Project description:Toxoplasma gondii is an intracellular parasite with a significant impact on human health, especially in cases where individuals are immunocompromised (e.g., due to HIV/AIDS). In Europe and North America only a few clonal genotypes appear to be responsible for the vast majority of Toxoplasma infections, and these clonotypes have been intensely studied to identify strain-specific phenotypes that may play a role in the manifestation of more severe disease. To identify and genetically map strain-specific differences in gene expression, we have carried out expression quantitative trait locus (eQTL) analysis on Toxoplasma gene expression phenotypes using spotted cDNA microarrays. This led to the identification of 16 Toxoplasma genes that had significant and mappable strain-specific variation in hybridization intensity. While the analysis should identify both cis and trans-mapping hybridization profiles, we only identified loci with strain-specific hybridization differences that are most likely due to differences in the locus itself (i.e., cis-mapping). Interestingly, a larger number of these cis-mapping genes than would be expected by chance encode either confirmed or predicted secreted proteins, many of which are known to localize to the specialized secretory organelles characteristic of members of the phylum Apicomplexa. For 6 of the cis-mapping loci we determined if the strain-specific hybridization differences were due to true transcriptional differences or rather strain-specific differences in hybridization efficiency because of extreme polymorphism and/or deletion, and we found examples of both scenarios. Keywords: eQTL mapping; virulence; Toxoplasma gondii 19 F1 progeny from a cross between a type II parent (PDS) and a type III parent (CTG) were used in RNA hybridizations to identify cis and trans-mapping loci regulating gene expression

Project description:This SuperSeries is composed of the following subset Series: GSE11437: Expression QTL mapping of Toxoplasma gondii genes, Bradyzoite array GSE11514: Expression QTL mapping of Toxoplasma gondii genes, Tachyzoite array Keywords: SuperSeries Refer to individual Series

Project description:Toxoplasma gondii is an intracellular parasite with a significant impact on human health, especially in cases where individuals are immunocompromised (e.g., due to HIV/AIDS). In Europe and North America only a few clonal genotypes appear to be responsible for the vast majority of Toxoplasma infections, and these clonotypes have been intensely studied to identify strain-specific phenotypes that may play a role in the manifestation of more severe disease. To identify and genetically map strain-specific differences in gene expression, we have carried out expression quantitative trait locus (eQTL) analysis on Toxoplasma gene expression phenotypes using spotted cDNA microarrays. This led to the identification of 16 Toxoplasma genes that had significant and mappable strain-specific variation in hybridization intensity. While the analysis should identify both cis and trans-mapping hybridization profiles, we only identified loci with strain-specific hybridization differences that are most likely due to differences in the locus itself (i.e., cis-mapping). Interestingly, a larger number of these cis-mapping genes than would be expected by chance encode either confirmed or predicted secreted proteins, many of which are known to localize to the specialized secretory organelles characteristic of members of the phylum Apicomplexa. For 6 of the cis-mapping loci we determined if the strain-specific hybridization differences were due to true transcriptional differences or rather strain-specific differences in hybridization efficiency because of extreme polymorphism and/or deletion, and we found examples of both scenarios. Keywords: eQTL mapping; virulence; Toxoplasma gondii

Project description:Toxoplasma gondii is an intracellular parasite with a significant impact on human health, especially in cases where individuals are immunocompromised (e.g., due to HIV/AIDS). In Europe and North America only a few clonal genotypes appear to be responsible for the vast majority of Toxoplasma infections, and these clonotypes have been intensely studied to identify strain-specific phenotypes that may play a role in the manifestation of more severe disease. To identify and genetically map strain-specific differences in gene expression, we have carried out expression quantitative trait locus (eQTL) analysis on Toxoplasma gene expression phenotypes using spotted cDNA microarrays. This led to the identification of 16 Toxoplasma genes that had significant and mappable strain-specific variation in hybridization intensity. While the analysis should identify both cis and trans-mapping hybridization profiles, we only identified loci with strain-specific hybridization differences that are most likely due to differences in the locus itself (i.e., cis-mapping). Interestingly, a larger number of these cis-mapping genes than would be expected by chance encode either confirmed or predicted secreted proteins, many of which are known to localize to the specialized secretory organelles characteristic of members of the phylum Apicomplexa. For 6 of the cis-mapping loci we determined if the strain-specific hybridization differences were due to true transcriptional differences or rather strain-specific differences in hybridization efficiency because of extreme polymorphism and/or deletion, and we found examples of both scenarios. Keywords: eQTL mapping; virulence; Toxoplasma gondii

Project description:This SuperSeries is composed of the following subset Series: GSE26558: Expression Quantitative Trait Locus (eQTL) Mapping of Stage-specific Gene Expression in Progeny from a type I X III Genetic Cross of Toxoplasma gondii GSE26607: Genomic hybridizations for the parents and progeny of the Toxoplasma gondii I X III genetic cross Refer to individual Series

Project description:Toxoplasma gondii is a ubiquitous protozoan pathogen able to infect both mammalian and avian hosts. Surprisingly, just three strains appear to account for the majority of isolates from Europe and N. America. To test the hypothesis that strain divergence might be driven by differences between mammalian and avian response to infection, we examine in vitro strain-dependent host responses in a representative avian host, the chicken. Chicken embryonic fibroblasts were cultivated in vitro and infected with different strains of Toxoplasma gondii; host transcriptional responses were then analyzed at 24 hours post-infection.

