Premium
Vaccines against malaria—still a long way to go
Author(s) -
Matuschewski Kai
Publication year - 2017
Publication title -
the febs journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.981
H-Index - 204
eISSN - 1742-4658
pISSN - 1742-464X
DOI - 10.1111/febs.14107
Subject(s) - malaria , plasmodium (life cycle) , immunity , malaria vaccine , biology , immunology , virology , cerebral malaria , plasmodium falciparum , vaccination , medicine , parasite hosting , immune system , world wide web , computer science
Several species of Plasmodium cause a broad spectrum of human disease that range from nausea and fever to severe anemia, cerebral malaria, and multiorgan failure. In malaria‐endemic countries, continuous exposure to Plasmodium sporozoite inoculations and subsequent blood infections elicit only partial and short‐lived immunity, which gradually develops over many years of parasite exposure and multiple clinical episodes. The ambitious goal of malaria vaccinology over the past 70 years has been to develop an immunization strategy that mounts protection superior to naturally acquired immunity. Herein, three principal concepts in evidence‐based malaria vaccine development are compared. Feasible leads are typically stand‐alone subunit vaccine approaches that block Plasmodium parasite life cycle progression or parasite/host interactions, and they constitute the majority of candidates in preclinical research and early clinical testing. Integrated approaches incorporate malaria antigen(s) into licensed or emerging pediatric vaccine formulations. This strategy can complement the malaria control portfolio even if the antimalarial component is only partially effective and has led to the development of the only candidate vaccine to date, namely RTS,S‐AS01. Experimental whole parasite vaccine approaches have been repeatedly shown to elicit sterile and lasting protection against identical parasite strains, but mass production, proof of broad protection against different parasite strains, and routes of vaccine delivery remain significant translational road blocks. Global access to an effective and affordable malaria vaccine will critically depend on innovative translational research that builds on a better molecular understanding of Plasmodium biology and host immunity.