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Ceramide Biosynthesis and NEET Proteins Impact Development, Function, and Maintenance of the Caenorhabditis elegans GermlineKing, Skylar Dawn 08 1900 (has links)
I used the C. elegans genetic model to examine the role of ceramide biosynthesis (sphingolipid pathway) and iron regulation and found that each process impacts germline development and function. Using a sphingolipid specific antibody mAb15B4, I found that sphingolipids are associated with germ granules (P granules) within C. elegans and zebrafish; thus, suggesting conservation of macromolecules associated with germ granules. Phenotype analysis of ceramide biosynthesis mutants in C. elegans revealed that this pathway is essential for normal germline function in the aging adult hermaphrodite; specifically, precocious germline senescence was observed. Furthermore, I found that disruption of ceramide biosynthesis, via the hyl-2 deletion mutation, negatively impacts mAb15B4 localization at the P granules. Through genetic suppression analysis, I determined that insulin signaling and lipid biosynthesis can modulate the mAb15B4 localization to P granules. Additional, phenotype analysis showed that ceramide biosynthesis dysfunction decreased fecundity, and led to germline structure defects and uterine tumors. Through suppression analysis, I determined that modulation of the insulin signaling pathway suppressed the precocious germline senescence due to ceramide biosynthesis dysfunction. Since the presence of uterine tumors is associated with reproductive senescence I concluded that ceramide biosynthesis has a role in germline maintenance in the aging of the germline (germline senescence).
The other important fate of a germ cell is programmed cell death. Apoptosis, which occurs through a highly conserved molecular pathway, is a normal component of growth and homeostatic processes. I used C. elegans to gain a greater understanding of the cisd gene function. The C. elegans genome has three previously uncharacterized cisd genes which code for CISD-1 (homology to vertebrate mitoNEET/CISD1 and NAF-1/CISD2) and CISD-3.1 and CISD-3.2 (homology to vertebrate Miner2/CISD3). I determined that independent disruption of the cisd genes resulted in a significant increase in the number of cell corpses within the adult hermaphrodite germline. Genetic analysis was used to examine the dysfunction of cisd-1 relative to the cell death canonical pathway genes. The increased gamete cell death in the cisd-1 hermaphrodite is suppressed by the ced-9 (Bcl-2 homolog) gain-of-function and requires functional CED-3 (caspase) and CED-4 (APAF). Additionally, the increased germ cell programmed cell death is facilitated by the pro-apoptotic, CED-9-binding protein, CED-13. Further analysis of the cisd gene family members show that cisd-3.2 dysfunction leads to germline defects and reproductive dysfunction, suggesting defects in germline stem cell proliferation. Expression analysis using the cisd promoters to drive fluorescent protein reporters showed that the cisd gene family is expressed in various tissues including the germline; fusion protein analysis showed that CISD-3 is mitochondrial localized. I propose that cisd-3.2 germline defects are a result of abnormal mitochondrial function.
Combined, this work is significant because it identifies sphingolipids as a new component of embryonic P granules, a role for ceramide biosynthesis in reproductive senescence, and places the cisd gene family members as regulators of physiological germline programmed cell death acting through CED-13 and the core apoptotic machinery. Furthermore, it is the first study to show that a CISD3 protein family member is required for normal germline function. These findings support the idea that ceramide biosynthesis and iron regulation are core components in germline development and function.
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