New interventions are needed to reduce morbidity and mortality associated with malaria, as well as to accelerate elimination and eventual eradication. Interventions that can break the cycle of parasite transmission, and prevent its reintroduction, will be of particular importance in achieving the eradication goal. In this regard, vaccines that interrupt malaria transmission (VIMT) have been highlighted as an important intervention, including transmission-blocking vaccines that prevent human-to-mosquito transmission by targeting the sexual, sporogonic, or mosquito stages of the parasite (SSM-VIMT). While the significant potential of this vaccine approach has been appreciated for decades, the development and licensure pathways for vaccines that target transmission and the incidence of infection, as opposed to prevention of clinical malaria disease, remain ill-defined. This article describes the progress made in critical areas since 2010, highlights key challenges that remain, and outlines important next steps to maximize the potential for SSM-VIMTs to contribute to the broader malaria elimination and eradication objectives.
Transmission-blocking vaccines have the potential to be key contributors to malaria elimination. Such vaccines elicit antibodies that inhibit parasites during their development in Anopheles mosquitoes, thus breaking the cycle of transmission. To date, characterization of humoral responses to Plasmodium falciparum transmission-blocking vaccine candidate Pfs25 has largely been conducted in pre-clinical models. Here, we present molecular analyses of human antibody responses generated in a clinical trial evaluating Pfs25 vaccination. From a collection of monoclonal antibodies with transmission-blocking activity, we identify the most potent transmission-blocking antibody yet described against Pfs25; 2544. The interactions of 2544 and three other antibodies with Pfs25 are analyzed by crystallography to understand structural requirements for elicitation of human transmission-blocking responses. Our analyses provide insights into Pfs25 immunogenicity and epitope potency, and detail an affinity maturation pathway for a potent transmission-blocking antibody in humans. Our findings can be employed to guide the design of improved malaria transmission-blocking vaccines.
Oral administration of anti-CFA/I minor pilin subunit (CfaE) antibodies conferred significant protection against ETEC, providing the first clinical evidence that fimbrial tip adhesins function as protective antigens.
Enterotoxigenic Escherichia coli (ETEC) are the most common cause of bacterial diarrhea in young children in developing countries and in travelers. Efforts to develop an ETEC vaccine have intensified in the past decade, and intestinal colonization factors (CFs) are somatic components of most investigational vaccines. CFA/I and related Class 5 fimbrial CFs feature a major stalk-forming subunit and a minor, antigenically conserved tip adhesin. We hypothesized that the tip adhesin is critical for stimulating antibodies that specifically inhibit ETEC attachment to the small intestine. To address this, we compared the capacity of donor strand complemented CfaE (dscCfaE), a stabilized form of the CFA/I fimbrial tip adhesin, and CFA/I fimbriae to elicit anti-adhesive antibodies in mice, using hemagglutination inhibition (HAI) as proxy for neutralization of intestinal adhesion. When given with genetically attenuated heat-labile enterotoxin LTR192G as adjuvant by intranasal (IN) or orogastric (OG) vaccination, dscCfaE exceeded CFA/I fimbriae in eliciting serum HAI titers and anti-CfaE antibody titers. Based on these findings, we vaccinated Aotus nancymaae nonhuman primates (NHP) with dscCfaE alone or admixed with one of two adjuvants, LTR192G and cholera toxin B-subunit, by IN and OG administration. Only IN vaccination with dscCfaE with either adjuvant elicited substantial serum HAI titers and IgA and IgG anti-adhesin responses, with the latter detectable a year after vaccination. In conclusion, we have shown that dscCfaE elicits robust HAI and anti-adhesin antibody responses in both mice and NHPs when given with adjuvant by IN vaccination, encouraging further evaluation of an ETEC adhesin-based vaccine approach.
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