Fatty Acid Biosynthesis In The Malaria Chloroplast As A Drug Target
Funder
National Health and Medical Research Council
Funding Amount
$131,035.00
Summary
Malarial parasites contain a chloroplast similar to that of plants. We recently found genetic evidence suggesting the malaria chloroplast makes fats in the same way as plant chloroplasts. Additionally, we have found that drugs and herbicides that block plant chloroplast fat production stop growth of malaria cultures. Parasitologists had assumed that malaria was unable to make fats and would scavenge them from its human host so we have probably discovered a new metabolic pathway in these parasite ....Malarial parasites contain a chloroplast similar to that of plants. We recently found genetic evidence suggesting the malaria chloroplast makes fats in the same way as plant chloroplasts. Additionally, we have found that drugs and herbicides that block plant chloroplast fat production stop growth of malaria cultures. Parasitologists had assumed that malaria was unable to make fats and would scavenge them from its human host so we have probably discovered a new metabolic pathway in these parasites. We now propose to prove that the drugs work by blocking essential, chloroplast-based fat production in parasites. This could lead to novel treatment of malaria and related parasites.Read moreRead less
Bridging The Gap Between Cartilage Biology And Osteoarthritis Risk Prediction
Funder
National Health and Medical Research Council
Funding Amount
$512,256.00
Summary
Osteoarthritis is a painful and debilitating cartilage disease affecting just under 1 in 10 Australians and costs the Australian economy roughly $12 billion per year. This project will develop computational models of cartilage with the ability to incorporate genetic and environmental risk factors into a predictive model of cartilage disease.
Coenzyme A Synthesis In The Human Malaria Parasite, Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$428,250.00
Summary
Malaria is responsible for hundreds of millions of cases and an estimated 1.5-2.7 million deaths each year. The disease is caused by a microscopic parasite which is becoming increasingly resistant to antimalarial drugs. There is a very real possibility that there will soon be parts of the world in which malaria is an untreatable disease, and there is an urgent need to identify new drug targets. This work focuses on a particular biochemical pathway in the human malaria parasite, Plasmodium falcip ....Malaria is responsible for hundreds of millions of cases and an estimated 1.5-2.7 million deaths each year. The disease is caused by a microscopic parasite which is becoming increasingly resistant to antimalarial drugs. There is a very real possibility that there will soon be parts of the world in which malaria is an untreatable disease, and there is an urgent need to identify new drug targets. This work focuses on a particular biochemical pathway in the human malaria parasite, Plasmodium falciparum. The pathway mediates the conversion of the nutrient, vitamin B5, into a molecule called Coenzyme A. It plays an essential role in the intraerythrocytic parasite and our preliminary data indicate that components of this pathway hold significant potential as antimalarial drug targets. In this project we will use a range of biochemical and molecular biology approaches to characterise in detail the components of this pathway in the parasite and to explore the possibility that compounds that inhibit this pathway may be of value as much-needed new antimalarial agents.Read moreRead less
I have discovered particular factors produced by our white blood cells have the ability to shut down or boost protein production in the gut, pancreas and lung. My vision is to harness these to devise new strategies for treatments for infectious and non-infectious diseases (inflammatory bowel disease, diabetes) that have a high burden on our healthcare system.
Targeting Redox Homeostasis To Prevent Mycobacterium Tuberculosis Persistence
Funder
National Health and Medical Research Council
Funding Amount
$396,025.00
Summary
Tuberculosis is now the leading cause of death from infectious disease worldwide. This reflects the ability of its causative agent to persist, leading to failure of antibiotic treatment and development of drug resistance. In this project, we propose to overcome this by inhibiting a unique metabolic pathway that is activated when the pathogen enters its persistent state. We will use a cutting-edge combination of techniques to develop this pathway for next-generation therapies.