Malaria has plagued humanity since antiquity. Today, it may sound surprising to recall that right until the late nineteenth century, malaria was believed to be a malady caused by foul odorous air or \u201cmiasmas\u201d emanating from polluted water bodies, swamps or marsh lands. It was the French military surgeon and pathologist, Alphonse Laveran (1880), who discovered a protozoan parasite to be the cause of malaria; he called it Oscillariamalariae,<\/em> which was later renamed as Plasmodium. <\/em>Some years later in 1897, Ronald Rossincriminated mosquito as the vector responsible for transmission of malaria. (Both Laveran and Ross received Nobel Prize for their work). These studies marked the beginning of scientific pursuit and understanding of what turned out to be a very complex protozoan pathogen in terms of its fascinating basic biology and the terrible disease it inflicts on humanity. Ever since, scientists all over the world have been relentlessly working to unravel the molecular mechanisms involved in host-pathogen interaction as well as<\/em> to devise effective strategies for treatment (drug development) and control (vector control) of malaria.<\/span><\/p>\n One of the most successful and impressive scientific advances in the 20th<\/sup> century in control of dreaded infectious diseases like small pox, polio, etc.<\/em>, has been the development of vaccines. No wonder that efforts towards developing a malaria vaccine have been in the forefront of R&D programmes of many leading labs across the globe. However, developing a malaria vaccine presents a host of formidable challenges. But before we get into the charm and challenge of developing a malaria vaccine, let us first revisit our basic knowledge about the life cycle of the malaria parasite. This knowledgewill help us to know the stages in the life cycle of the parasite which may be vulnerable to immune and\/or drug attack, and hence attractive targets for interventional strategies. <\/em><\/span><\/p>\n Typically, three distinct cycles constitute the complete life cycle of malaria parasite (Figure 1), namely, <\/em>Exoeryhtrocytic Cycle<\/em> in the liver of the vertebrate host, <\/em>Erythrocytic Cycle<\/em> in the red blood cells of the vertebrate host, and <\/em>Sporogonic Cycle<\/em> in the invertebrate host\/vector (female <\/em>Anopheles<\/em> mosquito). Malaria infection in a vertebrate host starts with the bite by an infected female Anopheles mosquito, which in the process of taking its blood meal injects thousands of sporozoites, the infective form of malaria parasite, into the skin of the vertebrate host. Eventually sporozoites find their way into the blood stream and get carried away to the liver where they infect hepatocytes, and over a period ranging from days to years depending upon the species of the malaria parasite, each sporozoiteundergoes exponential division to give rise to what is called tissue schizont stage. Each tissue schizont eventually bursts and releases thousandsof motile merozoites into the blood stream, each ready to infect an erythrocyte and initiate asexual erythrocytic cycle of the parasite. This cycle comprises sequential differentiation of an intracellular merozoite into a signet ring stage and trophozoite which undergoes multiple cell divisions to give rise to a schizont containing up to 32 or even more merozoites. Eventually schizonts burst out to release merozoites, each ready to initiate fresh asexual erythrocytic cycle of the parasite. It is this asexual erythrocytic cycle of the parasite which is responsible for all the morbidity and mortality associated with malaria (Figure 1). After a certain number of erythrocytic cycles, some of the parasites decide to differentiate into sexual stages, <\/em>i.e.,<\/em> male and female gametocytes to be taken up by the feeding female <\/em>Anopheles<\/em> mosquito. It is in the mosquito gut that parasite\u2019s male and female gametes are formed, to accomplish the process of fertilization and followed by further development into sporozoites. The sporozoites move into salivary glands of the female <\/em>mosquito, ready to infect fresh victim during the next blood meal of the mosquito (Figure 1).