The greatest impact of Plasmodium falciparum malaria infection in Africa is on children and pregnant women. Malaria infected red blood cells stick to receptor molecules on cells lining blood vessels. The parasite produces a family of proteins called PfEMP1, expressed on the cell surface. These PfEMP1 proteins are responsible for the sticking, and are major targets of the host immune response to malaria. We have found two particular receptor molecules, sugars called chondroitin sulphate A (CSA) a ....The greatest impact of Plasmodium falciparum malaria infection in Africa is on children and pregnant women. Malaria infected red blood cells stick to receptor molecules on cells lining blood vessels. The parasite produces a family of proteins called PfEMP1, expressed on the cell surface. These PfEMP1 proteins are responsible for the sticking, and are major targets of the host immune response to malaria. We have found two particular receptor molecules, sugars called chondroitin sulphate A (CSA) and hyaluronic acid (HA), to be particularly important in sticking in the placenta, and have identified a PfEMP1 molecule which sticks to these. We will study the role of antibodies against the parasite, and against the CSA and HA molecules, in protection against malaria. We believe that African women develop these antibodies with increasing pregnancies, protecting themselves and their babies from malaria in later pregnancies, and that men will not have these antibodies. Pregnant women who have HIV-AIDS have greater susceptiblity to malaria. We will compare antibody responses in HIV+ and HIV- women to see if this is because they produce less protective antibodies. The PfEMP1 proteins are the product of var genes. We can compare parasites using the var genes they express to fingerprint them. We will examine the var gene expression by parasites from different patients, and by the parasites circulating in the blood or stuck in the placenta (in pregnant women) or in the brain, lung, gut and other organs (of children who have died of malaria) to see if the fingerprints of var gene expression differ between these different patients, or between different places in the same patient.Read moreRead less
Placental Malaria, Placental Function, Nutrient Transport And Fetal Growth Restriction
Funder
National Health and Medical Research Council
Funding Amount
$483,517.00
Summary
Malaria infection in the placenta impairs the baby's growth, probably by causing placental inflammation. We believe this inflammation interferes with the ability of placental cells to transport nutrients such as amino acids and glucose from mother to baby. We will test this by examining the expression of genes and proteins involved in nutrient transport in placental samples from pregnant women, and in cell lines, and will examine how malaria affects growth factors that control this process.
Functional Genomic Analysis Of Exported DNA J Molecules In The Malaria Parasite Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$529,698.00
Summary
Every day 3500 people die of malaria and more than 40% of the world s population is at risk. Malaria is one of the biggest scourges of mankind. This project aims to translate the available genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets against malaria is important from a humanitarian point of view, and also to safeguard Australia and its neighbouring regions against the social and economic ....Every day 3500 people die of malaria and more than 40% of the world s population is at risk. Malaria is one of the biggest scourges of mankind. This project aims to translate the available genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets against malaria is important from a humanitarian point of view, and also to safeguard Australia and its neighbouring regions against the social and economical implication of this disease. The malaria parasite seeks shelter from the host immune system by hiding in red blood cells, but at the same time it has to stay in contact with the blood environment. This is achieved by export of virulence factors onto the surface of malaria parasite-infected red blood cells, which are essential for the maintenance of malaria infection. Without these virulence factors the body's immune system can get rid of the malaria parasites by itself. For display on the surface the proteins have to pass several membranes and are transferred through the red blood cell. The whole transport and assembly process of the virulence factors into functional units is very complex and requires several helper and co-helper molecules. With the deciphering of the malarial genetic code it became obvious that the parasite displays an unusual large number of co-helper molecules, which are putatively exported into the red blood cell. We will generate transgenic parasites deficient in the expression of these exported co-helper proteins and assess their role on the pathogenesis of this debilitating infectious disease.Read moreRead less