The immune regulation and epidemiological consequences of immune priming inDrosophila

Abstract

AbstractInvertebrates lack the specialized immune-memory cells responsible for vertebrate-like acquired immunity. However, there is increasing evidence that past infection by the same pathogen can ‘prime’ the insect immune response, resulting in improved survival upon reinfection. The mechanisms underlying these phenomenological accounts of priming are diverse, and often not completely clear. Here, we investigated the generality, specificity and mechanistic basis of immune priming in the fruit flyDrosophila melanogasterwhen infected with the gram-negative bacterial pathogenProvidencia rettgeri. We further explore the epidemiological consequences of immune priming and find it has the potential to curtail pathogen transmission by reducing pathogen shedding. We find that priming inDrosophilais a long-lasting, pathogen-specific response, occurring in several fly genetic backgrounds and is particularly stronger in male flies. Mechanistically, we find that the enhanced survival of individuals primed with an initial non-lethal bacterial inoculum coincides with a transient decrease in bacterial loads, and that this is likely driven by the IMD-responsive antimicrobial-peptideDiptericin-Bin the fat body. Further, we show that whileDiptericinsare required as the effector of bacterial clearance, it is not solely sufficient for immune priming, and requires regulation by the peptidoglycan recognition proteinsPGRP-LB, PGRP-LCandPGRP-LE. We discuss potential explanations for the observed sex differences in priming, and discuss the epidemiological consequences of innate immune priming in invertebrates.Author summaryImmunisation using attenuated or inactivated pathogens remains one of the most successful public health practices to reduce the incidence of infectious diseases. Immunisation works because humans and other vertebrate animals have evolved an immune response capable of specific immune memory, which ensures a strong, precise, and effective response to a secondary infection. While invertebrates lack the vertebrate-like specialized immune memory cells responsible for acquired immunity, there is now substantial evidence that invertebrates are capable of immune priming, characterised by improved survival to a pathogenic infection following an initial exposure to an attenuated or inactivated pathogen. Here, we investigated the occurrence, generality, specificity and mechanistic basis of immune priming in fruit flies when infected with the gram-negative pathogenProvidencia rettgeri. We find that priming with an initial non-lethal bacterial inoculum results increased survival after a secondary lethal challenge with the same live bacterial pathogen, and that this protective response may last at least two weeks after the initial exposure, is particularly strong in male flies, and occurs in several genetic backgrounds. We also find that primed flies shed less pathogen during infection, suggesting that priming can be a useful tool to reduce pathogen transmission in insects.