Microbiota-Dependent Priming of Antiviral Intestinal Immunity in Drosophila

Sansone, Christine Lynn; Cohen, Jonathan; Yasunaga, Ari; Xu, Jie; Osborn, Greg; Subramanian, Harry; Gold, Beth; Buchon, Nicolas; Cherry, Sara

doi:10.1016/j.chom.2015.10.010

Cited by 139 publications

(164 citation statements)

References 78 publications

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“…When these studies were extended to the gut epithelium, it was observed that priming by the microbiota was necessary for robust induction of Pvf2 in the intestinal epithelium following viral infection. The mechanism of priming of the microbiota however requires components of the Imd pathway (Imd, Tak1) and the NF-κB factor Relish, but not the Toll pathway [110], which seems in contrast to the previously mentioned study [94]. Both studies also found different effects of antibiotics on the antiviral defense mechanism (no effect: [94]; proviral effect: [110]).…”

Section: Involvement Of Innate Antimicrobial Immune Pathways (Toll Anmentioning

confidence: 75%

“…The necessity for tight control of immune pathways to prevent pathological damage from excessive activation has also been reported for the JAK/STAT pathway and is related to the concept of virus "tolerance" rather than "resistance" ( [79,151,152]; see also section 3.4). As already mentioned in section 3.2.4, RNAi screens identified a signaling circuit involving PVR, its ligand Pvf2 and ERK signaling, that controls DCV and arbovirus (including SINV) infections [110]. When these studies were extended to the gut epithelium, it was observed that priming by the microbiota was necessary for robust induction of Pvf2 in the intestinal epithelium following viral infection.…”

Section: Involvement Of Innate Antimicrobial Immune Pathways (Toll Anmentioning

confidence: 86%

“…Because of their importance to human health, emphasis was placed on arboviruses that are transmitted by mosquitoes but also can establish persistent infections in Drosophila cell lines and adult flies, such as SINV (Alphaviridae), RVFV and La Crosse virus (LACV) (Bunyaviridae), Dengue virus (DENV) and different strains of West Nile virus (WNV), such as the Kunjin strain (KUN) (Flaviviridae) and VSV (Rhabdoviridae) [109]. The Drosophila-specific pathogen DCV was also often included in the screens because it could serve as a model for pathogenic enterovirus infections in mammals [110], while other Drosophila-(Nora virus) or insect-specific viruses (FHV) were rarely included. Besides genome-wide screens, also targeted screens were performed, for instance targeting specific signaling pathways, immune genes, RNA helicases, RNA metabolism and endoplasmic reticulum (ER)-associated proteins [99,[111][112][113][114].…”

Section: Identification Of Host Factors That Restrict Viral Infectionmentioning

confidence: 99%

“…Further studies demonstrated the involvement of the nucleoporin Nup98, that also can function in transcription, and the transcription factor FoxK in the induction of the antiviral program [134,135], while also an antiviral function could be demonstrated for some of the induced genes such as the splicing factor B52 which was analyzed in more detail [135]. Targeted RNAi screens also identified the receptor tyrosine kinase PVR (Drosophila PDGF/VEGF receptor) and the ERK pathway as a broad-acting antiviral defense mechanism (restricting DCV, VSV, SINV and DENV; Table 1) [110,111]. Interestingly, in the intestinal epithelium this pathway is dependent on the gut microbiota that act by priming the gene encoding Pvf2, a ligand for the PVR receptor kinase, to be able to respond rapidly following viral infection through a mechanism that also involves transcriptional pausing [110].…”

Section: Broad Range Antiviral Defense Programsmentioning

confidence: 99%

“…Targeted RNAi screens also identified the receptor tyrosine kinase PVR (Drosophila PDGF/VEGF receptor) and the ERK pathway as a broad-acting antiviral defense mechanism (restricting DCV, VSV, SINV and DENV; Table 1) [110,111]. Interestingly, in the intestinal epithelium this pathway is dependent on the gut microbiota that act by priming the gene encoding Pvf2, a ligand for the PVR receptor kinase, to be able to respond rapidly following viral infection through a mechanism that also involves transcriptional pausing [110]. The antiviral immune mechanism in the gut epithelium is also dependent on the Imd pathway and will be discussed in greater detail below.…”

Section: Broad Range Antiviral Defense Programsmentioning

confidence: 99%

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Defense Mechanisms against Viral Infection in <em>Drosophila</em>: RNAi versus Non-RNAi

