Abstract
While many parasites develop within host cells to avoid antibody responses and to utilize host cytoplasmic resources, elaborate egress processes have evolved to minimize the time between escaping and invading the next cell. In human erythrocytes, malaria parasites perforate their enclosing erythrocyte membrane shortly before egress. Here, we show that these pores clearly function as an entry pathway into infected erythrocytes for compounds that inhibit parasite egress. The natural glycosaminoglycan heparin surprisingly inhibited malaria parasite egress, trapping merozoites within infected erythrocytes. Labeled heparin neither bound to nor translocated through the intact erythrocyte membrane during parasite development, but fluxed into erythrocytes at the last minute of the parasite lifecycle. This short encounter was sufficient to significantly inhibit parasite egress and dispersion. Heparin blocks egress by interacting with both the surface of intra-erythrocytic merozoites and the inner aspect of erythrocyte membranes, preventing the rupture of infected erythrocytes but not parasitophorous vacuoles, and independently interfering with merozoite disaggregation. Since this action of heparin recapitulates that of neutralizing antibodies, membrane perforation presents a brief opportunity for a new strategy to inhibit parasite egress and replication.
Highlights
To evade immune detection, intracellular apicomplexan parasites replicate within several layers of membranes[1,2]
Our data show that the highly-charged natural polymer heparin inhibits P. falciparum egress in vitro, exploiting a previously-unrecognized mode of interaction with infected erythrocytes from within, entering cells through parasite-derived pores in the erythrocyte membrane prior to parasite egress
The following heparin-cell interactions show the topology of proteins that are critically involved in the egress mechanism: surface proteins of merozoites and the inner aspect of erythrocyte membranes
Summary
Intracellular apicomplexan parasites replicate within several layers of membranes[1,2] This replication is only advantageous if parasite progeny can emerge successfully from host cells after breaking both the parasitophorous vacuolar membrane and the erythrocyte plasma membrane to invade new cells. Perforin-like protein 1 of P. falciparum was suggested to perforate both the parasitophorous vacuolar membrane and the erythrocyte membrane during the asexual cycle[15], but a recent study demonstrated it is dispensable for blood-stage parasite growth[16]. Entry could only occur at the very end of the replicative cycle, to inhibit parasite egress This was a surprising observation, because in analogy to antiviral mechanisms[21], it is postulated that heparin inhibits invasion in vitro by binding to merozoite surface proteins just prior to invasion, blocking subsequent merozoite binding to the erythrocyte surface[17] (there is a clear non-specific loss of merozoite adhesion)[22]. Our findings are the first indication of a technological application for the molecular-perforation stage of infected erythrocytes prior to egress
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