Project description:Acyl-coA synthases (ACSs) produce fatty acyl-CoAs that are used in metabolic and signaling pathways. Metazoans have a large number of ACS genes with differing expression patterns and substrate preferences, but the physiological roles of most ACS genes are unknown. Here, we focused on the C. elegans acyl CoA synthase, ACS-3, which is known to regulate fat uptake and de novo fat synthesis through the conserved nuclear hormone receptor, nhr-25. We performed microarray analysis of acs-3 mutants to elucidate the acs-3-regulated transcription program. This analysis revealed an enrichment among differentially regulated genes of those involved in lipid metabolism, pathogen and wounding responses, and sterol binding genes, among others. As the immunity genes were the most represented gene class, we performed pathogen sensitivity assays to test the phenotypic consequences of this immune gene regulation. Interestingly, acs-3 mutants were hypersensitive to the fungal pathogen D. coniospora, but only mildly sensitive to the bacterial pathogen P. aeruginosa. acs-3 mutation suppressed nhr-25 mutant sensitivity to P. aeruginosa, yet surprisingly microarray analysis of nhr-25(RNAi) animals revealed significant overlap with the acs-3 mutant transcriptome, with an enrichment of pathogen response genes. The upregulation of pathogen response genes in acs-3(ft5) mutants and following nhr-25 reduction-of-function (rf) does not appear to be due to a constitutive osmotic response or defective cuticle barrier, two potential explanations for the acs-3(ft5) and nhr-25(rf) expression of innate immunity genes in the absence of pathogen exposure. Together, these data indicate that ACS-3 promotes resistance to the fungal pathogen, D. coniospora and regulates innate immunity genes through an unknown mechanism. Potential roles for ACS-3 in innate immunity are discussed. We used two-color expression microarrays to compare the transcriptional profiles in two experimental conditions: 1) comparing wild-type (N2) L4 stage larval worms to acs-3(ft5) L4 larval mutant animals; and 2) animals grown to L4 larval stage on bacteria harboring vectors for either control or nhr-25 RNA-interference (RNAi). L4 stage was determined by morphology of the developing vulva. Three biological replicates were used for each experimental condition. Statistically significant changes in gene expression in each experimental were determined using M-bM-^@M-^\linear models for microarray dataM-bM-^@M-^] (limma).

Project description:Acyl-coA synthases (ACSs) produce fatty acyl-CoAs that are used in metabolic and signaling pathways. Metazoans have a large number of ACS genes with differing expression patterns and substrate preferences, but the physiological roles of most ACS genes are unknown. Here, we focused on the C. elegans acyl CoA synthase, ACS-3, which is known to regulate fat uptake and de novo fat synthesis through the conserved nuclear hormone receptor, nhr-25. We performed microarray analysis of acs-3 mutants to elucidate the acs-3-regulated transcription program. This analysis revealed an enrichment among differentially regulated genes of those involved in lipid metabolism, pathogen and wounding responses, and sterol binding genes, among others. As the immunity genes were the most represented gene class, we performed pathogen sensitivity assays to test the phenotypic consequences of this immune gene regulation. Interestingly, acs-3 mutants were hypersensitive to the fungal pathogen D. coniospora, but only mildly sensitive to the bacterial pathogen P. aeruginosa. acs-3 mutation suppressed nhr-25 mutant sensitivity to P. aeruginosa, yet surprisingly microarray analysis of nhr-25(RNAi) animals revealed significant overlap with the acs-3 mutant transcriptome, with an enrichment of pathogen response genes. The upregulation of pathogen response genes in acs-3(ft5) mutants and following nhr-25 reduction-of-function (rf) does not appear to be due to a constitutive osmotic response or defective cuticle barrier, two potential explanations for the acs-3(ft5) and nhr-25(rf) expression of innate immunity genes in the absence of pathogen exposure. Together, these data indicate that ACS-3 promotes resistance to the fungal pathogen, D. coniospora and regulates innate immunity genes through an unknown mechanism. Potential roles for ACS-3 in innate immunity are discussed.

Project description:Microarray expression profiling of C. elegans N2 L4 control(RNAi) vs. mdt-15(RNAi)

Project description:Comparison of gene expression profiles from C. elegans wildtype strain (N2) treated with L4440 and T25B9.1 RNAi for 5 days after L4 larvae stage. Jena Centre for Systems Biology of Ageing - JenAge (ww.jenage.de)

Project description:Comparison of gene expression profiles from C. elegans wildtype strain (N2) treated with L4440 and T25B9.1 RNAi for 2 days after L4 larvae stage. Jena Centre for Systems Biology of Ageing - JenAge (www.jenage.de)

Project description:C. elegans NHR-25 ChIP-seq

Project description:C. elegans: wildtype vs nhr-49-/- wildtype vs nhr-66-/- wildtype vs nhr-80-/-

Project description:Investigation of whole genome gene expression level changes in early generation Caenorhabditis elegans Bristol N2 rsd-2 and Bristol N2 rsd-6 single mutants, compared to late-generation strains at 25°C and 20°C

Project description:The gene nhr-6 encodes the sole C. elegans NR4A nuclear receptor homolog which has a critical role in organogenesis by regulating the development of the spermatheca organ. Here we utilized chromatin immunoprecipitation followed by next-generation sequencing (ChIP-seq) to identify NHR-6 binding sites during both the late L3/early L4 and mid L4 developmental stages. Our results revealed 30,745 enriched binding sites for NHR-6 with sites specific to each developmental stage and sites found in both stages. Additionally, ~70% of enriched sites were found within 3 kb upstream of a gene transcription start site. Binding sites for a cohort of candidate target genes with probable functions in spermatheca organogenesis were validated through qPCR. Reproductive and spermatheca phenotypes were also evaluated for these genes following a loss-of-function RNAi screen which revealed several genes with critical functions during spermatheca organogenesis. Our results uncovered a complex nuclear receptor regulatory network whereby NHR-6 regulates multiple cellular processes including proliferation, differentiation, and metabolism.

Project description:Comparison of gene expression profiles from C. elegans mutant strains (MIR73, MIR75 or MIR77) overexpressing genes involved in proline metabolism (B0513.5 or T22H6.2) with wildtype strain (N2) at 5 days after L4 larvae stage. Jena Centre for Systems Biology of Ageing - JenAge (www.jenage.de)