The essence of being an animal: sponge allorecognition and the evolution of individuality. The human genome encodes the ability to recognise self from nonself at the cellular level. In medicine, this innate ability results in the rejection of transplanted (grafted) tissues from unrelated individuals. This project seeks to get to the evolutionary foundation of self-nonself recognition by studying this process in a simple and tractable model - a sponge from the Great Barrier Reef. Like humans, spo ....The essence of being an animal: sponge allorecognition and the evolution of individuality. The human genome encodes the ability to recognise self from nonself at the cellular level. In medicine, this innate ability results in the rejection of transplanted (grafted) tissues from unrelated individuals. This project seeks to get to the evolutionary foundation of self-nonself recognition by studying this process in a simple and tractable model - a sponge from the Great Barrier Reef. Like humans, sponges reject cells and tissues derived from another individual. By defining the genetic basis of self-recognition in sponges we reveal the antiquity of this system and the core features of histocompatibility and immunity. Such insights can inform a range of regenerative medical pursuits.Read moreRead less
Do crayfish use the information carried by low-level electrical signals in the environment? Many vertebrates detect electric fields. Fish communicate electrically. No invertebrate has been shown to do so. We have evidence that crayfish change their behaviour following exposure to low-level, waterborne electrical signals. Crayfish behaviour is currently the preferred model for studying the neurobiology of social hierarchies in animals. Evidence that information is passing from either predators or ....Do crayfish use the information carried by low-level electrical signals in the environment? Many vertebrates detect electric fields. Fish communicate electrically. No invertebrate has been shown to do so. We have evidence that crayfish change their behaviour following exposure to low-level, waterborne electrical signals. Crayfish behaviour is currently the preferred model for studying the neurobiology of social hierarchies in animals. Evidence that information is passing from either predators or conspecifics through an undescribed electrosensory channel would fundamentally change the direction of that research. Behaviour modification using electrical signals could also prove to be a valuable tool in crustacean aquaculture. This is a proposal to discover the nature and behavioural implications of crayfish electroreception.Read moreRead less