Early life nutrition to improve feed efficiency in commercial dairy goats. This project aims to improve the productivity and welfare and reduce resource waste in commercial dairy goat kids. The Australian dairy goat industry is expanding (~20% per annum) yet there is little research to overcome hurdles to improving milk and meat production. There is also increased societal pressure to improve sustainability, reduce waste and maintain animal welfare. By investigating nutritional methods to improv ....Early life nutrition to improve feed efficiency in commercial dairy goats. This project aims to improve the productivity and welfare and reduce resource waste in commercial dairy goat kids. The Australian dairy goat industry is expanding (~20% per annum) yet there is little research to overcome hurdles to improving milk and meat production. There is also increased societal pressure to improve sustainability, reduce waste and maintain animal welfare. By investigating nutritional methods to improve productivity of male (for meat) and female (for milk) kids, this project will generate new knowledge relevant to Australian and international goat production systems. This project will assist goat producers to make decisions that maximise animal productivity with flow on benefits to manufacturers of goat products. Read moreRead less
Unravelling a novel stress-signalling system in bacteria. This project aims to investigate the cyclic-di-AMP signalling system in industrially important bacteria. The recently discovered cyclic-di-AMP is essential for normal bacterial growth and plays key roles in heat and antibiotic resistance, metabolism and virulence. This project will develop new biological assays to shed light on how bacteria sense and respond to environmental stress. Expected outcomes include a much deeper understanding of ....Unravelling a novel stress-signalling system in bacteria. This project aims to investigate the cyclic-di-AMP signalling system in industrially important bacteria. The recently discovered cyclic-di-AMP is essential for normal bacterial growth and plays key roles in heat and antibiotic resistance, metabolism and virulence. This project will develop new biological assays to shed light on how bacteria sense and respond to environmental stress. Expected outcomes include a much deeper understanding of signalling inputs and outputs. This should lead to benefits such as guiding the improvement of bacterial strains used in food and biochemical biotechnological applications, and may provide the foundation for the development of novel antibiotics.Read moreRead less