Swevers¹,

Liu²,

Smagghe³

2018

Preprint

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RNAi is considered a major antiviral defense mechanism in insects but its relative importance compared to other antiviral pathways has not been evaluated comprehensively. Here, it is attempted to give an overview of the antiviral defense mechanisms in Drosophila that involve both RNAi and non-RNAi to acquire a sense of their relative importance. While RNAi is considered important in most viral infections, many other pathways can exist that confer antiviral resistance. It is noted that very few direct recognition mechanisms of virus infections have been identified in Drosophila and that the activation of immune pathways may be accomplished indirectly through cell damage incurred by viral replication. In several cases, protection against viral infection can be obtained in RNAi mutants by non-RNAi mechanisms, confirming the variability of the RNAi defense mechanism according to the type of infection and the physiological status of the host. This analysis invites to investigate more systematically the relative contribution of RNAi in the antiviral response and more specifically to ask whether RNAi efficiency is affected when other defense mechanisms predominate. While Drosophila can function as a useful model, this issue may be more critical for economically important insects that are either controlled (agricultural pests and vectors of diseases) or protected from parasite infection (beneficial insects as bees) by RNAi products.

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Section: Involvement Of Innate Antimicrobial Immune Pathways (Toll Anmentioning

confidence: 75%

Section: Involvement Of Innate Antimicrobial Immune Pathways (Toll Anmentioning

confidence: 86%

Section: Identification Of Host Factors That Restrict Viral Infectionmentioning

confidence: 99%

Section: Broad Range Antiviral Defense Programsmentioning

confidence: 99%

Section: Broad Range Antiviral Defense Programsmentioning

confidence: 99%

See 3 more Smart Citations

Defense Mechanisms against Viral Infection in <em>Drosophila</em>: RNAi versus Non-RNAi

Swevers¹,

Liu²,

Smagghe³

2018

Preprint

View full text Add to dashboard Cite

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Tiny Drosophila intestinal stem cells, big power

Zhai¹,

Li²,

Liu³

et al. 2022

Cell Biology International

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The signaling pathways are highly conserved between Drosophila and mammals concerning intestinal development, regeneration, and disease. The powerful genetic tools of Drosophila make it a valuable and convenient alternative to answer basic biological questions that can not be addressed using mammalian models. In this review, we discuss recent advances in how we use fly midgut to answer the following key questions: (1) How intestine stem cell niches are established; (2) which factors control asymmetric division of stem cells; (3) how intestinal cells interact with environmental factors, such as tissue damage, microbiota, and diet; (4) how to screen aging/cancer-related factors or drugs by fly intestine stem cells.

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Analyses of locomotion, wing morphology, and microbiome in Drosophila nigrosparsa after recovery from antibiotics

et al. 2022

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Antibiotics, such as tetracycline, have been frequently used to cure arthropods of Wolbachia endosymbionts. After the symbionts have been removed, the hosts must recover for some generations from the side effects of the antibiotics. However, most studies do not assess the direct and indirect longer-term effects of antibiotics used to remove Wolbachia, which may question the exact contribution of this endosymbiont to the effects observed. Here, we used the fly Drosophila nigrosparsa treated or not with tetracycline for three generations followed by two generations of recovery to investigate the effects of this antibiotic on the fly locomotion, wing morphology, and the gut microbiome. We found that antibiotic treatment did not affect fly locomotion two generations after being treated with the antibiotic. In addition, gut-microbiome restoration was tested as a more efficient solution to reduce the potential side effects of tetracycline on the microbiome. There was no significant difference in alpha diversity between gut restoration and other treatments, but the abundance of some bacterial taxa differed significantly between the gut-restoration treatment and the control. We conclude that in D. nigrosparsa the recovery period of two generations after being treated with the antibiotic is sufficient for locomotion, and suggest a general assessment of direct and indirect effects of antibiotics after a particular recovery time.

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Microbiota-Dependent Priming of Antiviral Intestinal Immunity in Drosophila

Cited by 139 publications

References 78 publications

Defense Mechanisms against Viral Infection in <em>Drosophila</em>: RNAi versus Non-RNAi

Defense Mechanisms against Viral Infection in <em>Drosophila</em>: RNAi versus Non-RNAi

Tiny Drosophila intestinal stem cells, big power

Analyses of locomotion, wing morphology, and microbiome in Drosophila nigrosparsa after recovery from antibiotics

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