Transbilayer Phospholipid Asymmetry in Plasmodium knowlesi- Infected Host Cell Membrane

The membranes from normal and Plasmodium knowlesi-infected rhemsus monkey erythrocytes (90 to 95 percent infected with early ring stage) were analyzed for transbilayer distribution of phosphatidylcholine (PC). hosphatidylethanolamine (PE). and hosphatidylserine (PS). by means of chemical and enzymatic probes. The external monolayer of the normal red cell membrane contained at least 68 to 72 percent of the total phosphatidylcholine and 15 to 20 percent of the total phosphati dylethanolamine. In the infected cell, the transmembrane phosphatidylcholine distribution appeared to be reversed, with only 20 to 30 percent of it being externally localized, whereas roughly equal amounts of phosphatidylethanolamine were present in the outer and'inner surfaces. However, total pho.~phatid)'lserine in both the infected and normal red cells was exc/usi~'ely internal. Unlike that in the normal intact cell, external phosphatidylethanolamine in the parasitized cell was readily accessible to phospholipase A2. These results indicate that significant changes in molecular architecture of the host cell membrane are the result of varasitization.

A new look at nonparasitized red cells of malaria-infected monkeys

Many reports have shown that malarial parasites can produce distinct morphological and molecular alterations in the membranes of the parasitized erythrocytes (l-8), but few studies have been carried out on nonparasitized erythrocytes of infected animals (9-11).We report here that the outer leaflet of the membrane bilayer of non parasitized erythrocytes contains significantly larger amounts of aminophospholipids (phosphatidylethanolamine (PE) and phosphatidylserine (PS), than the normal red cell membrane. This alteration in nonparasitized red cells is probably caused by Ca2+ -induced crosslinking of spectrin, and gradually disappears after chloroquine treatment. The external localization of PS in these cells together with defective structure of their cytoskeletal network provide a strong basis for the complications associated with malaria infection like thrombosis, infarction and severe anaemia.