Project description:Sphingolipids are required for diverse biological functions and are degraded by specific catabolic enzymes. However, the mechanisms that regulate sphingolipid catabolism are not known. Here we characterize a transcriptional axis that regulates sphingolipid breakdown to control resistance against bacterial infection. From an RNAi screen for transcriptional regulators of pathogen resistance in the nematode C. elegans, we identified the nuclear hormone receptor nhr-66, a ligand-gated transcription factor homologous to human hepatocyte nuclear factor 4. Tandem chromatin immunoprecipitation-sequencing (ChIP-seq) and RNA sequencing (RNA-seq) experiments revealed that NHR-66 is a transcriptional repressor, which directly targets sphingolipid catabolism genes. Transcriptional de-repression of two sphingolipid catabolic enzymes in nhr-66 loss-of-function mutants drives the breakdown of sphingolipids, which enhances host susceptibility to infection with the bacterial pathogen Pseudomonas aeruginosa. These data define transcriptional control of sphingolipid catabolism in the regulation of cellular sphingolipids, a process that is necessary for pathogen resistance.

Project description:Transcriptional profiling of C. elegans NHR-49, NHR-66 and NHR-80 Independent data sets were generated for each mutant vs wildtpe comparison: NHR-49 (N=2), NHR-66 (N=3), NHR-80 (N=4)

Project description:Transcriptional profiling of C. elegans NHR-49, NHR-66 and NHR-80

Project description:Ectopic lipid deposition and altered mitochondrial dynamics contribute to the development of obesity and insulin resistance. However, the mechanistic link between both processes remains unclear. Here we demonstrate that abrogation of ceramide synthase (CerS)6, which generates C16:0-sphingolipids, but not of the alternative C16:0-sphingolipid synthetizing CerS5 protects from obesity and insulin resistance, and both enzymes regulate C16:0-sphingolipid synthesis in distinct intracellular compartments. Moreover, we identify proteins, which specifically interact with C16:0-sphingolipids derived from CerS5 or CerS6. Here, only CerS6-derived C16:0-sphingolipids bind the mitochondrial fission factor (Mff). CerS6- and Mff-deficiency protects from fatty acid-induced mitochondrial fragmentation in vitro, and both proteins genetically interact in vivo in obesity-induced mitochondrial fragmentation and development of insulin resistance. Our experiments reveal an unprecedented specificity of sphingolipid-signaling depending on specific synthetizing enzymes, provide a mechanistic link between lipid deposition and mitochondrial dynamics in obesity, and define the CerS6/sphingolid/Mff interaction as a therapeutic target for obesity and diabetes.

Project description:Protection against pathogens is a major function of the gut microbiota. Although bacterial natural products have emerged as crucial components of host-microbiota interactions, their exact role in microbiota-mediated protection is largely unexplored. We addressed this knowledge gap with the nematodeCaenorhabditis elegansand its microbiota isolatePseudomonas fluorescensMYb115 that is known to protect againstBacillus thuringiensis (Bt) infection. We find that MYb115-mediated protection depends on sphingolipids that are derived from an iterative type I polyketide synthase (PKS), thereby describing a noncanonical pathway of bacterial sphingolipid production. We provide evidence that MYb115-derived sphingolipids affectC. eleganstolerance to Bt infection by altering host sphingolipid metabolism. This work establishes sphingolipids as structural outputs of bacterial PKS and highlights the role of microbiota-derived sphingolipids in host protection against pathogens.

Project description:rs07-05_sphingolipids-cold - sphingo-1 - The cold choc response seems to be partly triggered by Sphingolipid species. To date no gene response as been associated to sphingolipid signaling pathway in plant. Our aim is to identify among the cold induced genes the ones regulated by sphingolipids and to try to define a sphingolipid pathway specific group of genes. - 7ml of 5 days-old cells suspensions were incubated in presence of different sphingolipid pathway inhibitors, 30 min to 2 hours depending in the coumpound (all were resuspended in DMSO and control were done with DMSO). Then a 30 min cold choc was applied before cells were harvested and frozen in cold nitrogen. RNA were then extracted. FB1 and DMS were from Alexis , Myr from Cayman, TSP from matreya. 6 dye-swap - treated vs untreated comparison

Project description:Previously, we identified NHR-49, functional homolog of the key vertebrate lipid metabolism regulator HNF4/PPARa, as essential for the longevity of Germiline Strem Cell (GSC)-less animals. Since longevity and stress resistance have been reported to be strongly linked, we examined the role of NHR-49 in resistance against the human opportunistic pathogen Pseudomonas aeruginosa, strain PA14. As a part of this effort we employed RNA-Sequencing to determine the downstream targets of NHR-49 in GSC-less animals.

Project description:The cleavage of sphingoid base phosphates by sphingosine-1-phosphate (S1P) lyase to produce phosphoethanolamine and a fatty aldehyde is the final degradative step in the sphingolipid metabolic pathway. We have studied mice with an inactive S1P lyase gene and have found that, in addition to the expected increase of sphingoid base phosphates, other sphingolipids (including sphingosine, ceramide, and sphingomyelin) were substantially elevated in the serum and /or liver of these mice. This latter increase is consistent with a reutilization of the sphingosine backbone for sphingolipid synthesis due to its inability to exit the sphingolipid metabolic pathway. Furthermore, the S1P lyase deficiency resulted in changes in the levels of serum and liver lipids not directly within the sphingolipid pathway, including phospholipids, triacyglycerol, diacylglycerol, and cholesterol. Even though lipids in serum and lipid storage were elevated in liver, adiposity was reduced in the S1P lyase-deficient mice. Microarray analysis of lipid metabolism genes in liver showed that the S1P lyase deficiency caused widespread changes in their expression pattern. These results demonstrate that S1P lyase is a key regulator of the levels of multiple sphingolipid substrates and reveal functional links between the sphingolipid metabolic pathway and other lipid metabolic pathways that may be mediated by shared lipid substrates and changes in gene expression programs. The disturbance of lipid homeostasis by altered sphingolipid levels may be relevant to metabolic diseases. Experiment Overall Design: RNA samples from liver for three sphingosine-1-phosphate lyase knock-out and three WT mice.

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

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).