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
Size matters, but at what cost? Role of male sex hormones in the placenta. This project aims to understand molecular pathways regulated by male sex hormones in the placenta that may contribute to sex-specific fetal growth and survival outcomes in response to reduced oxygen and/or glucose. Through this project, we expect to generate new knowledge of the mechanisms that drive sex-specific placental molecular function using interdisciplinary approaches. The application of this advanced understandin ....Size matters, but at what cost? Role of male sex hormones in the placenta. This project aims to understand molecular pathways regulated by male sex hormones in the placenta that may contribute to sex-specific fetal growth and survival outcomes in response to reduced oxygen and/or glucose. Through this project, we expect to generate new knowledge of the mechanisms that drive sex-specific placental molecular function using interdisciplinary approaches. The application of this advanced understanding of the sex-specific regulation of placental molecular function and fetal growth may be targeted in future studies to improve fetal growth outcomes in placental mammals such as livestock, domestic pets, and humans.Read moreRead less