Quantifying the effect of nutrient-gene interaction in utero in key tissues instrumental to productivity and sustainability of the beef industry. The cattle industry occupies 43 per cent of the land mass and provides 13 per cent of rural employment. Nutritional insult in utero affects postnatal reproductive and production traits in cattle and imposes epigenetic modifications. This project investigates the effect upon genes affecting appetite, ovarian development, adipogenesis, myogenesis and pos ....Quantifying the effect of nutrient-gene interaction in utero in key tissues instrumental to productivity and sustainability of the beef industry. The cattle industry occupies 43 per cent of the land mass and provides 13 per cent of rural employment. Nutritional insult in utero affects postnatal reproductive and production traits in cattle and imposes epigenetic modifications. This project investigates the effect upon genes affecting appetite, ovarian development, adipogenesis, myogenesis and post natal growth.Read moreRead less
Maximizing male fertility: the role of CRISP proteins. This project aims to investigate the function of cysteine rich secretory protein (CRISP) family members in fertility. It is expected to generate new knowledge on the role CRISP1 and 4 play in sperm competition in vivo, and thus, evolutionary processes; to define the role seminal plasma CRISPs play in fertility; and identify the mechanism underpinning their biological activities. This will be achieved using a range of innovative, state-of-the ....Maximizing male fertility: the role of CRISP proteins. This project aims to investigate the function of cysteine rich secretory protein (CRISP) family members in fertility. It is expected to generate new knowledge on the role CRISP1 and 4 play in sperm competition in vivo, and thus, evolutionary processes; to define the role seminal plasma CRISPs play in fertility; and identify the mechanism underpinning their biological activities. This will be achieved using a range of innovative, state-of-the-art approaches. Expected outcomes and benefits include an enhanced knowledge of the mechanisms underpinning fertility and infertility, enhanced collaboration and research knowhow, and an evidence base for future applied projects aimed enhancing fertility in agricultural species.Read moreRead less
Targeting TGF-beta proteins to control animal reproduction. This project aims to develop a suite of novel biologics to control fertility in female mammals. This project expects to demonstrate that targeting a single class of ovarian proteins will enhance or inhibit egg production. The expected outcomes of this project are to (1) transform the breeding of livestock animals, which should provide significant benefits to the agricultural industry, through increased herd/flock sizes, and (2) provide ....Targeting TGF-beta proteins to control animal reproduction. This project aims to develop a suite of novel biologics to control fertility in female mammals. This project expects to demonstrate that targeting a single class of ovarian proteins will enhance or inhibit egg production. The expected outcomes of this project are to (1) transform the breeding of livestock animals, which should provide significant benefits to the agricultural industry, through increased herd/flock sizes, and (2) provide a non-surgical method of contraception in companion/feral species, which should address the large unmet need for fertility control in these animals.
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Stimulation of the mammalian reproductive system by olfactory pathways. This project answers fundamental questions about mammalian reproductive biology but, because we work with the sheep model, our findings can be applied to two of Australia's biggest export industries, wool and sheepmeat. Understanding the reproductive responses of our production animals to exteroceptive factors such as socio-sexual signals, photoperiod and nutrition is an important first step towards refining the management ....Stimulation of the mammalian reproductive system by olfactory pathways. This project answers fundamental questions about mammalian reproductive biology but, because we work with the sheep model, our findings can be applied to two of Australia's biggest export industries, wool and sheepmeat. Understanding the reproductive responses of our production animals to exteroceptive factors such as socio-sexual signals, photoperiod and nutrition is an important first step towards refining the management of breeding programs. It has been argued that this approach will also minimise, and perhaps even remove the need for, exogenous hormones and drugs for controlling the reproductive process.Read moreRead less
Development of cloning technology for the Australian Pig Industry. Cloning has the potential to be the most efficient of the reproductive technologies developed for increasing genetic improvement in livestock. Currently up to 5% of cloned embryos develop to term in the pig. This is higher than that reported for cattle and sheep. Moreover the use of this technology in the pig does not appear not to result in the same sorts of problems and losses seen around the time of birth in these species ....Development of cloning technology for the Australian Pig Industry. Cloning has the potential to be the most efficient of the reproductive technologies developed for increasing genetic improvement in livestock. Currently up to 5% of cloned embryos develop to term in the pig. This is higher than that reported for cattle and sheep. Moreover the use of this technology in the pig does not appear not to result in the same sorts of problems and losses seen around the time of birth in these species i.e. the majority of cloned pigs appear normal and are healthy at birth. However before cloning can be used commercially, current efficiencies need to be increased approx two fold for this to be economically viable. The aim of the present study is to improve the efficiency of our current cloning protocol and develop associated technologies such as embryo freezing to facilitate commercialisation. This will ensure that the Australian Pig Industry remains competitive at a pivotal time in its development.Read moreRead less
Embryo genomics for engineering change. The proposed research program will contribute to areas that are critically important for Australia, such as agriculture, animal biodiversity, biomedicine, human health and biosafety. By addressing the high economic losses due to early embryonic mortality in farm animals, results from this research will enhance the competitiveness of Australian agriculture and biomedical research. The establishment of a world class research Centre for Animal Biotechnology a ....Embryo genomics for engineering change. The proposed research program will contribute to areas that are critically important for Australia, such as agriculture, animal biodiversity, biomedicine, human health and biosafety. By addressing the high economic losses due to early embryonic mortality in farm animals, results from this research will enhance the competitiveness of Australian agriculture and biomedical research. The establishment of a world class research Centre for Animal Biotechnology at the University of Adelaide will create a major addition to the national research base. The Centre will develop technology platforms to support various groups across the entire Australian scientific community.Read moreRead less
In vitro prediction tests of fertility of frozen semen of sheep and cattle. Variation in fertility after artificial insemination (AI) of frozen semen is high and leads to economic loss. Routine assessment of the quality of frozen semen relies on crude, simple tests of motility and morphology of sperm. More sophisticated sperm ultrastructural and function tests have recently been developed, but it is not known how these tests relate to fertility in the field. In this project we will test a ran ....In vitro prediction tests of fertility of frozen semen of sheep and cattle. Variation in fertility after artificial insemination (AI) of frozen semen is high and leads to economic loss. Routine assessment of the quality of frozen semen relies on crude, simple tests of motility and morphology of sperm. More sophisticated sperm ultrastructural and function tests have recently been developed, but it is not known how these tests relate to fertility in the field. In this project we will test a range of in vitro methods of assessment of motility and morphology of sperm and compare them with fertility of frozen semen samples after AI, leading to more objective methods of semen analysis.Read moreRead less
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
DNA methylation in IVF and cloned embryos. In vitro fertilisation (IVF) and cloning are new assisted reproductive technologies that in time will revolutionise genetic improvement of Australia's economically important animals. IVF and cloning can be associated with aberrant growth that results from atypical gene expression. DNA methylation is central to gene regulation and determines which genes are expressed. In this project a new technique will be used to quantify DNA methylation in naturall ....DNA methylation in IVF and cloned embryos. In vitro fertilisation (IVF) and cloning are new assisted reproductive technologies that in time will revolutionise genetic improvement of Australia's economically important animals. IVF and cloning can be associated with aberrant growth that results from atypical gene expression. DNA methylation is central to gene regulation and determines which genes are expressed. In this project a new technique will be used to quantify DNA methylation in naturally conceived, IVF and cloned embryos. The information will be used to improve IVF and cloning so that these technologies can be applied with confidence to increase the international competitiveness of Australia's livestock industries.Read moreRead less