Cecropins contribute to Drosophila host defense against a subset of fungal and Gram-negative bacterial infection

Cecropins are small helical secreted peptides with antimicrobial activity that are widely distributed among insects. Genes encoding Cecropins are strongly induced upon infection, pointing to their role in host defense. In Drosophila, four cecropin genes clustered in the genome (CecA1, CecA2, CecB, and CecC) are expressed upon infection downstream of the Toll and Imd pathways. In this study, we generated a short deletion Delta Cec(A-C) removing the whole cecropin locus. Using the Delta Cec(A-C) deficiency alone or in combination with other antimicrobial peptide (AMP) mutations, we addressed the function of Cecropins in the systemic immune response. Delta Cec(A-C) flies were viable and resisted challenge with various microbes as wild-type. However, removing Delta Cec(A-C) in flies already lacking 10 other AMP genes revealed a role for Cecropins in defense against Gram-negative bacteria and fungi. Measurements of pathogen loads confirm that Cecropins contribute to the control of certain Gram-negative bacteria, notably Enterobacter cloacae and Providencia heimbachae. Collectively, our work provides the first genetic demonstration of a role for Cecropins in insect host defense and confirms their in vivo activity primarily against Gram-negative bacteria and fungi. Generation of a fly line (Delta AMP14) that lacks 14 immune inducible AMPs provides a powerful tool to address the function of these immune effectors in host-pathogen interactions and beyond.

Iron sequestration by transferrin 1 mediates nutritional immunity in Drosophila melanogaster

Jean Philippe Boquete, Igor Iatsenko, Bruno Lemaitre, Alice Marra, Jasquelin Peña

Iron sequestration is a recognized innate immune mechanism against invading pathogens mediated by iron-binding proteins called transferrins. Despite many studies on antimicrobial activity of transferrins in vitro, their specific in vivo functions are poorly understood. Here we use Drosophila melanogaster as an in vivo model to investigate the role of transferrins in host defense. We find that systemic infections with a variety of pathogens trigger a hypoferremic response in flies, namely, iron withdrawal from the hemolymph and accumulation in the fat body. Notably, this hypoferremia to infection requires Drosophila nuclear factor kappa B (NF-kappa B) immune pathways, Toll and Imd, revealing that these pathways also mediate nutritional immunity in flies. Next, we show that the iron transporter Tsf1 is induced by infections downstream of the Toll and Imd pathways and is necessary for iron relocation from the hemolymph to the fat body. Consistent with elevated iron levels in the hemolymph, Tsf1 mutants exhibited increased susceptibility to Pseudomonas bacteria and Mucorales fungi, which could be rescued by chemical chelation of iron. Furthermore, using siderophore-deficient Pseudomonas aeruginosa, we discover that the siderophore pyoverdine is necessary for pathogenesis in wild-type flies, but it becomes dispensable in Tsf1 mutants due to excessive iron present in the hemolymph of these flies. As such, our study reveals that, similar to mammals, Drosophila uses iron limitation as an immune defense mechanism mediated by conserved iron-transporting proteins transferrins. Our in vivo work, together with accumulating in vitro studies, supports the immune role of insect transferrins against infections via an iron withholding strategy.

NATL ACAD SCIENCES2020

The contribution of the host stress response to the pathogenesis of Pseudomonas entomophila in the Drosophila intestine

