbiota, and stem cell activity.

2009

The melanization reaction in Drosophila: More than black or white

Jan Paul Dudzic

EPFL2018

The double-edged toxins

Mario Gonzalo Garcia Arraez

EPFL2018