Abstract
Despite recent efforts toward control and elimination, malaria remains a major public health problem worldwide. Plasmodium falciparum resistance against artemisinin, used in front line combination drugs, is on the rise, and the only approved vaccine shows limited efficacy. Combinations of novel and tailored drug and vaccine interventions are required to maintain the momentum of the current malaria elimination program. Current evidence suggests that strain-transcendent protection against malaria infection can be achieved using whole organism vaccination or with a polyvalent vaccine covering multiple antigens or epitopes. These approaches have been successfully applied to the human-infective sporozoite stage. Both systemic and tissue-specific pathology during infection with the human malaria parasite P. falciparum is caused by asexual blood stages. Tissue tropism and vascular sequestration are the result of specific binding interactions between antigens on the parasite-infected red blood cell (pRBC) surface and endothelial receptors. The major surface antigen and parasite ligand binding to endothelial receptors, PfEMP1 is encoded by about 60 variants per genome and shows high sequence diversity across strains. Apart from PfEMP1 and three additional variant surface antigen families RIFIN, STEVOR, and SURFIN, systematic analysis of the infected red blood cell surface is lacking. Here we present the most comprehensive proteomic investigation of the parasitized red blood cell surface so far. Apart from the known variant surface antigens, we identified a set of putative single copy surface antigens with low sequence diversity, several of which are validated in a series of complementary experiments. Further functional and immunological investigation is underway to test these novel P. falciparum blood stage proteins as possible vaccine candidates.
Highlights
From the ‡Department of Immunology and Infectious Diseases, Harvard T.H
Membrane Proteomics: An Immune Profiling Approach to Identify P. falciparum Surface Antigens—In a first series of experiments, we performed a combination of immune profiling using sera from mice immunized with shaved or unshaved parasitized red blood cells (RBC) (pRBC) membranes and proteomics of pRBC membranes, with the aim to identify pRBC surface antigens (Fig. 1A)
To optimize the preparation of surface-shaved pRBCs, we assessed whether addition of sucrose (as used in surface shaving of Gram-positive bacteria [35, 36]) could reduce RBC lysis previously seen with Phosphate-buffered saline (PBS) alone
Summary
From the ‡Department of Immunology and Infectious Diseases, Harvard T.H. Chan School of Public Health, Boston, Massachusetts 02115; §The Broad Institute of MIT and Harvard, Cambridge, Massachusetts 02142; ¶Wellcome Centre for Molecular Parasitology, University of Glasgow, Glasgow G12 8TA, UK; ʈSanofi Biopharmaceutics Development, Framingham, Massachusetts 02142; **Sanofi Pasteur Biologics, Cambridge, Massachusetts 02139; ‡‡Department of Pathology, Brigham and Women’s Hospital, Boston, Massachusetts 02115. We present the most comprehensive proteomic investigation of the parasitized red blood cell surface so far. Plasmodium falciparum Surface Proteomics sites start an active process of host cell remodeling. As mature RBCs lack organelles and intracellular membranes, parasite-derived trafficking machinery is introduced into the host cell cytosol to export parasite antigens to the RBC and its plasma membrane. Such antigens can establish new permeation pathways for nutrient uptake, induce adherence of parasitized RBCs (pRBC) to the vascular lining in the deep tissue (sequestration), bind unparasitized RBCs (rosetting), or evade immunity by antigenic variation (reviewed in [2])
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