Project description:Toxoplasma gondii is a ubiquitous protozoan pathogen able to infect both mammalian and avian hosts. Surprisingly, just three strains appear to account for the majority of isolates from Europe and N. America. To test the hypothesis that strain divergence might be driven by differences between mammalian and avian response to infection, we examine in vitro strain-dependent host responses in a representative avian host, the chicken. Chicken embryonic fibroblasts were cultivated in vitro and infected with different strains of Toxoplasma gondii (Type II = ME49, Type III = CEP); host transcriptional responses were then analyzed at 24 hours post-infection.

Project description:Distinct genotypic and pathogenicity differences exist between strains of the opportunistic protozoan Toxoplasma gondii. The label-free quantitative acetylomics approach was applied to investigate the differences in the level of acetylation between RH strain, PRU strain and PYS strain of T. gondii. The results showed that lysine acetylation in RH strain was the largest (458 acetylated proteins) among the three strains. The PYS strain had the second-largest acetylome (188 acetylated proteins), whereas lysine acetylation in PRU strain (115 acetylated proteins) was the smallest. Motif analysis revealed four, three and four motifs enriched from lysine acetylation sequences in RH strain, PRU strain and PYS strain respectively, suggesting specificity of acetyltransferases in these strains. Our analysis also identified 15 DAPs (differentially expressed acetylated proteins), 3 DAPs and 26 DAPs in RH strain vs PRU strain, PRU strain vs PYS strain and PYS strain vs RH strain, respectively. Compared with PYS strain and PRU strain, histone acetyltransferase and glycyl-tRNA synthase had higher expression levels in RH strain, reflecting genotype-specific differences in stress tolerance. These findings provide novel insight into the acetylomic profiles of major genotypes of T. gondii and provide an important resource for further analysis of the roles of the acetylated parasite proteins in the regulation of cellular functions.

Project description:Toxoplasma gondii is a ubiquitous protozoan pathogen able to infect both mammalian and avian hosts. Surprisingly, just three strains appear to account for the majority of isolates from Europe and N. America. To test the hypothesis that strain divergence might be driven by differences between mammalian and avian response to infection, we examine in vitro strain-dependent host responses in a representative avian host, the chicken. To identify parasite drivers of strain-dependent host response, QTL mapping was used; analysis revealed a locus on Toxoplasma chromosome VIIb. To determine whether this was the parasite gene ROP16, array analysis was performed on chicken embryonic fibroblasts infected with Type I parasites and ROP16-KO parasites (of a Type I background). Chicken embryonic fibroblasts were cultivated in vitro and infected with either Type I (RH) parasites or Type I ROP16-KO parasites; ROP16-dependent host transcriptional responses were then analyzed at 5 hours post-infection.

Project description:The population structure of Toxoplasma gondii includes three highly prevalent clonal lineages, types I, II, and III, which differ greatly in virulence in the mouse model. Previous studies have implicated a family of serine threonine protein kinases found in rhoptries (ROPs) as important in mediating virulence differences between types I vs. III and II vs. III. Here, we explored the genetic basis of differences in virulence between the highly virulent type I lineage and moderately virulent type II based on a new genetic cross and linkage mapping. Genome-wide association revealed a single quantitative trait locus controls the > 4 log difference in lethality between these strains. Neither ROP16 nor ROP18, previously implicated in virulence differences in T. gondii, were found to contribute to differences between types I and II. Instead, the major virulence locus contained a cluster of pseudokinases denoted as rhoptry protein 5 (ROP5); this locus contains a tandem cluster of polymorphic alleles that differed in expression levels between strains. ROP5 alleles contained only part of the catalytic triad of canonical S/T kinases, and consistent with this they lack demonstrable kinase activity in vitro. Genetic disruption of the rop5 locus in the type I lineage lead to a > 5 log increase in the lethal dose, and surviving mice developed lasting immunity and were protected from an otherwise lethal challenge. These findings reveal that amplification of a polymorphic cluster of pseudokinases plays an important role in pathogenesis of toxoplasmosis in the mouse model. We used a new genotyping protocol based on hybridization of parental and recombinant progeny genomic DNA (gDNA) to Affymetrix gene arrays constructed for T. gondii (http://ancillary.toxodb.org/docs/Array-Tutorial.html). We identified 1,603 single feature polymorphisms (SFP) based on probes that successfully discriminated perfect match (type II) from mismatch (type I) hybridization across all clones and provided reliable SFP markers for this cross.