Exploring the immunomodulatory potential of Natural Killer T cells. Natural Killer T cells (NKT cells) are an innate-like population of T cells that recognise a range of lipid based antigens when bound to the antigen-presenting molecule, CD1d. Once activated, NKT cells rapidly secrete a variety of cytokines. This project, in partnership with Vaxine Pty Ltd, aims to gain a basic understanding of NKT recognition of lipids and NKT cell activation by lipids. The project aims to use a combination of ....Exploring the immunomodulatory potential of Natural Killer T cells. Natural Killer T cells (NKT cells) are an innate-like population of T cells that recognise a range of lipid based antigens when bound to the antigen-presenting molecule, CD1d. Once activated, NKT cells rapidly secrete a variety of cytokines. This project, in partnership with Vaxine Pty Ltd, aims to gain a basic understanding of NKT recognition of lipids and NKT cell activation by lipids. The project aims to use a combination of cellular immunology and structural biology to gain insight into NKT cell agonism.Read moreRead less
Enhanced multivalent vaccine responses using a novel vaccine vector system. Enhanced multivalent vaccine responses using a novel vaccine vector system. This project aims to develop a multicomponent vaccine system to deliver equal effectiveness against several disease targets in a single administration. New and innovative vaccine design strategies incorporating economical commercial production processes are urgently needed for new and existing human and animal health applications. A vaccine capab ....Enhanced multivalent vaccine responses using a novel vaccine vector system. Enhanced multivalent vaccine responses using a novel vaccine vector system. This project aims to develop a multicomponent vaccine system to deliver equal effectiveness against several disease targets in a single administration. New and innovative vaccine design strategies incorporating economical commercial production processes are urgently needed for new and existing human and animal health applications. A vaccine capable of targeting multiple diseases by a single injection is an obvious way to expedite future vaccine development and deployment. However, the recipient’s immune system can repress equivalent responses to these multicomponent vaccines. This project’s research is expected to address these problems, and underpin the future commercial development of this vaccine platform.Read moreRead less
The development of a potent new passive immunotherapeutic for the treatment and prevention of bacterial sepsis and septic shock. Bacterial sepsis and septic shock is a leading cause of death in hospital intensive care units and represents a significant public health burden. By developing a new passive immunotherapeutic regimen to treat and prevent bacterial sepsis and septic shock, the project aims to reverse the significant mortality and morbidity associated with this condition.
Understanding The Role Of The Atypical Cadherin Fat4 In Lymphatic Vascular Development
Funder
National Health and Medical Research Council
Funding Amount
$1,006,248.00
Summary
This application will define the role of a large cell adhesion molecule, FAT4, in lymphatic vascular development. By understanding how FAT4 functions in lymphatic vessels, we will gain insight to the mechanisms by which mutations in the gene that encodes this protein cause a human lymphoedema syndrome.
Male-female Sperm Signalling - A Novel Pathway For Peri-conceptual Health?
Funder
National Health and Medical Research Council
Funding Amount
$674,920.00
Summary
This project will investigate a new biological process in reproduction, whereby sperm delivered to the cervix at coitus transmit signalling molecules called microRNAs that influence the female immune response, to increase the chances of conception and pregnancy. We will define the molecular details of this signalling pathway in mouse models, and then determine whether human sperm have a comparable function in ‘priming’ the female body to conceive.
Use of mitochondrial electron transport chain mutants to evaluate how non-phosphorylating respiration influences plant metabolite profiles and stress tolerance. This project uses transgenic plant technology to elucidate how mitochondrial function impacts on the profile of metabolites in plant cell and tissues and whether altering these profiles influences a plant's ability tog row in harsh conditions. It will contribute to our fundamental knowledge of plant metabolism using a metabolomic anaylsi ....Use of mitochondrial electron transport chain mutants to evaluate how non-phosphorylating respiration influences plant metabolite profiles and stress tolerance. This project uses transgenic plant technology to elucidate how mitochondrial function impacts on the profile of metabolites in plant cell and tissues and whether altering these profiles influences a plant's ability tog row in harsh conditions. It will contribute to our fundamental knowledge of plant metabolism using a metabolomic anaylsis of plant stress response. This will be achieved using new high-throughput technologies, allowing reliable qualitative and quantitative analysis of large numbers of samples. This approach will compliment existing genomic and proteomic analyses of plants exposed to abiotic stress.Read moreRead less
Target Of Rapamycin control of nutrient uptake. This project aims to study nutrient uptake in eukaryotes. It is expected to generate new knowledge of critical and conserved features of environmental and Target Of Rapamycin (TOR)-mediated control of nutrient uptake, specifically endocytosis, building on novel preliminary data that identifies novel TOR control points. The expected outcomes include new insights into mechanisms controlling nutrient uptake and fostering institutional collaboration. T ....Target Of Rapamycin control of nutrient uptake. This project aims to study nutrient uptake in eukaryotes. It is expected to generate new knowledge of critical and conserved features of environmental and Target Of Rapamycin (TOR)-mediated control of nutrient uptake, specifically endocytosis, building on novel preliminary data that identifies novel TOR control points. The expected outcomes include new insights into mechanisms controlling nutrient uptake and fostering institutional collaboration. This knowledge is highly relevant to any industry or research project utilising living organisms, as nutrient availability supports survival, cell growth and proliferation.Read moreRead less
Mechanisms Of Premature Cranial Fusion: Role Of Retinol Binding Protein 4 In Osteogenesis And Suture Fusion
Funder
National Health and Medical Research Council
Funding Amount
$555,855.00
Summary
Craniosynostosis is a condition where the skull bones fuse prematurely, affecting skull shape, vision and cognition. It occurs in 1 in 2,500 births. The only treatment is surgery, which is life-threatening, costly and may need to be repeated. By studying how fusion happens in this project we may be able to devise therapies to minimize the risks and need for re-operation. Here, we hope to show that modification of a single substance in the skull of mouse models can prevent premature bone fusion.
The migration of cancer cells (metastasis) is responsible for most cancer deaths. Central to this is dynamic organisation of the actin cytoskeleton _ an internal structure that provides cell shape and enables movement. We have identified a family of small molecules (called miR-200) that regulates this actin cytoskeleton through specifically downregulating various genes. We are investigating the nature of these genes and their role in cell motility _ an underlying pre-requisite of metastasis.
Mechanisms controlling enteroendocrine hormone secretion in human duodenum. This project aims to gain a deeper understanding of nutrient sensing pathways present in enteroendocrine cells within the human intestine. These cells control digestive function, blood glucose levels and food intake and are thus critical to digestion. This project will endeavour to be the first to assess the biology of human enteroendocrine cells and will use innovative approaches to deeply assess function from the level ....Mechanisms controlling enteroendocrine hormone secretion in human duodenum. This project aims to gain a deeper understanding of nutrient sensing pathways present in enteroendocrine cells within the human intestine. These cells control digestive function, blood glucose levels and food intake and are thus critical to digestion. This project will endeavour to be the first to assess the biology of human enteroendocrine cells and will use innovative approaches to deeply assess function from the level of the individual to isolated enteroendocrine cells.Read moreRead less