Generation of a C. elegans tdp-1 null allele and humanized TARDBP containing human disease-variants.

Clinical variants of TARDBP are associated with frontotemporal dementia (FTD), amyotrophic lateral sclerosis (ALS) and other degenerative diseases. The predicted C. elegans ortholog of TARDBP is encoded by tdp-1 , but functional orthology has not been demonstrated in vivo. We undertook CRISPR/Cas9-based genome editing of the tdp-1 locus to create a complete loss of function allele; all tdp-1 exons and introns were deleted, creating tdp-1(tgx58) , which resulted in neurodegeneration after oxidative stress. Next, we undertook CRISPR-based genome editing to replace tdp-1 exons with human TARDBP coding sequences, creating humanized ( hTARDBP ) C. elegans expressing TDP-43 . Based on the efficiency of this genome editing, we suggest that iterative genome editing of the tdp-1 target locus using linked coCRISPR markers, like dpy-10 , would be a more efficient strategy for sequential assembly of the large engineered transgenes. hTARDBP decreased the neurodegeneration defect of tdp-1(tgx58) , demonstrating functional cross-species orthology. To develop C. elegans models of FTD and ALS, we inserted five different patient TARDBP variants in the C. elegans hTARDBP locus. Only one clinical variant increased stress-induced neurodegeneration; other variants caused inconsistent or negligible defects under these conditions. Combined, this work yielded an unambiguous null allele for tdp-1 , a validated, humanized hTARDBP, and multiple ALS/FTD patient-associated variant models that can be used for future studies.

Neuronal control of maternal provisioning in response to social cues.

Mothers contribute cytoplasmic components to their progeny in a process called maternal provisioning. Provisioning is influenced by the parental environment, but the molecular pathways that transmit environmental cues between generations are not well understood. Here, we show that, in Caenorhabditis elegans, social cues modulate maternal provisioning to regulate gene silencing in offspring. Intergenerational signal transmission depends on a pheromone-sensing neuron and neuronal FMRFamide (Phe-Met-Arg-Phe)-like peptides. Parental FMRFamide-like peptide signaling dampens oxidative stress resistance and promotes the deposition of mRNAs for translational components in progeny, which, in turn, reduces gene silencing. This study identifies a previously unknown pathway for intergenerational communication that links neuronal responses to maternal provisioning. We suggest that loss of social cues in the parental environment represents an adverse environment that stimulates stress responses across generations.

A Caenorhabditis elegans model for ether lipid biosynthesis and function.

Ether lipids are widespread in nature, and they are structurally and functionally important components of membranes. The roundworm, Caenorhabditis elegans, synthesizes numerous lipid species containing alkyl and alkenyl ether bonds. We isolated C. elegans strains carrying loss-of-function mutations in three genes encoding the proteins required for the initial three steps in the ether lipid biosynthetic pathway, FARD-1/FAR1, ACL-7/GNPAT, and ADS-1/AGPS. Analysis of the mutant strains show that they lack ether lipids, but possess the ability to alter their lipid composition in response to lack of ether lipids. We found that increases in de novo fatty acid synthesis and reduction of stearoyl- and palmitoyl-CoA desaturase activity, processes that are at least partially regulated transcriptionally, mediate the altered lipid composition in ether lipid-deficient mutants. Phenotypic analysis demonstrated the importance of ether lipids for optimal fertility, lifespan, survival at cold temperatures, and resistance to oxidative stress.Caenorhabditis.

Fatty acid desaturation and the regulation of adiposity in Caenorhabditis elegans.

Monounsaturated fatty acids are essential components of membrane and storage lipids. Their synthesis depends on the conversion of saturated fatty acids to unsaturated fatty acids by Delta9 desaturases. Caenorhabditis elegans has three Delta9 desaturases encoded by the genes fat-5, fat-6, and fat-7. We generated nematodes that display a range of altered fatty acid compositions by constructing double-mutant strains that combine mutations in fat-5, fat-6, and fat-7. All three double-mutant combinations have reduced survival at low temperatures. The fat-5;fat-6 double mutants display relatively subtle fatty acid composition alterations under standard conditions, but extreme fatty acid composition changes and reduced survival in the absence of food. The strain with the most severe defect in the production of unsaturated fatty acids, fat-6;fat-7, exhibits slow growth and reduced fertility. Strikingly, the fat-6;fat-7 double-mutant animals have decreased fat stores and increased expression of genes involved in fatty acid oxidation. We conclude that the Delta9 desaturases, in addition to synthesizing unsaturated fatty acids for properly functioning membranes, play key roles in lipid partitioning and in the regulation of fat storage.

Genetic regulation of unsaturated fatty acid composition in C. elegans.

Delta-9 desaturases, also known as stearoyl-CoA desaturases, are lipogenic enzymes responsible for the generation of vital components of membranes and energy storage molecules. We have identified a novel nuclear hormone receptor, NHR-80, that regulates delta-9 desaturase gene expression in Caenorhabditis elegans. Here we describe fatty acid compositions, lifespans, and gene expression studies of strains carrying mutations in nhr-80 and in the three genes encoding delta-9 desaturases, fat-5, fat-6, and fat-7. The delta-9 desaturase single mutants display only subtle changes in fatty acid composition and no other visible phenotypes, yet the fat-5;fat-6;fat-7 triple mutant is lethal, revealing that endogenous production of monounsaturated fatty acids is essential for survival. In the absence of FAT-6 or FAT-7, the expression of the remaining desaturases increases, and this ability to compensate depends on NHR-80. We conclude that, like mammals, C. elegans requires adequate synthesis of unsaturated fatty acids and maintains complex regulation of the delta-9 desaturases to achieve optimal fatty acid composition.