How do apicomplexan parasites steal amino acids from their hosts? The single-celled parasites that cause malaria and toxoplasmosis are adept at stealing nutrients from the host animals that they infect. How they do this is, however, poorly understood. This project seeks to identify the processes by which these parasites scavenge amino acids, an essential class of nutrient, from their hosts. Using innovative experimental approaches, the project aims to identify and characterise the parasite prote ....How do apicomplexan parasites steal amino acids from their hosts? The single-celled parasites that cause malaria and toxoplasmosis are adept at stealing nutrients from the host animals that they infect. How they do this is, however, poorly understood. This project seeks to identify the processes by which these parasites scavenge amino acids, an essential class of nutrient, from their hosts. Using innovative experimental approaches, the project aims to identify and characterise the parasite proteins that mediate the uptake of different amino acids into the parasite. The intended outcomes of the project are to provide comprehensive insights into a fundamental aspect of parasite biology, and inform strategies to treat the diseases caused by these parasites by cutting off their nutrient supply.Read moreRead less
The physiological importance of GLP-1R and GIPR dimerisation. Cell surface receptors are vital for relaying information from hormones to the cell to influence cell function, and ultimately physiological responses. Receptors can form oligomers with other receptors, but whether this can influence cellular and physiological responses is not yet defined. This biology-based project aims to bridge this knowledge gap by studying the dimerisation between two related receptors involved in whole body meta ....The physiological importance of GLP-1R and GIPR dimerisation. Cell surface receptors are vital for relaying information from hormones to the cell to influence cell function, and ultimately physiological responses. Receptors can form oligomers with other receptors, but whether this can influence cellular and physiological responses is not yet defined. This biology-based project aims to bridge this knowledge gap by studying the dimerisation between two related receptors involved in whole body metabolic homeostasis. Our team will deliver new knowledge into the disciplines of pharmacology, cellular biology, metabolism and physiology, and provide interdisciplinary research training to students and junior scientists, and strengthen research collaboration within and outside of Australia.Read moreRead less