The Role Of Duffy And PF4 In The Platelet Killing Of Malaria Parasites.
Funder
National Health and Medical Research Council
Funding Amount
$350,045.00
Summary
Platelets in the blood can kill the Plasmodium parasite, which lives inside red blood cells and causes malaria. Platelets bind parasite-infected red cells and release a molecule that is toxic to the parasite. This project will study why a red cell molecule called Duffy is also needed for this function of platelets. Most Africans carry a gene for Duffy that stops its expression in red cells, and may therefore be more susceptible to malaria because their platelets cannot kill the malaria parasite.
Analysing the protective role of platelets during malaria infection. Platelets protect the host during malarial infection. This project aims to study how platelets kill the malaria parasite by investigating the role of host molecules and their potential as novel antimalarial agents. The role of platelets in the pathogenesis of cerebral malaria syndrome will also be investigated.
Biogenesis of red blood cell membrane modifications by the malaria parasite Plasmodium falciparum. Malaria is not only a major global health problem, but also affects countries neighbouring Australia like Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (aid and military personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology to identi ....Biogenesis of red blood cell membrane modifications by the malaria parasite Plasmodium falciparum. Malaria is not only a major global health problem, but also affects countries neighbouring Australia like Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (aid and military personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology to identify new intervention targets for Plasmodium falciparum infection. Developing novel targets is mandated by humanity, but also to safeguard Australia's region against the social and economic implications of this disease. An Australian developed intervention would increase the global visibility of its science, leading to increased investments.Read moreRead less
Functional Genomic Analysis of Exported DNAJ Molecules in the Malaria Parasite Plasmodium falciparum. Malaria is not only a global health problem, but also affects countries surrounding Australia like PNG and Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (eg. aid and security personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology t ....Functional Genomic Analysis of Exported DNAJ Molecules in the Malaria Parasite Plasmodium falciparum. Malaria is not only a global health problem, but also affects countries surrounding Australia like PNG and Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (eg. aid and security personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets is mandated by humanity, and also to safeguard Australia's region against the social and economical implication of this disease. An Australian developed intervention would increase the global visibility of its science, leading to increased investments.Read moreRead less
Targeting An Ion Pump In The Malaria Parasite With Multiple Compound Classes
Funder
National Health and Medical Research Council
Funding Amount
$384,686.00
Summary
Large-scale antimalarial drug screening projects have identified three different classes of compound that kill the malaria parasite at extremely low doses and which hold real promise as next-generation antimalarials. Genetic evidence, as well as preliminary data from our own lab, has led us to the hypothesis that all three compound classes exert their antimalarial effect by blocking a molecular ion pump on the parasite surface. The aim of this study is to test this.
Identification of structural proteins in the tissue cyst wall of Toxoplasma gondii. Most infections with Toxoplasma gondii are asymptomatic, however, infection during pregnancy can lead to miscarriage or blindness, deafness and mental retardation in the developing baby. Furthermore, in AIDS patients, toxoplasmosis is the leading cause of fatal encephalitis as the normally dormant tissue cysts are reactivated in the absence of an effective immune system. In Australia, it has been estimated that ~ ....Identification of structural proteins in the tissue cyst wall of Toxoplasma gondii. Most infections with Toxoplasma gondii are asymptomatic, however, infection during pregnancy can lead to miscarriage or blindness, deafness and mental retardation in the developing baby. Furthermore, in AIDS patients, toxoplasmosis is the leading cause of fatal encephalitis as the normally dormant tissue cysts are reactivated in the absence of an effective immune system. In Australia, it has been estimated that ~30% of the population is infected with T. gondii and the occurrence of congenital toxoplasmosis is 0.2% of live births, which translates to roughly 500 cases/year. Our research will identify structural proteins in Toxoplasma cyst walls that will lead to the design of new strategies to control the diseases caused by these parasites.Read moreRead less
Composition, assembly and functions of the pellicle of apicomplexan parasites: a structure pivotal to disease transmission and progression. Apicomplexan parasites are successful agents of disease (e.g. malaria) due to their superb ability to quickly invade host cells and generate many more parasites. This project will study the dedicated structures beneath the parasite cell covering that are responsible for these abilities to help refine strategies for combating apicomplexan diseases.
Biogenesis of the relict plastid of Apicomplexan parasites: the role of a dynamin-related protein in apicoplast division. The Apicomplexa are a group of intracellular parasites that cause several important diseases. Most Apicomplexa contain an organelle called the apicoplast that is indispensable for their survival and that can only form through the division of pre-existing apicoplasts. This project will examine the molecular mechanisms of how this process occurs.