Dissecting the impact of stress on reproduction: Novel peptide mediates inhibitory effects of stress on female reproduction. This research proposal offers a pioneering opportunity to develop treatments that overcome the negative impact of stress on reproduction. Specifically, knowledge generated in this project will be vital in the development of strategic defences against the impact of stress on reproduction. This project fundamentally addresses Research Priority 2: Promoting and maintaining go ....Dissecting the impact of stress on reproduction: Novel peptide mediates inhibitory effects of stress on female reproduction. This research proposal offers a pioneering opportunity to develop treatments that overcome the negative impact of stress on reproduction. Specifically, knowledge generated in this project will be vital in the development of strategic defences against the impact of stress on reproduction. This project fundamentally addresses Research Priority 2: Promoting and maintaining good health. Given that suppression of reproduction by stress occurs in all mammalian species including humans, domestic animals and wildlife, being able to prevent or overcome stress-induced reproductive dysfunction will generate significant health, social, economic and ecological benefits. Read moreRead less
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
Molecular mechanisms for seminal fluid signalling in reproduction. Male seminal fluid regulation of the female reproductive process influences fertility and fecundity in humans and animal species. Infertility and impaired reproductive function is a major economic constraint in livestock industries, and carries a substantial social and public health cost in humans. This research will identify the active signalling molecules in seminal fluid and quantify their importance in reproductive success ....Molecular mechanisms for seminal fluid signalling in reproduction. Male seminal fluid regulation of the female reproductive process influences fertility and fecundity in humans and animal species. Infertility and impaired reproductive function is a major economic constraint in livestock industries, and carries a substantial social and public health cost in humans. This research will identify the active signalling molecules in seminal fluid and quantify their importance in reproductive success and health of offspring. The outcomes will inform development of new diagnostic assays for male fertility, and underpin strategic design of novel fertility treatments and products with applications in the human health and animal breeding industries. Read moreRead less
Male germ line transgenesis and siRNA technology for manipulating genes in domestic species. Professor Shemesh has successfully developed male germ line transgenesis in species such as bovine and chicken. This technology allows genes to be manipulated via sperm in a wide range of animals besides mice, avoiding the need for a female in vitro fertilization regimen. He is curently applying interference RNA (siRNA) transgenically to manipulate genes in vivo. Together these two technologies offer imm ....Male germ line transgenesis and siRNA technology for manipulating genes in domestic species. Professor Shemesh has successfully developed male germ line transgenesis in species such as bovine and chicken. This technology allows genes to be manipulated via sperm in a wide range of animals besides mice, avoiding the need for a female in vitro fertilization regimen. He is curently applying interference RNA (siRNA) transgenically to manipulate genes in vivo. Together these two technologies offer immense possibilities to manipulate a wide range of species for economic, biotechnological or medical research purposes. Professor Shemesh wishes to come to Adelaide to establish these technologies there as parts of ongoing research projects, related to the physiology of the ovarian hormone relaxin in aging research.Read moreRead less