Mechanisms of manchette function. This project aims to define the function of the manchette, a poorly understood microtubule-based structure present in haploid male germ cells. This project aims to define key mechanisms underpinning manchette development and movement, and to generate a detailed picture of the dynamics of germ cell development using imaging technologies and unique animal models. Such knowledge should improve the understanding of how male fertility is achieved, the origin of infer ....Mechanisms of manchette function. This project aims to define the function of the manchette, a poorly understood microtubule-based structure present in haploid male germ cells. This project aims to define key mechanisms underpinning manchette development and movement, and to generate a detailed picture of the dynamics of germ cell development using imaging technologies and unique animal models. Such knowledge should improve the understanding of how male fertility is achieved, the origin of infertility and how species-specific differences in sperm form are achieved. Such insights may ultimately lead to improved agricultural efficiencies and job creation.Read moreRead less
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
The Role of C-kit and Selected TGF beta Family Members in Recruitment. The recruitment of primordial follicles into the growth phase is central to female reproductive function, however the control of this process to date, has been poorly understood due to inadequate technologies. Our team has recently developed novel recruitment models and a new and innovative method of isolating primordial follicles which will enable us to identify the role of c-kit and selected TGF beta family members in recru ....The Role of C-kit and Selected TGF beta Family Members in Recruitment. The recruitment of primordial follicles into the growth phase is central to female reproductive function, however the control of this process to date, has been poorly understood due to inadequate technologies. Our team has recently developed novel recruitment models and a new and innovative method of isolating primordial follicles which will enable us to identify the role of c-kit and selected TGF beta family members in recruitment. This work will provide cornerstone scientific knowledge about the control of female reproduction and provide the impetus for the development of more effective contraception and superovulation strategies in mammals.Read moreRead less
A novel microtubule severing protein involved in male germ cell biology. The project aims to better understand the cellular and biochemical mechanisms underlying a key component of male fertility. Microtubules are a fundamental component of all cells. A mechanism that is increasingly recognised as essential for microtubules regulation is severing. It has been discovered that an uncharacterised microtubule severing protein, KATNAL2, has a key role in male germ cell development. This project aims ....A novel microtubule severing protein involved in male germ cell biology. The project aims to better understand the cellular and biochemical mechanisms underlying a key component of male fertility. Microtubules are a fundamental component of all cells. A mechanism that is increasingly recognised as essential for microtubules regulation is severing. It has been discovered that an uncharacterised microtubule severing protein, KATNAL2, has a key role in male germ cell development. This project aims to define the mechanisms underlying KATNAL2 function in the male germ line. It is expected that these data will generate a comprehensive picture of KATNAL2 function and provide foundation data of relevance across multiple species and tissues. In the longer term, it may also reveal a rational strategy for fertility enhancement or suppression.Read moreRead less
Epigenetic and biomarker approaches to improving dairy cow fertility. The dairy industry will not deliver sustainable higher productivity unless the reproductive performance of dairy cows is significantly improved. This expected outcome will be achieved via the identification of epigenetic and protein biomarkers of improved fertility that will be used to develop superior breeding stock. Caruncular and intercaruncular tissues and blood have been obtained from both fertile (New Zealand Holstein-Fr ....Epigenetic and biomarker approaches to improving dairy cow fertility. The dairy industry will not deliver sustainable higher productivity unless the reproductive performance of dairy cows is significantly improved. This expected outcome will be achieved via the identification of epigenetic and protein biomarkers of improved fertility that will be used to develop superior breeding stock. Caruncular and intercaruncular tissues and blood have been obtained from both fertile (New Zealand Holstein-Friesian) and sub-fertile (North American Holstein-Friesian) cows within pasture-based dairying systems that include seasonal calving and subclinical uterine inflammation (associated with poor reproductive performance). Determinations will be conducted using deep parallel (next generation) sequencing and mass spectrometry.Read moreRead less
Brain Regulation of Reproduction: Challenging the ‘KNDy’ Hypothesis. The brain switches reproduction on and off by changing the frequency of pulses of gonadotrophin releasing hormone. The processes that produce the pulses have been a puzzle for decades but, recently, brain cells that produce three peptides (kisspeptin, neurokinin B, dynorphin), known as ‘KNDy cells’, have been heralded as the ‘missing link’, or even the ‘pulse generator’. Using sheep, this project will challenge the KNDy hypothe ....Brain Regulation of Reproduction: Challenging the ‘KNDy’ Hypothesis. The brain switches reproduction on and off by changing the frequency of pulses of gonadotrophin releasing hormone. The processes that produce the pulses have been a puzzle for decades but, recently, brain cells that produce three peptides (kisspeptin, neurokinin B, dynorphin), known as ‘KNDy cells’, have been heralded as the ‘missing link’, or even the ‘pulse generator’. Using sheep, this project will challenge the KNDy hypothesis with pheromones and with acute increases in nutrition, two factors that rapidly increase the frequency of gonadotrophin releasing hormone pulses. The outcomes of this research are directly relevant to the optimisation of reproductive management in farm animals, wildlife and humans.Read moreRead less
Battle of the sexes: can surroundings differentially affect male and female mammalian preimplantation embryos. Equality between the sexes is an issue even at conception. The environment surrounding the embryo can bias the development of one sex over another. This project will assist in the understanding of how male and female embryos differ and will improve assisted reproductive technologies for domestic animal breeding programs, endangered animal conservation and human infertility treatment.
Use of quinone adducted peptides in the regulation of fertility. This project describes a novel strategy for the non-surgical induction of sterility in male and female mammals with applications in the fields of biotechnology, veterinary medicine and the humane control of pest animal species. The approach is dependent upon the known sensitivity of the germ line to oxidative stress. The strategy rests upon the demonstration that quinone-adducted peptides will selectively bind to non-renewable cel ....Use of quinone adducted peptides in the regulation of fertility. This project describes a novel strategy for the non-surgical induction of sterility in male and female mammals with applications in the fields of biotechnology, veterinary medicine and the humane control of pest animal species. The approach is dependent upon the known sensitivity of the germ line to oxidative stress. The strategy rests upon the demonstration that quinone-adducted peptides will selectively bind to non-renewable cell types in the ovary and testis and redox cycle at the cell surface generating a highly localised state of oxidative stress. This stress will then recapitulate the impact of radiation on reproductive tissues by selectively compromising the viability of the germ line, inducing a state of sterility.Read moreRead less
Male to female sperm signalling – a new role for sperm in reproduction? Male seminal fluid is commonly thought simply to provide sperm for conception. This project aims to investigate a lesser known action of sperm: modifying the female immune response to increase the chances of reproductive success. The project aims to define the molecular pathway through which sperm interact with female cells, particularly how B-defensins on sperm bind to Toll-like receptors to stimulate female immune toleranc ....Male to female sperm signalling – a new role for sperm in reproduction? Male seminal fluid is commonly thought simply to provide sperm for conception. This project aims to investigate a lesser known action of sperm: modifying the female immune response to increase the chances of reproductive success. The project aims to define the molecular pathway through which sperm interact with female cells, particularly how B-defensins on sperm bind to Toll-like receptors to stimulate female immune tolerance. The project plans to use embryo transfer and genetic mouse models to determine the physiological benefit of sperm signalling. Evidence that seminal fluid signalling operates in mammals to ensure optimal female reproductive investment would advance knowledge of the male contribution to the reproductive process.Read moreRead less