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
The impact of environmental toxicants on the fertility of female animals. This study aims to address a problem of national significance; determining the impact of commonly used environmental toxicants (pesticides) on the fertility and health of female animals, both agricultural and native. This project expects to generate new knowledge in the fields of ovarian biology, female fertility and toxicology by using a combination of mouse and marsupial animal models. The expected outcomes include the e ....The impact of environmental toxicants on the fertility of female animals. This study aims to address a problem of national significance; determining the impact of commonly used environmental toxicants (pesticides) on the fertility and health of female animals, both agricultural and native. This project expects to generate new knowledge in the fields of ovarian biology, female fertility and toxicology by using a combination of mouse and marsupial animal models. The expected outcomes include the establishment of interdisciplinary collaborations and provision of world-class training for staff and students in the field of reproductive biology. This project should provide significant benefits, such as improved chemical management in livestock production and the development of marsupial conservation action plans.Read moreRead less
Sperm ciliary gating and midpiece formation – a novel player and process. We have identified CCDC112 an essential player in mammalian sperm tail development and male fertility. This project aims to define the role of CCDC112 in 1) the formation of the core to the sperm tail, the axoneme, and 2) the packaging of mitochondria into the midpiece. Within this Discovery Project we will define the mechanism(s) of CCDC112 functions and the consequences of its dysfunction. Insights from this grant will b ....Sperm ciliary gating and midpiece formation – a novel player and process. We have identified CCDC112 an essential player in mammalian sperm tail development and male fertility. This project aims to define the role of CCDC112 in 1) the formation of the core to the sperm tail, the axoneme, and 2) the packaging of mitochondria into the midpiece. Within this Discovery Project we will define the mechanism(s) of CCDC112 functions and the consequences of its dysfunction. Insights from this grant will be of significance to fertility across mammals and may ultimately benefit the selection of highly fertile males within the agricultural sector.Read moreRead less
Beyond pineal melatonin: sensing the seasons without the eye. The project will identify the causal connection between seasonal breeding in animals and a recently recognised brain biochemical pathway by applying experimental treatments mimicking seasonal environmental changes in a mutant and wild-type nematode worm model. Through experimentation we will identify useful biological targets that might be manipulated to enhance control of seasonal breeding in managed animals. With better control of r ....Beyond pineal melatonin: sensing the seasons without the eye. The project will identify the causal connection between seasonal breeding in animals and a recently recognised brain biochemical pathway by applying experimental treatments mimicking seasonal environmental changes in a mutant and wild-type nematode worm model. Through experimentation we will identify useful biological targets that might be manipulated to enhance control of seasonal breeding in managed animals. With better control of reproductive output in animals, farmers and managers can increase and/or decrease reproductive output as needed in managed species including livestock and vertebrate pests. This will enhance the use of precious land resources and minimize ecological damage from overbreeding.Read moreRead less
Glucocorticoid receptor-αD1 modulates stress and inflammation . Environmental stressors in mammalian pregnancy often cause inflammation in the mother which has an adverse effect on the fetus and its survival. The current grant aims to examine the mechanism by which stress and inflammation coexist in pregnancy because stress hormones normally exert anti-inflammatory actions. Contrary to convention, a new glucocorticoid receptor (GR), GRalpha D1, is linked to increasing inflammation. Using innova ....Glucocorticoid receptor-αD1 modulates stress and inflammation . Environmental stressors in mammalian pregnancy often cause inflammation in the mother which has an adverse effect on the fetus and its survival. The current grant aims to examine the mechanism by which stress and inflammation coexist in pregnancy because stress hormones normally exert anti-inflammatory actions. Contrary to convention, a new glucocorticoid receptor (GR), GRalpha D1, is linked to increasing inflammation. Using innovative molecular biology approaches, GRalphaD1's function will be examined to provide a deeper understanding of how stress regulates inflammation in animal reproduction. The project aims to enhance interdisciplinary collaborations with expected benefits including a paradigm shift in our knowledge in this field.Read moreRead less