<\/span><\/p>\n As mentioned above, paroxysms, the fever episodes of malaria coincide with the bursting of infected erythrocytes and release of products of multiplication of the parasite in the blood stream. The periodicity and severity of fever is characteristic of different species of malaria parasite. Thus, four species of malaria parasite that can infect humans are as follows:<\/em><\/span><\/p>\n Figure 1. Life Cycle of malaria parasite (<\/u><\/strong><\/em>Source: CDC, Atlanta, Georgia, USA<\/u><\/strong><\/em>)<\/u><\/strong><\/em><\/span><\/p>\n Developing a malaria vaccine involves surmounting multiple tough challenges (Table 1). The fact that more than one species of <\/em>Plasmodium<\/em> causes malaria in humans means that an effective vaccine has to be developed against each of those species; that represents the first challenge in the path to a successful malaria vaccine. Multiple stages of the life cycle add the next level of complexity to the problem. Multiple antigenic proteins present in each of the multiple stages of life cycle, genetic diversity and antigenic variation, redundancy in molecular mechanisms of host cell invasion, <\/em>etc<\/em>., amplify the challenge of developing a malaria vaccine by several folds.<\/em><\/span><\/p>\n Table 1. Multiplicity of Challenge in Developing a Malaria Vaccine<\/strong><\/em><\/span><\/p>\n <\/strong><\/em><\/span><\/td>\n<\/tr>\n 1. <\/em>Multiple species of human malaria parasite<\/em><\/span><\/p>\n 2. <\/em>Multiple genetic strains of each species<\/em><\/span><\/p>\n 3. <\/em>Multiple stages of life cycle, each with its own specific niche<\/em><\/span><\/p>\n 4. Multiple antigens in each stage <\/em>of the parasite<\/span><\/p>\n 5. Multiple variants of each antigen<\/span><\/p>\n 6. <\/em>Multiple \u201cimmunological decoys\u201d: immunodominant but generally non-protective antigenic proteins or peptides<\/em><\/span><\/p>\n 7. <\/em>Lack of a reliable animal model system<\/em><\/span><\/p>\n 8. <\/em>Poor immunogenicity of potentially protective antigenic proteins<\/em><\/span><\/p>\n 9. <\/em>Shortlife-span of protective immune response<\/em><\/span><\/p>\n 10. <\/em>Poor immunological memory following malaria vaccination\/infection<\/em><\/span><\/p>\n <\/em><\/span><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n <\/em><\/span><\/p>\n Efforts for developing malaria vaccine started way back in 1960s, when Ruth Nussenzweig and colleagues, demonstrated that immunization with attenuated sporozoites, delivered through bites of x-irradiated infected mosquitoes, imparted sterile protection to mice challenged with the murine malaria parasite <\/em>P. berghei<\/em> sporozoites (Nussenzweig <\/em>et al<\/em>., 1967, <\/em>Nature, <\/em>216<\/strong><\/em>:160-61). It was soon followed by successful immunization of humans against <\/em>P. falciparum<\/em> (Clyde <\/em>et al<\/em>., 1973, <\/em>Am J Med Sci, <\/em>266<\/strong><\/em>:169-177). These early studies, along with subsequent corroborating studies, in mice, non-human primates and humans established the benchmark of an effective malaria vaccine to be long term sterile immunity against <\/em>Plasmodium<\/em> challenge infection (Hoffman <\/em>et al<\/em>., 2002, <\/em>J Infect Dis<\/em> 185<\/strong>: 1155-64; Hoffman et al., 2015, <\/em>Vaccine<\/em> 33:<\/strong> D13-D23)<\/em><\/span><\/p>\n Ever since those pioneering promising studies, the research for malaria vaccine discovery\/development has gone through cycles of euphoria and frustration, underlining scientific roadblocks like incomplete understanding of the biology of the parasite on the one hand, and nature of the \u201cprotective\u201d immune response required on the other. As a result of application of advanced genomic biology and molecular immunology strategies over a period of more than last thirty years, a large number of molecules have been identified and evaluated as candidate vaccines. A number of pre-erythrocytic stages and asexual blood stages vaccine formulations are being evaluated in clinical trials as indicated in Table 2 and 3, and Figure 2.<\/em><\/span><\/p>\n <\/u><\/strong><\/span><\/p>\n Table 2. List of leading Pre-erythrocytic malaria vaccine candidates against P. falciparum <\/em>malaria<\/u><\/strong><\/span><\/p>\n <\/u><\/span><\/p>\n\n
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