Project description:Resistance to amebiasis is associated with a polymorphism in the leptin receptor. Previous studies demonstrated that humans with the ancestral Q223 leptin receptor allele were nearly four times less likely to be infected with Entamoeba histolytica than those carrying the mutant R223 allele. We hypothesized that the Q223 allele protected against E. histolytica via STAT3-mediated transcription of genes required for mucosal immunity. To test this, mice containing the humanized LEPR Q or R allele at codon 223 were intracecally infected with E. histolytica. Susceptibility to amebiasis was assessed, and cecal tissues analyzed for changes in gene expression. By 72 h post-challenge all Q223 mice had cleared E. histolytica, whereas 39% of 223R mice were infected. 37 genes were differentially expressed in response to infection at 72 h, including pro-inflammatory genes (CXCL2, calprotectin (S100A8/9), Pla2g7, Itbg2, and MMP9) and functions pertaining to the movement and activity of immune cells. A comparison at 12 h post-challenge of infected Q223 vs. R223 mice identified a subset of differentially-expressed genes, many of which were closely linked to leptin signaling. Further analyses indicated that the Q223 gene expression pattern was consistent with a suppressed apoptotic response to infection, while 223R showed increased cellular proliferation and recruitment. These studies are the first to illuminate the downstream effects of leptin receptor polymorphisms on intestinal infection by E. histolytica. As such, they are important for the insight that they provide to this previously uncharacterized mechanism of mucosal immunity. Resistance to amebiasis is associated with a polymorphism in the leptin receptor. Previous studies demonstrated that humans with the ancestral Q223 leptin receptor allele were nearly four times less likely to be infected with Entamoeba histolytica than those carrying the mutant R223 allele. We hypothesized that the Q223 allele protected against E. histolytica via STAT3-mediated transcription of genes required for mucosal immunity. To test this, mice containing the humanized LEPR Q or R allele at codon 223 were intracecally infected with E. histolytica. Susceptibility to amebiasis was assessed, and cecal tissues analyzed for changes in gene expression. By 72 h post-challenge all Q223 mice had cleared E. histolytica, whereas 39% of 223R mice were infected. 37 genes were differentially expressed in response to infection at 72 h, including pro-inflammatory genes (CXCL2, calprotectin (S100A8/9), Pla2g7, Itbg2, and MMP9) and functions pertaining to the movement and activity of immune cells. A comparison at 12 h post-challenge of infected Q223 vs. R223 mice identified a subset of differentially-expressed genes, many of which were closely linked to leptin signaling. Further analyses indicated that the Q223 gene expression pattern was consistent with a suppressed apoptotic response to infection, while 223R showed increased cellular proliferation and recruitment. These studies are the first to illuminate the downstream effects of leptin receptor polymorphisms on intestinal infection by E. histolytica. As such, they are important for the insight that they provide to this previously uncharacterized mechanism of mucosal immunity. Control (non-infected QQ or RR) vs. infected with E. histolytica at two time points (12hour and 72 hour)

Project description:Resistance to amebiasis is associated with a polymorphism in the leptin receptor. Previous studies demonstrated that humans with the ancestral Q223 leptin receptor allele were nearly four times less likely to be infected with Entamoeba histolytica than those carrying the mutant R223 allele. We hypothesized that the Q223 allele protected against E. histolytica via STAT3-mediated transcription of genes required for mucosal immunity. To test this, mice containing the humanized LEPR Q or R allele at codon 223 were intracecally infected with E. histolytica. Susceptibility to amebiasis was assessed, and cecal tissues analyzed for changes in gene expression. By 72 h post-challenge all Q223 mice had cleared E. histolytica, whereas 39% of 223R mice were infected. 37 genes were differentially expressed in response to infection at 72 h, including pro-inflammatory genes (CXCL2, calprotectin (S100A8/9), Pla2g7, Itbg2, and MMP9) and functions pertaining to the movement and activity of immune cells. A comparison at 12 h post-challenge of infected Q223 vs. R223 mice identified a subset of differentially-expressed genes, many of which were closely linked to leptin signaling. Further analyses indicated that the Q223 gene expression pattern was consistent with a suppressed apoptotic response to infection, while 223R showed increased cellular proliferation and recruitment. These studies are the first to illuminate the downstream effects of leptin receptor polymorphisms on intestinal infection by E. histolytica. As such, they are important for the insight that they provide to this previously uncharacterized mechanism of mucosal immunity. Resistance to amebiasis is associated with a polymorphism in the leptin receptor. Previous studies demonstrated that humans with the ancestral Q223 leptin receptor allele were nearly four times less likely to be infected with Entamoeba histolytica than those carrying the mutant R223 allele. We hypothesized that the Q223 allele protected against E. histolytica via STAT3-mediated transcription of genes required for mucosal immunity. To test this, mice containing the humanized LEPR Q or R allele at codon 223 were intracecally infected with E. histolytica. Susceptibility to amebiasis was assessed, and cecal tissues analyzed for changes in gene expression. By 72 h post-challenge all Q223 mice had cleared E. histolytica, whereas 39% of 223R mice were infected. 37 genes were differentially expressed in response to infection at 72 h, including pro-inflammatory genes (CXCL2, calprotectin (S100A8/9), Pla2g7, Itbg2, and MMP9) and functions pertaining to the movement and activity of immune cells. A comparison at 12 h post-challenge of infected Q223 vs. R223 mice identified a subset of differentially-expressed genes, many of which were closely linked to leptin signaling. Further analyses indicated that the Q223 gene expression pattern was consistent with a suppressed apoptotic response to infection, while 223R showed increased cellular proliferation and recruitment. These studies are the first to illuminate the downstream effects of leptin receptor polymorphisms on intestinal infection by E. histolytica. As such, they are important for the insight that they provide to this previously uncharacterized mechanism of mucosal immunity.

