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Despite recent progress in the fight against malaria, it still remains a global health challenge necessitating development of intervention strategies. However, the search for malaria vaccine(s) has so far been very challenging. Multiple targets have been tested and so far only a few show promise with one having been endorsed by the WHO. In this study we explore the development of immunity in a low transmission setting, with very few documented re-infections, in order to understand the kinetics of the development and waning of immunity to current and novel blood-stage vaccine candidate antigens. To do this we performed a high-throughput measurement of natural acquired immunity against P. falciparum antigens utilizing a well-established micro-array platform based on the mammalian protein expression system. This large panel of known and novel recombinant full length ectodomain P. falciparum merozoite vaccine candidates were differently recognized by the immune system. Based on the overal spread of the data, some of these antigens induced the acquisition of high levels (1st tertile) of antibodies, among which included novel antigens such as PF3D7_1025300, PF3D7_1105800, PF3D7_1334400, PF3D7_0911300, PF3D7_1252300, PF3D7_1460600, PF3D7_1453100, PF3D7_0831400 and some induced low levels of antibodies (3rd tertile) while others induced moderate levels (4th tertile). In this longitudinal cohort with low level of malaria endemicity, acquisition of humoral immunity to these full length ectodomains P. falciparum antigens demonstrate different dynamics over-time, whereby it was either not acquired or if it was acquired it was either maintained or lost at different rates. These various identified novel antigens are potentially ideal candidates to be prioritized for further functional and or serological studies.
Despite recent progress in the fight against malaria, it still remains a global health challenge necessitating development of intervention strategies. However, the search for malaria vaccine(s) has so far been very challenging. Multiple targets have been tested and so far only a few show promise with one having been endorsed by the WHO. In this study we explore the development of immunity in a low transmission setting, with very few documented re-infections, in order to understand the kinetics of the development and waning of immunity to current and novel blood-stage vaccine candidate antigens. To do this we performed a high-throughput measurement of natural acquired immunity against P. falciparum antigens utilizing a well-established micro-array platform based on the mammalian protein expression system. This large panel of known and novel recombinant full length ectodomain P. falciparum merozoite vaccine candidates were differently recognized by the immune system. Based on the overal spread of the data, some of these antigens induced the acquisition of high levels (1st tertile) of antibodies, among which included novel antigens such as PF3D7_1025300, PF3D7_1105800, PF3D7_1334400, PF3D7_0911300, PF3D7_1252300, PF3D7_1460600, PF3D7_1453100, PF3D7_0831400 and some induced low levels of antibodies (3rd tertile) while others induced moderate levels (4th tertile). In this longitudinal cohort with low level of malaria endemicity, acquisition of humoral immunity to these full length ectodomains P. falciparum antigens demonstrate different dynamics over-time, whereby it was either not acquired or if it was acquired it was either maintained or lost at different rates. These various identified novel antigens are potentially ideal candidates to be prioritized for further functional and or serological studies.
Despite novel global measures to combat malaria, the disease remains a considerable healthcare burden especially in resource limited settings. It accounts for over 2 million deaths per year, most of which are among young children and pregnant women. Despite intensive research and development, only one candidate vaccine, radiationattenuated sporozoite (RAS, S) has made considerable progress to phase 3 clinical trials, albeit a documented partial efficacy of 46% against clinical malaria. However, it's on the road map of becoming the first licensed malaria vaccine with identified potential for development of deployable malaria vaccine. Success of this candidate forms a vital public health tool designed to eradicate global malaria. Parasite antigenic diversity, poor understanding of antimalarial immunity, and lack of immune correlates of protection constitute among the major hindrances of developing an effective malaria vaccine. Current vaccine models such as RAS, S targets Plasmodium falciparum during the preerythrocytic and erythrocytic stages, while a few other interventions direct their activity by blocking transmission against asexual stages, and/or against pregnancy-associated malaria. Recombinant vaccines have initially been designed from antigens containing one or two strains, which represents a significantly small fraction of the genetic diversity of malaria parasites, eventually making it cumbersome for investigators to establish strain-specific efficacy in clinical trials. This current review, therefore, seeks to provide an overview of major achievements in malaria research; highlighting potential applications, confounders while also showcasing future directions that purpose to enhance discovery of safe and effective anti-malaria vaccines.
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