Discovery Early Career Researcher Award - Grant ID: DE210100375
Funder
Australian Research Council
Funding Amount
$428,191.00
Summary
Defining single-strand DNA break repair capacity in oocytes. This project aims to investigate fundamental biological mechanisms required for the production of high-quality oocytes, which fortify female fertility and the propagation of all sexually reproducing species. Exploiting unique mouse models, this study will define the importance of single strand DNA break repair capacity in oocytes for the first time, by outlining the role of single strand DNA repair proteins in maintaining genetic integ ....Defining single-strand DNA break repair capacity in oocytes. This project aims to investigate fundamental biological mechanisms required for the production of high-quality oocytes, which fortify female fertility and the propagation of all sexually reproducing species. Exploiting unique mouse models, this study will define the importance of single strand DNA break repair capacity in oocytes for the first time, by outlining the role of single strand DNA repair proteins in maintaining genetic integrity of gametes throughout their lifespan. In doing so, the intended outcome of this project is to dramatically improve our understanding of quality control in the female germ line. This should provide significant benefits to Australia by positioning it as a world leader in the field of Reproductive Science.Read moreRead less
DNA repair: a critical quality control mechanism in the female germ line. This project aims to investigate the fundamental biological mechanisms required for the production of high quality gametes, which underpin female fertility and the propagation of all sexually reproducing species. By taking advantage of unique mouse and avian models, this project expects to define the role of the DNA repair protein TOP3A in the successful completion of meiosis and it's requirement for the survival and genet ....DNA repair: a critical quality control mechanism in the female germ line. This project aims to investigate the fundamental biological mechanisms required for the production of high quality gametes, which underpin female fertility and the propagation of all sexually reproducing species. By taking advantage of unique mouse and avian models, this project expects to define the role of the DNA repair protein TOP3A in the successful completion of meiosis and it's requirement for the survival and genetic integrity of gametes throughout their lifespan. In doing so, the intended outcome of this project is to dramatically improve our understanding of quality control in the female germ line. This should provide significant benefits to Australia by positioning it as a world leader in the field of Reproductive Science.Read moreRead less
Skin in the game: biomimetics, fitness and the springtail cuticle. This project aims to examine the relationship between cuticle (skin) properties, water balance, and fitness in springtails, key players in soil systems. Springtail cuticles are diverse, responsive, and extremely resistant to wetting by water, alcohol and other substances. Their Australian diversity has not been well explored for biomimetic new materials. This project expects to explore options for new applications in materials sc ....Skin in the game: biomimetics, fitness and the springtail cuticle. This project aims to examine the relationship between cuticle (skin) properties, water balance, and fitness in springtails, key players in soil systems. Springtail cuticles are diverse, responsive, and extremely resistant to wetting by water, alcohol and other substances. Their Australian diversity has not been well explored for biomimetic new materials. This project expects to explore options for new applications in materials science and engineering by generalising the cuticle structure-function relationship. Expected outcomes are new information to harness for industry the diversity of nature’s self-cleaning, water repellent surfaces. Significant benefits lie in potential new biomimetic manufacturing options.Read moreRead less
Unravelling the maternal gut microbiome as a driver of fetal development . This project aims to experimentally determine how changes in the maternal gut microbiota impact the phenotype of the offspring. This innovative project uses an interdisciplinary approach combined with novel models and the latest generation technology for genome sequencing. Expected outcomes include extensive new knowledge of how the gut microbiota communicates with the host during pregnancy and the impact this has on the ....Unravelling the maternal gut microbiome as a driver of fetal development . This project aims to experimentally determine how changes in the maternal gut microbiota impact the phenotype of the offspring. This innovative project uses an interdisciplinary approach combined with novel models and the latest generation technology for genome sequencing. Expected outcomes include extensive new knowledge of how the gut microbiota communicates with the host during pregnancy and the impact this has on the gastrointestinal, immune, cardiovascular and reproductive systems. Our findings should yield information that may ultimately be translated into products that augment agricultural production, providing significant benefits.Read moreRead less
Purinergic signalling in placentation and vascular adaptation in pregnancy. Our traditional understanding of purinergic signalling in the placenta is significantly outdated and incomplete. The placenta is critical for reproduction in all eutherian mammals, delivering critical nutrition and oxygen to the developing fetus. This project aims to define the role of purinergic signalling as a critical mechanism driving placentation and angiogenesis. This is the first study of its kind and will use sop ....Purinergic signalling in placentation and vascular adaptation in pregnancy. Our traditional understanding of purinergic signalling in the placenta is significantly outdated and incomplete. The placenta is critical for reproduction in all eutherian mammals, delivering critical nutrition and oxygen to the developing fetus. This project aims to define the role of purinergic signalling as a critical mechanism driving placentation and angiogenesis. This is the first study of its kind and will use sophisticated models to improve our fundamental understanding and ability to manipulate mammalian reproduction via the purinoreceptors. This proposal builds on my skills and expertise; improving our knowledge of the processes driving placental and vascular morphogenesis and offers important discoveries for reproductive science.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100103
Funder
Australian Research Council
Funding Amount
$459,674.00
Summary
Fortifying animal and plant germ cells against proteotoxic stress. Cellular stress is responsible for widespread inefficiencies in plant and animal reproduction. Using high resolution proteomics and cryo-electron microscopy, this project aims to investigate how plant and animal germ cells respond to environmental stresses that are known to disrupt fertility, and assess two novel strategies to decrease the sensitivity of cells to stress. This project is expected to generate new global knowledge i ....Fortifying animal and plant germ cells against proteotoxic stress. Cellular stress is responsible for widespread inefficiencies in plant and animal reproduction. Using high resolution proteomics and cryo-electron microscopy, this project aims to investigate how plant and animal germ cells respond to environmental stresses that are known to disrupt fertility, and assess two novel strategies to decrease the sensitivity of cells to stress. This project is expected to generate new global knowledge in the area of fertility regulation with the potential to improve the tolerance of crop species to heat stress, prevent economic losses and help to secure future food production. Further, this project has the intended benefit of improving the fertility of animal species that suffer from stress-induced infertility.
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