All live beings are in constant interaction with microorganisms that may be beneficial, deleterious or commensal. Insects in particular live in close contact with microorganisms. This is especially true for species, like the fruit fly Drosophila melanogaster that feed, lay eggs and develop on or close to decomposing organic matter. In contrast to vertebrates, insects did not evolve an adaptive immune system to combat pathogens selectively. They instead rely on surprisingly efficient innate defense mechanisms for the control and clearance of all microbes without any species-specific targeting. Innate immunity encompasses a wide range of mechanisms that rely on direct pathogen recognition and elimination. In addition, metabolic and behavioral responses also strongly affect the outcome of insect interactions with both pathogenic and non-pathogenic bacteria. Although the Drosophila immune system has been extensively described, little is known about the role of immune effectors in tolerating and controlling symbiotic microbes.
For this reason, during my PhD studies, I investigated how Drosophila melanogaster immune effectors differentially interact with mutualistic symbionts. First, I investigated the role of some of the host antimicrobials, called antimicrobial peptides and lysozymes, in maintaining the homeostasis of the gut microbiota. I found that both antimicrobial peptides and lysozymes can actively regulate the gut microbiota composition and abundancy, especially during aging.
In a second part of my thesis, I got interested in Spiroplasma, a heritable symbiotic bacterium that lives within the fly hemolymph. I characterized the role of the Drosophila iron transporter Transferrin 1 (Tsf1) during Spiroplasma-Drosophila symbiosis. I first showed that mutant flies for tsf1 have an impaired Spiroplasma load, due to iron relocation from the hemolymph to the fat body, where it becomes inaccessible for Spiroplasma. Furthermore, I demonstrated that Spiroplasma scavenges host iron only when it is bound to the protein, which points to Tsf1 and iron transport as a control mechanism for hemolymphatic symbionts.
Collectively, my studies contribute to a better understanding of how the innate immune effectors interact with Drosophila microbial symbionts to both regulate and maintain stable, long-lasting, interactions.