Effector Export In P. Falciparum Infected Human Erythrocytes
Funder
National Health and Medical Research Council
Funding Amount
$1,066,920.00
Summary
We will investigate malaria, a parasitic disease that kills over 450,000 people a year. We will explore how the parasite identifies, invades and remodels the host cells in which it lives, scavenging nutrients and hiding from the immune system. We will characterize the proteins involved in these critical events, as they are potential targets for drugs. We will study how parasites cause disease and how the host responds to infection.
The Structural Resolution Of PTEX, The Translocon Of Virulence Proteins And Malaria Parasites.
Funder
National Health and Medical Research Council
Funding Amount
$561,028.00
Summary
The extraordinary virulence of malaria parasites is in part due to their ability to export hundreds of proteins into their red blood cell hosts that help them obtain nutrients and avoid the immune system. Recently we discovered the molecular machine that exports proteins into the host cell and we now wish to establish how it works so drugs can be tailored to block the machine and kill the parasites.
Functional Dissection Of The Malaria RhopH Complex And Its Contribution To New Permeation Pathways
Funder
National Health and Medical Research Council
Funding Amount
$604,718.00
Summary
The ability of Plasmodium to invade and remodel its host erythrocyte are the most significant contributors to its ability to cause the disease malaria. This project aims to understand how proteins secreted from a specialized rhoptry organelle during erythrocyte invasion help Plasmodium to remodel the erythrocyte so that the parasite can gain access to the vital nutrients it requires for survival. This research will validate whether drugs targeting the rhoptry proteins are viable drug targets.
Determining The Mechanistic Basis Of The Patterns Of Inverse Drug Susceptibility Induced By Two Key Drug Resistance Proteins Of The Malaria Parasite.
Funder
National Health and Medical Research Council
Funding Amount
$567,273.00
Summary
The inexhaustible capacity of many pathogens and cancers to develop resistance to new drugs is a serious threat to world health. Yet in acquiring resistance to one drug, many pathogens and cancer cells become hypersensitive to one or more other drugs. We seek to elucidate several of the molecular mechanisms underpinning this phenomenon in the malaria parasite. Insights gained from this work will contribute to the formulation of new therapeutic strategies that overcome or retard drug resistance.
Malaria is a devastating disease of global significance. With mounting resistance to current drugs and no licensed malaria vaccine, there is a pressing need to search for new strategies to reduce the global burden of malaria. My research program aims to understand how the parasites that cause malaria extensively renovate the cells in which they reside and subvert their host so that they can thrive and survive, with a view to identifying new pathways that can be targeted by drugs or vaccines.
Functional Characterisation Of The Malaria Protein Export Machinery
Funder
National Health and Medical Research Council
Funding Amount
$556,104.00
Summary
The ability of malaria parasites to cause one of the most devastating infectious diseases of humans is in part due to their ability to export hundreds of proteins into their host red blood cells to obtain nutrients, evade the immune system and contribute to associated pathologies. Recently, we discovered the molecular machine that exports proteins into the host cell and so now we wish to establish how it works so that drugs can be tailored to block it to kill these parasites.
Dissecting The Interactions Of Antimalarial Drugs With The Two Key Determinants Of Drug Resistance In The Malaria Parasite - The 'chloroquine Resistance Transporter' And The 'multidrug Resistance Transporter 1'
Funder
National Health and Medical Research Council
Funding Amount
$415,218.00
Summary
The malaria parasite is a single-celled organism which invades the red blood cells of its host. The aim of this fellowship is to study two proteins that are central to the parasite’s ability to evade the toxic effects of a number of drugs. The parasite's susceptibility to chloroquine, and other drugs, is altered by small changes in these proteins. This work will advance our understanding of the increasingly widespread phenomenon of antimalarial drug resistance, and of how it may be overcome.