Project description:Intracellular parasites reprogram the host functions for their survival and reproduction. Conversely, the infected host attempts to defend the microbial insult. The extent and relevance of parasite-mediated host response in vivo remains poorly studied. We utilized Eimeria falciformis, an obligate intracellular parasite completing its entire life cycle in the mouse intestinal epithelium, to identify and validate the host determinants of the parasite infection. The most prominent mouse genes induced during the onset of asexual (24 hrs) and sexual (144 hrs) parasite cycle include IFNg-regulated factors, e.g., immunity-related GTPases IRGA6/B6/D/M2/M3, guanylate-binding proteins GBP2/3/5/8, chemokines CxCL9-11 and several enzymes of the kynurenine pathway including indoleamine 2,3-dioxygenase 1 (IDO1). These results indicated a multifarious innate defense (tryptophan catabolism, IRG, GBP, chemokines signaling) mounted by epithelial cells, and a consequential adaptive immune response (chemokines-cytokines signaling, lymphocyte recruitment). A notable increase in the inflammation- and immunity-associated transcripts correlated with the severity of infection and influx of B-cells, T-cells and macrophages to the parasitized tissue. Indeed, parasite growth was enhanced in the animals inhibited for CxCr3, a major chemokine receptor on immune cells. Interestingly, despite a prominent induction, the mouse IRGB6 failed to recognize and disrupt the parasitophorous vacuole in the parasite cultures, implying an immune evasion by E. falciformis. Likewise, the oocyst output was impaired in IFNg-R-/- and IDO1-/- mice, which signifies a subversion of IFNg-signaling by the parasite to promote its growth. In brief, the Eimeria-rodent model shows contrasting roles of IFNg-signaling for parasite development, identifies a retinue of potential host determinants, and epitomizes its efficacy for in vivo parasite-host interaction studies. Microarray experiments were performed as dual-color hybridizations on Agilent mouse whole genome catalog 44K arrays. To compensate for dye-specific effects, a dye-reversal color-swap was applied.

Project description:Intracellular parasites reprogram the host functions for their survival and reproduction. Conversely, the infected host attempts to defend the microbial insult. The extent and relevance of parasite-mediated host response in vivo remains poorly studied. We utilized Eimeria falciformis, an obligate intracellular parasite completing its entire life cycle in the mouse intestinal epithelium, to identify and validate the host determinants of the parasite infection. The most prominent mouse genes induced during the onset of asexual (24 hrs) and sexual (144 hrs) parasite cycle include IFNg-regulated factors, e.g., immunity-related GTPases IRGA6/B6/D/M2/M3, guanylate-binding proteins GBP2/3/5/8, chemokines CxCL9-11 and several enzymes of the kynurenine pathway including indoleamine 2,3-dioxygenase 1 (IDO1). These results indicated a multifarious innate defense (tryptophan catabolism, IRG, GBP, chemokines signaling) mounted by epithelial cells, and a consequential adaptive immune response (chemokines-cytokines signaling, lymphocyte recruitment). A notable increase in the inflammation- and immunity-associated transcripts correlated with the severity of infection and influx of B-cells, T-cells and macrophages to the parasitized tissue. Indeed, parasite growth was enhanced in the animals inhibited for CxCr3, a major chemokine receptor on immune cells. Interestingly, despite a prominent induction, the mouse IRGB6 failed to recognize and disrupt the parasitophorous vacuole in the parasite cultures, implying an immune evasion by E. falciformis. Likewise, the oocyst output was impaired in IFNg-R-/- and IDO1-/- mice, which signifies a subversion of IFNg-signaling by the parasite to promote its growth. In brief, the Eimeria-rodent model shows contrasting roles of IFNg-signaling for parasite development, identifies a retinue of potential host determinants, and epitomizes its efficacy for in vivo parasite-host interaction studies.

Project description:Successful asexual reproduction of intracellular pathogens depend on their potential to exploit host resources and subvert antimicrobial defense. Here, we deployed two prevalent intracellular parasites of mammalian cells, namely Toxoplasma gondii and Eimeria falciformis, to identify the potential host determinants of infection. Expression analyses of the young adult mouse colonic (YAMC) epithelial cells showed regulation of several distinct transcripts upon infection by either parasite, indicating that closely-related pathogens program their intracellular niches in notably adaptive manner. Conversely, parasitized mouse embryonic fibroblasts (MEFs) exhibited a divergent transcriptome compared to corresponding YAMC cells, suggesting that individual host cells mount fairly discrete response while encountering a given pathogen. Among a limited set of factors similarly regulated by both parasites, we identified cFos, a master transcription factor, that was consistently induced throughout infection. Indeed, the asexual development of T. gondii and E. falciformis was severely impaired in MEF cells lacking cFos expression. Last but not least, our comparative transcriptomics of the parasitized MEFs (wild-type and cFos-/- mutant) and YAMC epithelial cells disclosed a cFos-network, underlying signal transduction cascades, as well as a repertoire of nucleotides-binding and ion-binding proteins, which are likely co-opted by coccidian pathogens to acclimatize the mammalian host environment.

Project description:antibiotic treatment changed the Eimeria falciformis infection

Project description:16S rRNA sequencing of Eimeria falciformis Infection mice

Project description:Eimeria tenella (Coccidian parasite)

Project description:Eimeria praecox (Coccidian parasite)

Project description:Eimeria mitis (Coccidian parasite)

Project description:Eimeria acervulina (Coccidian parasite)

Project description:Eimeria maxima (Coccidian parasite)