Ion Transport In The Human Malaria Parasite, Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
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. However, despite the significance of the malaria parasite for world health, the basic physiology of th ....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. However, despite the significance of the malaria parasite for world health, the basic physiology of this organism is poorly understood. This project focuses on the mechanisms involved in ion balance in the parasite. Ion balance is a basic 'housekeeping' function in all cells, and disruption of the mechanisms involved will inevitably impair cell function. The work proposed here will lead to an understanding of ion balance in the intracellular parasite and provide insight into whether the mechanisms involved may be suitable antimalarial drug targets.Read moreRead less
Chloroquine Resistance And The Physiology Of The Malaria Parasite S Digestive Vacuole
Funder
National Health and Medical Research Council
Funding Amount
$287,921.00
Summary
Malaria is an infectious disease, caused by a single-celled parasite which invades the red blood cells of its human host. Each year, malaria causes the death of up to 3 million people, mostly children under the age of 5 The parasite has become resistant to most, if not all, of the antimalarial drugs presently available, and there is no vaccine. There is therefore an urgent need to develop new antimalarial drugs, and-or to devise strategies for overcoming the parasite s drug resistance mechanisms ....Malaria is an infectious disease, caused by a single-celled parasite which invades the red blood cells of its human host. Each year, malaria causes the death of up to 3 million people, mostly children under the age of 5 The parasite has become resistant to most, if not all, of the antimalarial drugs presently available, and there is no vaccine. There is therefore an urgent need to develop new antimalarial drugs, and-or to devise strategies for overcoming the parasite s drug resistance mechanisms. Chloroquine was, for many years, the mainstay of antimalarial chemotherapy and was, in many senses, a 'wonder-drug' cheap, safe and effective. However the emergence and spread of parasites that are resistant to chloroquine has meant that the drug is now largely useless as an antimalarial. Chloroquine kills (sensitive) parasite through an effect on the parasite s digestive vacuole an internal acidic compartment in which the parasite breaks down protein taken up from its host red blood cell. This compartment plays a crucial role in the growth and proliferation of the parasite. Yet we understand very little about its basic physiology, and nor do we understand the mechanism by which chloroquine-resistant parasites are able to survive exposure to the drug. The aim of the work proposed here is to gain an increased understanding of some of the mechanisms underlying the physiology of the parasite s digestive vacuole, as well as some of the factors influencing the accumulation of chloroquine within this compartment. The former part of the work may well reveal new antimalarial drug targets. The latter part of the work will increase our understanding of the mechanism of chloroquine resistance, thereby laying the groundwork for strategies by which these mechanisms might be circumvented and chloroquine-related drugs thereby restored to the front-line of our ongoing and increasingly desperate fight against malaria.Read moreRead less
Determining Fundamental Mechanisms Compromised In Kir-linked Disease States
Funder
National Health and Medical Research Council
Funding Amount
$600,040.00
Summary
The human nervous system and organs are reliant on precisely controlled transmission of electrical currents through sodium and potassium channels. Their core functions are compromised when currents fail to switch on and off normally. Faulty potassium channels are implicated in diabetes, epilepsy and heart failure. This project re-examines the mechanisms controlling potassium channels, with a view to scientific and therapeutic discrimination between the different classes present in human cells.