Microparticles as effectors of microvascular alterations in brain inflammation. Cerebral malaria (CM) kills many children worldwide, but we do not understand why their small blood vessels in the brain become obstructed. We found that tiny elements detached from cell membranes, called microparticles (MP), are dramatically elevated in the blood during CM. Our results strongly suggest that these MP are important in CM development. We have found that some drugs block the release of MP and the stick ....Microparticles as effectors of microvascular alterations in brain inflammation. Cerebral malaria (CM) kills many children worldwide, but we do not understand why their small blood vessels in the brain become obstructed. We found that tiny elements detached from cell membranes, called microparticles (MP), are dramatically elevated in the blood during CM. Our results strongly suggest that these MP are important in CM development. We have found that some drugs block the release of MP and the stickiness of malaria parasites to blood vessels. Our project will tackle the conditions of MP production and define new drugs to prevent it. It also will explain how the brain becomes affected by high numbers of MP. Our results will cast new light on why the brain functions abnormally when its blood vessels become modified.Read moreRead less
Brain metabolic changes in experimental malaria: a paradigm for the molecular mechanisms of intravascular inflammation. Malaria is endemic in countries directly to the north of Australia, as close as Papua New Guinea and East Timor. This project's findings about malaria also will have relevance to other infectious diseases of national importance. The outcomes will contribute to Australia's research reputation. We will build international links that will increase the national knowledge base and r ....Brain metabolic changes in experimental malaria: a paradigm for the molecular mechanisms of intravascular inflammation. Malaria is endemic in countries directly to the north of Australia, as close as Papua New Guinea and East Timor. This project's findings about malaria also will have relevance to other infectious diseases of national importance. The outcomes will contribute to Australia's research reputation. We will build international links that will increase the national knowledge base and research skill base. Young scientists will be trained in state-of-the-art research techniques in a cross-disciplinary environment that is the way of future biological research. The project may identify potential drug targets for malaria or other infectious diseases. The Intellectual Property will be protected and commercialised.Read moreRead less
Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential ground ....Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential groundwork for the development of drugs that target this transport mechanism.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668450
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Upgrade of comparative phenotypical and functional cell analysis at James Cook University. North Queensland is a fast growing region with significant need for the development of a world-class research facility. James Cook University has recently established the Comparative Genomics Centre at the School of Pharmacy and Molecular Sciences, which will contribute to education and basic research in the region. The research outcomes from the projects of the Comparative Genomics Centre and affiliated l ....Upgrade of comparative phenotypical and functional cell analysis at James Cook University. North Queensland is a fast growing region with significant need for the development of a world-class research facility. James Cook University has recently established the Comparative Genomics Centre at the School of Pharmacy and Molecular Sciences, which will contribute to education and basic research in the region. The research outcomes from the projects of the Comparative Genomics Centre and affiliated laboratories facilitated by the analytical flow cytometer will support the definition and identification of the interactions between genetic and environmental factors in disease and will help to attract researchers. Results from this work will aid the search for therapies for specific health problems.Read moreRead less
Role of the GxxxG domain in the function of mammalian prion proteins. Prion proteins have been associated with a number of diseases of humans and animals (such as Creutzfeldt-Jakob Disease in humans and BSE, or 'mad-cow' disease in cattle) which have had major public health, social and economic consequences in countries where they have been detected. This project will identify mechanisms by which a highly conserved region of the prion protein plays a role in the conversion to the disease associa ....Role of the GxxxG domain in the function of mammalian prion proteins. Prion proteins have been associated with a number of diseases of humans and animals (such as Creutzfeldt-Jakob Disease in humans and BSE, or 'mad-cow' disease in cattle) which have had major public health, social and economic consequences in countries where they have been detected. This project will identify mechanisms by which a highly conserved region of the prion protein plays a role in the conversion to the disease associated form. This will provide avenues for identifying the normal function of the prion protein, and increase our knowledge of prion biology. This will benefit both in terms of healthy ageing and in protecting the agriculture sector from prion diseases in farmed animals.Read moreRead less