Inflammation as an early form of maternal-fetal signalling in pregnancy. The project aims to understand the role of inflammatory signalling in marsupial pregnancy. This project is expected to explain why inflammation, a processes normally confined to injury and infection, is a part of reproduction in live-bearing mammals. Outcomes of this project include robust measures of the capacity for, impact of, and evolution of, inflammatory signalling in marsupial pregnancy. The project will provide new ....Inflammation as an early form of maternal-fetal signalling in pregnancy. The project aims to understand the role of inflammatory signalling in marsupial pregnancy. This project is expected to explain why inflammation, a processes normally confined to injury and infection, is a part of reproduction in live-bearing mammals. Outcomes of this project include robust measures of the capacity for, impact of, and evolution of, inflammatory signalling in marsupial pregnancy. The project will provide new knowledge about the unique biology of Australia's marsupial fauna.This project will provide significant benefits, including enhanced capacity for reproduction research in Australia, new international collaborations between Melbourne and Yale, and a new explanation for the puzzling role of inflammation in pregnancy.Read moreRead less
Is SPINT1 a key regulator of placental development? . The placenta is an essential organ required for reproduction in placental species. This project aims to elucidate the fundamental biology of SPINT1 in placental development. It will generate new knowledge about whether the spatial and temporal expression of SPINT1 is conserved across several species; cow, sheep, lizard, mouse and human. It will also define the molecular mechanisms by which SPINT1 directs formation, maturation and expansion o ....Is SPINT1 a key regulator of placental development? . The placenta is an essential organ required for reproduction in placental species. This project aims to elucidate the fundamental biology of SPINT1 in placental development. It will generate new knowledge about whether the spatial and temporal expression of SPINT1 is conserved across several species; cow, sheep, lizard, mouse and human. It will also define the molecular mechanisms by which SPINT1 directs formation, maturation and expansion of the placental exchange interface which is critical for offspring survival.
The project will increase understanding of placental development, enhance collaboration and research knowhow, and promote future applied projects in all species that reproduce via placental support.Read moreRead less
Identification of causal variants for complex traits. The aim of this project is to identify causal variants for complex traits in cattle and humans. Although most important traits in agriculture, medicine and evolution are complex traits, very few of the genetic variants affecting these traits are known and this undermines our understanding of how genetic variants affect a trait and practical uses of this knowledge. Huge datasets of individuals with genome sequence and phenotypes and new statis ....Identification of causal variants for complex traits. The aim of this project is to identify causal variants for complex traits in cattle and humans. Although most important traits in agriculture, medicine and evolution are complex traits, very few of the genetic variants affecting these traits are known and this undermines our understanding of how genetic variants affect a trait and practical uses of this knowledge. Huge datasets of individuals with genome sequence and phenotypes and new statistical methods provide the opportunity to close this gap. The outcome will be identification of many genomic variants causing variation in complex traits. This will benefit scientific understanding of complex traits and the ability to predict traits for individuals from their genome sequence.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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Understanding sperm motion at surfaces. This project aims to reveal the biophysics of sperm motion at surfaces, using 3D imaging, advanced mathematical modelling, and microfluidics. This interdisciplinary project expects to generate new knowledge of sperm flagellar activity, using an innovative microfluidic approach to measure full dynamics of sperm motion in 3D and compare experimental observations with computational results. The project is expected to reveal the intraflagellar mechanisms that ....Understanding sperm motion at surfaces. This project aims to reveal the biophysics of sperm motion at surfaces, using 3D imaging, advanced mathematical modelling, and microfluidics. This interdisciplinary project expects to generate new knowledge of sperm flagellar activity, using an innovative microfluidic approach to measure full dynamics of sperm motion in 3D and compare experimental observations with computational results. The project is expected to reveal the intraflagellar mechanisms that trigger the switch between 3D and 2D flagellar waveforms near surfaces. This should provide significant benefits, such as important insights into the biophysics of mammalian reproduction and the origin of flagellar motility in eukaryotes.Read moreRead less