Project description:We used RNA-seq to discover that gene expression changes during aging are attenuated in elt-2 overexpressors relative to controls Whole-worm mRNA was sequenced from worms over-expressing elt-2 and control worms. Five biological replicates were collected for each condition.

Project description:We used RNA-seq to identify 292 genes that are differentially-regulated following elt-2 RNAi

Project description:We used RNA-seq to identify 292 genes that are differentially-regulated following elt-2 RNAi Whole-worm mRNA was sequenced from elt-2 RNAi- and control-fed worms. Biological triplicates were assay for each condition

Project description:We used RNA-seq to identify 162 genes that are differentially-regulated following elt-2 RNAi Whole-worm mRNA was sequenced from elt-2 RNAi- and control-fed worms. Biological triplicates were assay for each condition

Project description:We used RNA-seq to identify 162 genes that are differentially-regulated following elt-2 RNAi

Project description:Two GATA transcription factors, ELT-2 and ELT-7, function in the differentiation of the Caenorhabditis elegans intestine. Though loss of elt-7 causes no discernable phenotype on its own, it significantly enhances intestinal morphology defects in elt-2 loss-of-function mutants. We sought to identify the cohorts of gene targets unique to or shared by ELT-2 and ELT-7 in an effort to determine the logic underlying their differential impact on intestinal development.

Project description:In the past decade, the paradigm which claimed that invertebrate immune systems lack specificity has been reconsidered. Accumulating evidence supports that invertebrate immune systems are able to mount specific responses to the pathogen species-, and even to the pathogen strain-level. However, the underlying molecular mechanisms behind invertebrate immune specificity remain mostly unknown. Studying the molecular basis of invertebrate immune specificity in a genetically tractable model, such as the nematode Caenorhabditis elegans, has the potential to reveal insights into the immune systems of other metazoans, including humans. We chose to study the mechanisms of specific immune responses of the worm to two different pathogenic strains of the Gram-positive bacterium Bacillus thuringiensis (MYBY18247 and MYBT18679), because there is phenotypic evidence of specific genotype-genotype interactions between this host-pathogen pair. We did an initial RNA-Seq experiment upon pathogen exposure and found that 9% of the differentially expressed genes change their expression in different ways when comparing the two pathogen strains. Through promoter region motif enrichment analysis, we found the GATA transcription factor ELT-2 is responsible for the pathogen strain-specific transcriptomic response. Upon elt-2 knockdown worms exposed to MYBT18679 display lower survival rate coupled with higher intestinal damage than non-infected controls. Additionally, by performing further genetic analysis using gene knockdown and knockout, we found that the p38 MAPK pathway acts likely in parallel to elt-2 and the transcription factor skn-1 cooperates with elt-2 to promote resistance to MYBT18679. On the other hand, elt-2 knockdown leads to a substantially higher survival rate, together with lower intestinal tissue damage compared to control worms, upon exposure to MYBT18247, another pathogenic Bacillus thuringiensis strain. The MYBT18247 pathogen load of elt-2(RNAi) worms compared to control worms remained unchanged, suggesting the elt-2 negatively regulates tolerance towards MYBT18247. We found that tolerance to MYBT18247 was positively regulated by the transcription factors: FOXO daf-16, bZip zip-2, nhr-99 and nhr-193. To identify elt-2 negatively-regulated downstream targets that could promote tolerance to MYBT18247, we performed a second RNA-Seq experiment, this time including elt-2(RNAi) worms exposed to both pathogenic strains. We found four genes negatively regulated by elt-2: cdr-2, poml-3, dhs-30 and tre-3, with putative function in detoxification and lipid metabolism, which can mediate tolerance to MYBT18247. We conclude that ELT-2 coordinates strain-specific immune responses in this invertebrate host and promotes resistance upon exposure to MYBT18679, while it negatively regulates tolerance to MYBT18247. The response is likely to be specific to the crystal pore-forming toxins produced by this pathogen.

Project description:ELT-2 is the major transcription factor required for Caenorhabditis elegans intestinal development. It initiates in embryos to promote development then persists after hatching through larval and adult stages. Though the sites of ELT-2 binding are characterized and the transcriptional changes that result from ELT-2 depletion are described, a major missing piece has been the lack of an intestine-specific transcriptome profile over developmental time. We generated this dataset by Fluorescence Activated Cell Sorting (FACS) intestine cells at distinct developmental stages. We analyzed this dataset in conjunction with previously conducted ELT-2 studies to evaluate ELT-2’s role in directing the intestinal regulatory network through development. We found that only 33% of intestine-enriched genes in the embryo were direct targets of ELT-2 but that number increased to 75% by the L3 stage. This suggests additional transcription factors promote intestinal transcription especially in the embryo. Furthermore, only half of ELT-2’s direct target genes were dependent on ELT-2 for their proper expression levels, and an equal proportion of those responded to elt-2 depletion with over-expression as with under-expression. That is, ELT-2 can either activate or repress direct target genes. Indeed, we observed that ELT-2 repressed its own promoter, implicating new models for its autoregulation. Together, our results illustrate that ELT-2 impacts roughly 20 – 50% of intestine-specific genes, that ELT-2 both positively and negatively controls its direct targets, and that our current model of the intestinal regulatory network is incomplete as the factors responsible for directing the expression of many intestinal genes remain unknown.

Project description:We identified genome-wide sites of occupancy for the intestine-specific transcription factor ELT-2 in L3-staged N2 worm by performing ELT-2 ChIP-seq on whole worms; we performed RNA-seq on L3-staged N2 whole worms

Project description:We identified genome-wide sites of occupancy for the intestine-specific transcription factor ELT-2 in L3-staged N2 worm by performing ELT-2 ChIP-seq on whole worms; we performed RNA-seq on L3-staged N2 whole worms To identify DNA regions of direct ELT-2 occupancy, we performed the following ChIP-seq assays 1) ELT-2 ChIP-seq on L3 staged N2 C. elegans worms; 2) H3K4me3 ChIP-seq on matched L3 staged N2 worms; 3) Mock IgG-only ChIP-seq negative control on L3 stage N2 worms. Input DNA was also sequenced for each replicate. In addition, we performed RNA-seq on two replicates of L3 N2 C. elegans worms.