Abstract
All multicellular organisms are exposed to a diversity of infectious agents and to the emergence and proliferation of malignant cells. The protection conferred by some infections against cancer has been recently linked to the production of acquired immunity effectors such as antibodies. However, the evolution of innate immunity as a mechanism to prevent cancer and how it is jeopardized by infections remain poorly investigated. Here, we explored this question by performing experimental infections in two genetically modified invertebrate models (Drosophila melanogaster) that develop invasive or non-invasive neoplastic brain tumors. After quantifying tumor size and antimicrobial peptide gene expression, we found that Drosophila larvae infected with a naturally occurring bacterium had smaller tumors compared to controls and to fungus-infected larvae. This was associated with the upregulation of genes encoding two antimicrobial peptides—diptericin and drosomycin—that are known to be important mediators of tumor cell death. We further confirmed that tumor regression upon infection was associated with an increase in tumor cell death. Thus, our study suggests that infection could have a protective role through the production of antimicrobial peptides that increase tumor cell death. Finally, our study highlights the need to understand the role of innate immune effectors in the complex interactions between infections and cancer cell communities in order to develop innovative cancer treatment strategies.
Highlights
All multicellular organisms are exposed to a diversity of infectious agents and to the emergence and proliferation of malignant cells
We compared tumor growth in non-infected larvae and in larvae infected by the gram-negative bacterium Pectobacterium carotovorum carotovorum (Pcc) or by the fungal entomopathogen Beauvaria bassiana (Bb), both known to strongly stimulate antimicrobial peptides (AMP) production[36]
Analysis of tumor phenotype showed that larvae orally infected by the Pcc bacterium showed a 20% decrease in tumor size compared to uninfected ones (Fig. 1D; p = 0.004) and Bb infected ones (p = 0.026)
Summary
All multicellular organisms are exposed to a diversity of infectious agents and to the emergence and proliferation of malignant cells. The evolution of innate immunity as a mechanism to prevent cancer and how it is jeopardized by infections remain poorly investigated We explored this question by performing experimental infections in two genetically modified invertebrate models (Drosophila melanogaster) that develop invasive or non-invasive neoplastic brain tumors. Malignant cells have been omnipresent in the bodies of multicellular organisms for more than half a billion years[9], and in post-reproductive stages[10] They are involved in reciprocal interactions with microbes and parasites[11], setting the scene for fascinating, yet complex, tripartite interactions. The role of infectious pressures on tumor development in invertebrates has been poorly investigated, with the exception of studies on infectious neoplasia[28]
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