Plasmodium-specific antibodies block in vivo parasite growth without clearing infected red blood cells.

Jasmin Akter,Megan S F Soon,Trish Elliott,Rosemary Aogo,Lily G Fogg,Deborah Cromer,Miles P Davenport,Kylie R James,David S Khoury,Ismail Sebina,Jessica A Engel,Ashraful Haque,Pawat Laohamonthonkul,Arya Sheelanair,Matthew W A Dixon,Bryce S Thomas,Clara P S Pernold,Lianne I M Lansink,Michael J Blackman

doi:10.1371/journal.ppat.1007599

Abstract

Plasmodium parasites invade and multiply inside red blood cells (RBC). Through a cycle of maturation, asexual replication, rupture and release of multiple infective merozoites, parasitised RBC (pRBC) can reach very high numbers in vivo, a process that correlates with disease severity in humans and experimental animals. Thus, controlling pRBC numbers can prevent or ameliorate malaria. In endemic regions, circulating parasite-specific antibodies associate with immunity to high parasitemia. Although in vitro assays reveal that protective antibodies could control pRBC via multiple mechanisms, in vivo assessment of antibody function remains challenging. Here, we employed two mouse models of antibody-mediated immunity to malaria, P. yoelii 17XNL and P. chabaudi chabaudi AS infection, to study infection-induced, parasite-specific antibody function in vivo. By tracking a single generation of pRBC, we tested the hypothesis that parasite-specific antibodies accelerate pRBC clearance. Though strongly protective against homologous re-challenge, parasite-specific IgG did not alter the rate of pRBC clearance, even in the presence of ongoing, systemic inflammation. Instead, antibodies prevented parasites progressing from one generation of RBC to the next. In vivo depletion studies using clodronate liposomes or cobra venom factor, suggested that optimal antibody function required splenic macrophages and dendritic cells, but not complement C3/C5-mediated killing. Finally, parasite-specific IgG bound poorly to the surface of pRBC, yet strongly to structures likely exposed by the rupture of mature schizonts. Thus, in our models of humoral immunity to malaria, infection-induced antibodies did not accelerate pRBC clearance, and instead co-operated with splenic phagocytes to block subsequent generations of pRBC.

Highlights

Clinical symptoms of malaria occur during the erythrocytic phase of infection, when Plasmodium parasites mature and replicate asexually in red blood cells (RBC) [1]
Malaria occurs when Plasmodium parasites replicate inside red blood cells, with the number of parasitised cells correlating with disease severity
Antibodies are highly effective at controlling parasitised RBC (pRBC) numbers in the bloodstream, and yet we know very little about how they function in vivo

Summary

Introduction

Clinical symptoms of malaria occur during the erythrocytic phase of infection, when Plasmodium parasites mature and replicate asexually in red blood cells (RBC) [1]. A key feature of the asexual life-cycle in RBC is the capacity for rapid population growth, because each parasite can produce many daughter parasites (up to 32 daughter merozoites). The fold-increase in parasitised RBC (pRBC) from one cycle to the is expressed by Parasite Multiplication Rate, PMR, a useful measure of parasite growth [2,3,4]. PMR can be influenced by host and parasite factors, such as how many merozoites are produced per replicating parasite, or how effectively the host clears parasites from the bloodstream. If PMR = 16, four cycles of infection could theoretically result in a 65,536-fold (164) increase in pRBC density. It is important to minimise parasite replication to reduce the risk and severity of malaria

Methods

Results

Discussion

Conclusion