Mon travail de These a porte sur la description de l’immunite antibacterienne de la planaire, et plus particulierement la memoire immunitaire innee.La memoire immunitaire innee constitue une ligne de defense de l’hote a la reinfection qui ne fait intervenir que des composants de l’immunite innee. Presente chez les vertebres et les invertebres, ces derniers constituent un modele de choix car depourvus d’immunite acquise. La planaire dispose d’une memoire immunitaire innee envers S. aureus, qui, suite a une reinfection, se traduit par une elimination exacerbee. La depletion des planaires en cellules souches et la greffe tissulaire ont permis de mettre en avant les cellules souches comme acteurs principaux de cette reponse immunitaire. Un criblage RNAi associe a un profilage transcriptomique ont fait ressortir des genes en les hierarchisant au sein d’une voie de signalisation impliquant un recepteur au peptidoglycane (pgrp-2), une histone methyltransferase (setd8.1), et un mecanisme effecteur dans l’elimination bacterienne (p38 et morn2). Setd8.1, histone methyltransferase, se placerait au cœur du processus en deposant des marques epi-genetiques sur des loci de l’ADN, garantissant l’expression accrue des genes effecteurs suite a la reinfection. Ce mecanisme, decrit chez l’Homme, n’avait jusqu’alors jamais implique des cellules souches, ni ce type d’histone methyltransferase comme acteurs dans la memoire immunitaire innee.Collectivement, l’investigation du systeme immunitaire de la planaire a permis la decouverte de mecanismes de defense antibacterienne inedits, dont le transfert a l’Homme pourrait completer l’approche actuelle du traitement des maladies infectieuses.
Transcription factor EB (TFEB) is a key transcription factor that orchestrates the cellular response to stress. Dysregulation of TFEB is associated with a range of human diseases, and understanding the regulatory mechanisms of TFEB is crucial for identifying potential drug targets. In this study, we used Caenorhabditis elegans to screen for E3 ubiquitin ligases regulating the activity of TFEB's homolog, HLH-30, upon pathogenic infection. We identified WWP-1 as a regulator of HLH-30-dependent immune response controlling HLH-30 stability to mediate host defense in vivo. We found that HLH-30 interacts with WWP-1, supporting a model of WWP-1 directly regulating HLH-30. Furthermore, we found that WWP-1's human homolog WWP2 binds TFEB, directly induces TFEB ubiquitination and stabilizes TFEB. Finally, we found that WWP2 is required for TFEB-dependent host response in human monocytes-derived macrophages upon infection. Overall, our work has identified an evolutionarily conserved regulation of TFEB by WWP2 and highlighted its role in modulating stress response.
Little is known about how organisms exposed to recurrent infections adapt their innate immune responses. Here, we report that planarians display a form of instructed immunity to primo-infection by Staphylococcus aureus that consists of a transient state of heightened resistance to re-infection that persists for approximately 30 days after primo-infection. We established the involvement of stem cell-like neoblasts in this instructed immunity using the complementary approaches of RNA-interference-mediated cell depletion and tissue grafting-mediated gain of function. Mechanistically, primo-infection leads to expression of the peptidoglycan receptor Smed-PGRP-2, which in turn promotes Smed-setd8-1 histone methyltransferase expression and increases levels of lysine methylation in neoblasts. Depletion of neoblasts did not affect S. aureus clearance in primo-infection but, in re-infection, abrogated the heightened elimination of bacteria and reduced Smed-PGRP-2 and Smed-setd8-1 expression. Smed-PGRP-2 and Smed-setd8-1 sensitize animals to heightened expression of Smed-p38 MAPK and Smed-morn2, which are downstream components of anti-bacterial responses. Our study reveals a central role of neoblasts in innate immunity against S. aureus to establish a resistance state facilitating Smed-sted8-1-dependent expression of anti-bacterial genes during re-infection.
In the last decade, a major dogma in the field of immunology has been called into question by the identification of a cell autonomous innate immune memory. This innate immune memory (also named trained immunity) was found to be mostly carried by innate immune cells and to be characterized by an exacerbated inflammatory response with a heightened expression of proinflammatory cytokines, including TNF-α, IL-6 and IL-1β. Unlike the vast majority of cytokines, IL-1β is produced as a proform (pro-IL-1β) and requires a proteolytic cleavage to exert its biological action. This cleavage takes place mainly within complex molecular platforms named inflammasomes. These platforms are assembled upon both the infectious or sterile activation of NOD-like receptors (NLRs), thereby allowing for the recruitment and activation of caspases and the subsequent maturation of pro-IL-1β into IL-1β. The NLRP3 inflammasome has recently been implicated both in western diet-induced trained immunity, and in the detection of microbial virulence factors (effector-triggered immunity (ETI)). Here, we will attempt to link these two immune processes and provide arguments to hypothesize the existence of trained immunity triggered by microbial virulence factors (effector-triggered trained immunity (ETTI)).
Studies of tissue regeneration and host-pathogen interactions using the model planarian Schmidtea mediterranea have been performed at an experimental temperature of 19 °C. S. mediterranea planarians exposed to 19 °C-32 °C were observed for survival, mobility, feeding and regeneration for three months and elimination of the Staphylococcus aureus pathogen over six days. S. mediterranea planarians died at 30 °C-32 °C after 18 days of observation but tolerated temperatures of 19 °C up to 28 °C with non-significant differences in mobility and feeding behavior. Genetic malleability tested by RNAi feeding was still efficient at 26 °C and 28 °C. Concerning the immune capacity of planarians, we reported an exacerbation of the immune response in worms infected by S. aureus at 26 °C and 28 °C. These observations suggest a temperature modulation of planarian stem cells and illustrate the importance of modulating experimental temperature when using planarians as model organisms to study regeneration and immune response.
The strategies evolved by pathogens to infect hosts and the mechanisms used by the host to eliminate intruders are highly complex. Because several biological pathways and processes are conserved across model organisms, these organisms have been used for many years to elucidate and understand the mechanisms of the host-pathogen relationship and particularly to unravel the molecular processes enacted by the host to kill pathogens. The emergence of RNA interference (RNAi) and the ability to apply it toward studies in model organisms have allowed a breakthrough in the elucidation of host-pathogen interactions. The aim of this mini-review is to highlight and describe recent breakthroughs in the field of host-pathogen interactions using RNAi screens of model organisms. We will focus specifically on the model organisms Drosophila melanogaster, Caenorhabditis elegans and Danio rerio. Moreover, a recent study examining the immune system of Planarian will be discussed.