Project description:Entamoeba histolytica, the agent of amebiasis, colonizes the human colon and can invade the lining of the colon to disseminate in the deep layers of the intestine. Amebiasis mainly affects poor people in developing countries, where the barriers between human feces and food or water are inadequate. Humans are the only reservoir of E. histolytica and are the sole target organism of the development of the disease, which limits our knowledge of the crosstalk between the colon and the parasite, especially during the acute phase of amebiasis. In the present work, we constructed a three-Dimensional (3D)-intestinal model capable of reproducing important features of the human intestine. Using this model and leading-edge technologies, including tissue and cell imaging, transcriptomics, and proteomics, as well as ELISA-based immune response inspection, the early stages of amebic infection have been studied. The data obtained highlight the importance of several virulence markers already shown in patients or experimental models, but also underscore the involvement of other factors that appear to be key regulators of gene expression or important in the secretome of the infected tissue. In addition, we characterized the cellular stress responses against amebiasis and novel regulatory mechanisms utilized by this parasite to modulate the immune response and survive within the human intestine.

Project description:We provided a full spectrum analysis for E. histolytica AGO2-2 associated 27nt small RNAs. Additionally, comparative analysis of small RNA populations from virulent and non-virulent amebic strains indicates that small RNA populations may regulate virulence genes.

Project description:We provided a full spectrum analysis for E. histolytica AGO2-2 associated 27nt small RNAs. Additionally, comparative analysis of small RNA populations from virulent and non-virulent amebic strains indicates that small RNA populations may regulate virulence genes. AGO2-2 bound small RNAs from E. histolytica strain HM-1:IMSS were immunoprecipitated and sequenced using 454 technology. Three independant sequencing runs were perfomed using the same RNA sample. In addition, size selected small RNAs from E. histolytica strain Rahman were sequenced with the same technology. One sequencing run was performed on this sample.

Project description:The Effect of the Leptin Receptor Q223R Polymorphism on the Host Transcriptome Following Infection with E. histolytica.

Project description:Entamoeba histolytica is a protozoan parasite responsible for amebiasis, a disease which is characterized by acute inflammation of the colon. Adaptation of the parasite to toxic level of nitric oxide (NO) produced by phagocytes may be essential for the establishment of chronic amebiasis and for the survival of parasite within the host. To obtain insight into the mechanism of adaptation to NO, E. histolytica trophozoites were selected in vitro by stepwise exposures to increasing amounts of NO donor S-Nitrosoglutathione (GSNO) up to a concentration of 110 µM. These NO adapted trophozoites (NAT) were more resistance to acute exposure of GSNO (350μM), to activated macrophages and have a better capability to invade porcine colon explants compared to wild-type trophozoites. The transcriptome of NAT was investigated by RNA-sequencing (RNA-seq) and it showed only a weak overlapping with the transcriptome of trophozoites exposed to acute nitrosative stress (TEANS).

Project description:Leptin protects hosts cells from E. histolytica cytotoxicity via a STAT-3 dependent mechanism

Project description:Entamoeba histolytica contains a large and novel family of transmembrane kinases (TMK) with proposed roles that include both amebic response to the environment and immune evasion. In the later case, the process requires several elements --these include a large gene family encoding antigenically distinct surface proteins and the expression of one variant antigen at a time by a single pathogen. Laser-capture microdissection was used in conjunction with microarray analysis to demonstrate that single trophozoites express more than one TMK gene. Overall, our data indicates that multiple members of the novel E. histolytica TMK family are utilized for non-redundant functions by the parasite.

Project description:Enteric protozoan parasite Entamoeba histolytica is a causative agent of amebiasis. One of the major virulence factors of this parasite is cysteine protease (CP). To understand the molecular basis of intracellular trafficking of CP, we identified CP5 binding protein and named cysteine protease binding protein family 1 (CPBF1). To study the function of CPBF1, we generate CPBF1 gene silenced strain and analyzed the expression profile by custom made microarray. E. histolytica G3 strain was transfected with pSAP2 vector or pSAP2-CPBF1 and established the transformats by selecting the transfected cells with G418. After confirm the gene silencing of CPBF1 by RT-PCR, we performed the transcriptome analysis of pSAP2 (mock) and pSAP2-CPBF1 (gene silenced) cells.