Sveta Chakrabarti

Recently, several studies done in Drosophila have revealed that efficient and rapid recovery from bacterial infection in the gut is possible only when bacterial clearance by the immune system is coordinated with repair through renewal of the epithelium damaged by infection. In this thesis, I have analyzed how the entomopathogenic bacterium Pseudomonas entomophila affects the immune response and epithelium renewal. A microarray analysis first showed that P. entomophila is recognized by the Drosophila immune system since ingestion of this bacterium stimulated the expression of antimicrobial peptide genes by the Imd pathway. In addition, stress and damage related pathways were strongly induced by P. entomophila, which correlate with its capacity to inflict severe damage. While antibacterial genes were induced in the gut following infection with P. entomophila, the immune response was not productive due to a general inhibition of translation that affected all the newly synthesized transcripts. Furthermore, the blockage of translation also inhibited the repair program by blocking the production of JAK-STAT ligands (upd3, upd2) and growth factors, which stimulate the intestinal stem cells proliferation and differentiation. I next analyzed the pathways that link cellular damage to reduction of translation. Using a genetic approach, I showed that inhibition of translation was induced by two signaling pathways: i) the phosphorylation of elongation initiation factor 2α (eIF2α) by the stress kinase GCN2 and ii) the inhibition of the TOR pathway by the AMPK kinase. Both kinases sense metabolic deprivation, suggesting that cellular damages induced by P. entomophila induce a state of “starvation”. Inhibition of translation is usually an adaptive cellular response to adjust the metabolism to the energy status of the cells. The observation that GCN2-deficient flies survived better than wild-type flies to P. entomophila indicates that pathogenesis is linked to an over-activation of stress pathways that usually help to endure the consequence of an infection. In this in vivo model of infection, I also showed that the reduction of translation was a consequence of cellular damage to the intestine caused by host-derived reactive oxygen species (through the activity of Duox) and by the direct action of a pore-forming toxin produced by the pathogen. As a consequence of this translational arrest, flies succumbed P. entomophila infection because they were unable to repair gut damage. Finally, I showed that inhibition of translation also had a strong influence on innate immune responses observed upon P. entomophila infection. The specific activation of a systemic immune response (antimicrobial peptides produced by the fat body) observed upon P. entomophila infection could be recapitulated by feeding flies with a non-lethal pathogen and an inhibitor of translation. Hence, I showed translation inhibition could be an important feature that shapes the immune response. The p38 MAPK family is involved in stress and immunity in both mammals and Drosophila. In Drosophila, three p38-MAPK-encoding genes, p38a, p38b and p38c, have been identified but their function in the gut immune response is poorly characterized. In the second part of my thesis, I have analyzed the role of these three p38 MAPKs in Drosophila intestinal immunity, especially p38c, which is strongly enriched in the gut. I first confirmed that the three p38 are involved kinases are involved in the defense to oral infection with pathogenic (but non-lethal) bacteria such as Erwinia carotovora 15. Surprisingly, p38c mutant flies were more resistant to P. entomophila and did not show the reduction in translation observed in wild-type flies. Interestingly, the transcription of the ROS producing enzyme Duox was reduced in p38c raising the hypothesis that p38 contributes to P. entomophila pathogenicity by activating Duox. Furthermore, I have obtained preliminary data indicating that p38c and the transcription factor ATF-3 act in the same pathway contributing the host immune response and lipid metabolism. Together, my thesis reveals the complex cross-talks between stress and immune pathways during microbial infection. While, it shows that stress pathways usually contribute to endure the damage caused by infection, excessive activation of these pathways can contribute to pathogenesis.

EPFL2013

Prevalence of local immune response against oral infection in a Drosophila/Pseudomonas infection model

Bruno Lemaitre

Pathogens have developed multiple strategies that allow them to exploit host resources and resist the immune response. To study how Drosophila flies deal with infectious diseases in a natural context, we investigated the interactions between Drosophila and a newly identified entomopathogen, Pseudomonas entomophila. Flies orally infected with P. entomophila rapidly succumb despite the induction of both local and systemic immune responses, indicating that this bacterium has developed specific strategies to escape the fly immune response. Using a combined genetic approach on both host and pathogen, we showed that P. entomophila virulence is multi-factorial with a clear differentiation between factors that trigger the immune response and those that promote pathogenicity. We demonstrate that AprA, an abundant secreted metalloprotease produced by P. entomophila, is an important virulence factor. Inactivation of aprA attenuated both the capacity to persist in the host and pathogenicity. Interestingly, aprA mutants were able to survive to wild-type levels in immune-deficient Relish flies, indicating that the protease plays an important role in protection against the Drosophila immune response. Our study also reveals that the major contribution to the fly defense against P. entomophila is provided by the local, rather than the systemic immune response. More precisely, our data points to an important role for the antimicrobial peptide Diptericin against orally infectious Gram-negative bacteria, emphasizing the critical role of local antimicrobial peptide expression against food-borne pathogens.

2006

The contribution of the host stress response to the pathogenesis of Pseudomonas entomophila in the Drosophila intestine

Sveta Chakrabarti

EPFL2013