Project description:Insulin/IGF-1 Signaling (IIS) is known to constrain longevity by inhibiting the transcription factor FOXO. How phosphorylation mediated by IIS kinases regulates lifespan beyond FOXO remains unclear. Here, we profile IIS-dependent phosphorylation changes in a large-scale quantitative phosphoproteomic analysis of wild-type and three IIS mutant Caenorhabditis elegans strains. We quantify more than 15,000 phosphosites and find that 476 of these are differentially phosphorylated in the long-lived daf-2/insulin receptor mutant. We develop a machine learning-based method to prioritize 25 potential lifespan-related phosphosites. We perform validations to show that AKT-1 pT492 inhibits DAF-16/FOXO and compensates the loss of daf-2 function, that EIF-2α pS49 potently inhibits protein synthesis and daf-2 longevity, and that reduced phosphorylation of multiple germline proteins apparently transmits reduced DAF-2 signaling to the soma. In addition, an analysis of kinases with enriched substrates detects that casein kinase 2 (CK2) subunits negatively regulate lifespan. Our study reveals detailed functional insights into longevity.
Project description:P granules in C. elegans are required for fertility and function to maintain germ cell identity and pluripotency. Sterility in the absence of P granules is often accompanied by the mis-expression of soma-specific proteins and the initiation of somatic differentiation in germ cells. To investigate whether this is caused by the accumulation of somatic transcripts, we performed mRNA-seq on dissected germlines with and without P granules. Strikingly, we found that somatic transcripts do not increase in the young adult germline when P granules are impaired. Instead, we found that impairing P granules causes sperm-specific mRNAs to become highly overexpressed. This includes the accumulation of major sperm protein (MSP) transcripts in germ cells, a phenotype that is suppressed by feminization of the germline. A core component of P granules, the endo-siRNA-binding Argonaute protein CSR-1, has recently been ascribed with the ability to license transcripts for germline expression. However, impairing CSR-1 has very little effect on the accumulation of its mRNA targets. Instead, we found that CSR-1 functions with P granules to prevent MSP and sperm-specific mRNAs from being transcribed in the hermaphrodite germline. These findings suggest that P granules protect germline integrity through two different mechanisms, by 1) preventing the inappropriate expression of somatic proteins at the level of translational regulation, and by 2) functioning with CSR-1 to limit the domain of sperm-specific expression at the level of transcription. Four biological replicates of each condition (empty vector control, P granule RNAi, and CSR-1 RNAi germlines) were collected for total RNA.
Project description:Mutations affecting spliceosomal proteins are frequently found in hematological malignancies, including myelodysplastic syndromes and acute myeloid leukemia. DDX41/Abstrakt is a metazoan-specific spliceosomal DEAD-box RNA helicase found to be recurrently mutated in inherited myelodysplastic syndromes and in relapsing cases of acute myeloid leukemia. The genetic properties and genomic impacts of disease-causing missense mutations in DDX41 and other spliceosomal proteins have been uncertain. Here we conduct a comprehensive molecular genetic analysis of the C. elegans DDX41 ortholog, SACY-1. Our results reveal general essential functions for SACY-1 in both the germline and the soma, as well as specific functions affecting germline sex determination and cell cycle control. Certain sacy-1/DDX41 mutations, including the R525H human oncogenic variant, confer antimorphic activity, suggesting that they compromise the function of the spliceosome. Consistent with these findings, sacy-1 exhibits synthetic lethal interactions with several spliceosomal components, and biochemical analyses suggest that SACY-1 is a component of the C. elegans spliceosome. We used the auxin-inducible degradation system to analyze the impact of SACY-1 on the transcriptome using RNA sequencing. SACY-1 depletion impacts the transcriptome through splicing-independent and splicing-dependent mechanisms. The observed transcriptome changes suggest that disruption of spliceosomal function induces a stress response. Altered 3’ splice site usage represents the predominant splicing defect observed upon SACY-1 depletion, consistent with a role for SACY-1 as a second-step splicing factor. Missplicing events appear more prevalent in the soma than the germline, suggesting that surveillance mechanisms protect the germline from aberrant splicing.