Preclinical efficacy and immunogenicity assessment to show that a chimeric Plasmodium falciparum UB05-09 antigen could be a malaria vaccine candidate.

Although it is generally agreed that an effective vaccine would greatly accelerate the control of malaria, the lone registered malaria vaccine Mosquirix™ has an efficacy of 30%-60% that wanes rapidly, indicating a need for improved second-generation malaria vaccines. Previous studies suggested that immune responses to a chimeric Plasmodium falciparum antigen UB05-09 are associated with immune protection against malaria. Herein, the preclinical efficacy and immunogenicity of UB05-09 are tested. Growth inhibition assay was employed to measure the effect of anti-UB05-09 antibodies on P. falciparum growth in vitro. BALB/c mice were immunized with UB05-09 and challenged with the lethal Plasmodium yoelii 17XL infection. ELISA was used to measure antigen-specific antibody production. ELISPOT assays were employed to measure interferon-gamma production ex vivo after stimulation with chimeric UB05-09 and its constituent antigens. Purified immunoglobulins raised in rabbits against UB05-09 significantly inhibited P. falciparum growth in vitro compared to that of its respective constituent antigens. A combination of antibodies to UB05-09 and the apical membrane antigen (AMA1) completely inhibited P. falciparum growth in culture. Immunization of BALB/c mice with recombinant UB05-09 blocked parasitaemia and protected them against lethal P. yoelii 17XL challenge infection. These data suggest that UB05-09 is a malaria vaccine candidate that could be developed further and used in conjunction with AMA1 to create a potent malaria vaccine.

Conformational variability in the D2 loop of Plasmodium Apical Membrane antigen 1.

Apical Membrane Antigen 1 (AMA1) plays a vital role in the invasion of the host erythrocyte by the malaria parasite, Plasmodium. It is thus an important target for vaccine and anti-malaria therapeutic strategies that block the invasion process. AMA1, present on the surface of the parasite, interacts with RON2, a component of the parasite's rhoptry neck (RON) protein complex, which is transferred to the erythrocyte membrane during invasion. The D2 loop of AMA1 plays an essential role in invasion as it partially covers the RON2-binding site and must therefore be displaced for invasion to proceed. Several structural studies have shown that the D2 loop is very mobile, a property that is probably important for the function of AMA1. Here we present three crystal structures of AMA1 from P. falciparum (strains 3D7 and FVO) and P. vivax (strain Sal1), in which the D2 loop could be largely traced in the electron density maps. The D2 loop of PfAMA1-FVO and PvAMA1 (as a complex with a monoclonal antibody Fab) has a conformation previously noted in the P. knowlesi AMA1 structure. The D2 loop of PfAMA1-3D7, however, reveals a novel conformation. We analyse the conformational variability of the D2 loop in these structures, together with those previously reported. Three different conformations can be distinguished, all of which are highly helical and show some similarity in their secondary structure organisation. We discuss the significance of these observations in the light of the flexible nature of the D2 loop and its role in AMA1 function.

Structure of the malaria vaccine candidate antigen CyRPA and its complex with a parasite invasion inhibitory antibody.

Invasion of erythrocytes by Plasmodial merozoites is a composite process involving the interplay of several proteins. Among them, the Plasmodium falciparum Cysteine-Rich Protective Antigen (PfCyRPA) is a crucial component of a ternary complex, including Reticulocyte binding-like Homologous protein 5 (PfRH5) and the RH5-interacting protein (PfRipr), essential for erythrocyte invasion. Here, we present the crystal structures of PfCyRPA and its complex with the antigen-binding fragment of a parasite growth inhibitory antibody. PfCyRPA adopts a 6-bladed ß-propeller structure with similarity to the classic sialidase fold, but it has no sialidase activity and fulfills a purely non-enzymatic function. Characterization of the epitope recognized by protective antibodies may facilitate design of peptidomimetics to focus vaccine responses on protective epitopes. Both in vitro and in vivo anti-PfCyRPA and anti-PfRH5 antibodies showed more potent parasite growth inhibitory activity in combination than on their own, supporting a combined delivery of PfCyRPA and PfRH5 in vaccines.

Effect of linker length and residues on the structure and stability of a fusion protein with malaria vaccine application.

BACKGROUND: Recombinant protein technology has revolutionized the world of biology and medicine. Following this progress, fusion protein technology, as a novel innovation, has opened new horizons for the development of proteins that do not naturally exist. Fusion proteins are generated via genetically fusing two or more genes coding for separate proteins, thus the product is a single protein having functional properties of both proteins. As an indispensable element in fusion protein construction, linkers are used to separate the functional domains in order to improve their expression, folding and stability. METHOD: We computationally fused an antigen and an adjuvant together using different linkers to obtain a two-domain fusion construct which can potentially act as an oral vaccine candidate against malaria. We then predicted the structures computationally to find out the probable folding of each domain in the designed construct. RESULTS: One of the fusion constructs was selected based on the highest value for C-score. Ramchandran Plot analysis represented that most residues were fallen in favorable regions. CONCLUSION: Our in silico analysis showed that (GGGGS)3 linker confers the best structure and stability for our target fusion protein.

In vivo deglycosylation of recombinant proteins in plants by co-expression with bacterial PNGase F.

At present, several eukaryotic expression systems including yeast, insect and mammalian cells and plants are used for the production of recombinant proteins. Proteins with potential N-glycosylation sites are efficiently glycosylated when expressed in these systems. However, the ability of the eukaryotic expression systems to glycosylate may be not desirable for some proteins. If target proteins that do not carry N-linked glycans in the native host contain potential N-linked glycosylation sites, they can be aberrantly glycosylated in the eukaryotic expression systems, thus, potentially impairing biological activity. Recently, we have developed a strategy of enzymatic deglycosylation of proteins in vivo by co-introducing bacterial PNGase F via agroinfiltration followed by transient expression in plants. (1) Here, we summarize our work on this topic and its potential implications.