Identification and characterisation of caspase inhibitors. Organisms use a tightly controlled process of cell death (termed apoptosis) to remove dangerous and unwanted cells. Dysregulation of this process can contribute to diseases such as cancer and autoimmune disease. Caspases are protease effectors of apoptosis. Regulation of their activity is vital for effective control of cell survival and death. Using a functional screening system invented by the 1st CI, we aim to isolate and characterise ....Identification and characterisation of caspase inhibitors. Organisms use a tightly controlled process of cell death (termed apoptosis) to remove dangerous and unwanted cells. Dysregulation of this process can contribute to diseases such as cancer and autoimmune disease. Caspases are protease effectors of apoptosis. Regulation of their activity is vital for effective control of cell survival and death. Using a functional screening system invented by the 1st CI, we aim to isolate and characterise novel inhibitors of caspases. Such inhibitors may in time be used as targets for development of therapeutic or diagnostic reagents aimed at manipulating the apoptotic process to diagnose, prevent or treat disease.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100226
Funder
Australian Research Council
Funding Amount
$424,000.00
Summary
Advanced molecular discovery and characterisation facility. Natural product drug discovery in Australia requires access to high throughput functional assays to guide the separation and of novel bioactives with therapeutic potential. By establishing the advanced molecular discovery and characterisation facility in an academic environment across two institutions, research programs in early drug lead discovery and characterisation will be accelerated. It will provide unique capabilities not curren ....Advanced molecular discovery and characterisation facility. Natural product drug discovery in Australia requires access to high throughput functional assays to guide the separation and of novel bioactives with therapeutic potential. By establishing the advanced molecular discovery and characterisation facility in an academic environment across two institutions, research programs in early drug lead discovery and characterisation will be accelerated. It will provide unique capabilities not currently available in Australia, and help Australian researchers remain internationally competitive in breakthrough science and frontier technologies. The research enabled by this facility will lead to development of new drug candidates by the emerging Australian biotechnology industry.Read moreRead less
The biology, structure and function of bacterial virulence effectors. This project is closely aligned with the National Research Priority of Promoting and Maintaining Good Health and will establish a research framework to investigate novel virulence processes that allow bacterial pathogens to infect humans and cause disease. This fresh approach to the study of bacterial pathogenesis will sit outside classic genetic methods to investigate infection and immunity which rely heavily on genetic manip ....The biology, structure and function of bacterial virulence effectors. This project is closely aligned with the National Research Priority of Promoting and Maintaining Good Health and will establish a research framework to investigate novel virulence processes that allow bacterial pathogens to infect humans and cause disease. This fresh approach to the study of bacterial pathogenesis will sit outside classic genetic methods to investigate infection and immunity which rely heavily on genetic manipulation of the pathogen. Other than providing fundamental information on host-pathogen interactions, this work may lead to novel disease interventions by inhibition of bacterial virulence factor activity and/or enhancement of host inflammatory and immune responses.Read moreRead less
Identification of novel markers of inflammation. This project will benefit Australia as it will increase basic understanding of inflammatory processes, result in a new generation of diagnostics for inflammatory diseases that could lead to earlier diagnosis and to monitor treatment, resulting in large economic and health benefit. It may lead to development of novel new therapies using monoclonal antibodies to regulate processes in immune, cardiovascular and infectious diseases. The work will gene ....Identification of novel markers of inflammation. This project will benefit Australia as it will increase basic understanding of inflammatory processes, result in a new generation of diagnostics for inflammatory diseases that could lead to earlier diagnosis and to monitor treatment, resulting in large economic and health benefit. It may lead to development of novel new therapies using monoclonal antibodies to regulate processes in immune, cardiovascular and infectious diseases. The work will generate significant economic spin-offs to the Australian biotechnology industry and will further relationships and training between research and development.Read moreRead less
Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight i ....Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight into CTL generation by providing greater understanding of how multicellular systems function both at the cellular and molecular level.Read moreRead less