The importance of human FcgammaRI in mediating protection to malaria

The success of passive immunization suggests that antibody-based therapies will be effective at controlling malaria. We describe the development of fully human antibodies specific for Plasmodium falciparum by antibody repertoire cloning from phage display libraries generated from immune Gambian adults. Although these novel reagents bind with strong affinity to malaria parasites, it remains unclear if in vitro assays are predictive of functional immunity in humans, due to the lack of suitable animal models permissive for P. falciparum. A potentially useful solution described herein allows the antimalarial efficacy of human antibodies to be determined using rodent malaria parasites transgenic for P. falciparum antigens in mice also transgenic for human Fc-receptors. These human IgG1s cured animals of an otherwise lethal malaria infection, and protection was crucially dependent on human FcgammaRI. This important finding documents the capacity of FcgammaRI to mediate potent antimalaria immunity and supports the development of FcgammaRI-directed therapy for human malaria.     

Gene disruption of Plasmodium falciparum p52 results in attenuation of malaria liver stage development in cultured primary human hepatocytes

Difficulties with inducing sterile and long lasting protective immunity against malaria with subunit vaccines has renewed interest in vaccinations with attenuated Plasmodium parasites. Immunizations with sporozoites that are attenuated by radiation (RAS) can induce strong protective immunity both in humans and rodent models of malaria. Recently, in rodent parasites it has been shown that through the deletion of a single gene, sporozoites can also become attenuated in liver stage development and, importantly, immunization with these sporozoites results in immune responses identical to RAS. The promise of vaccination using these genetically attenuated sporozoites (GAS) depends on translating the results in rodent malaria models to human malaria. In this study, we perform the first essential step in this transition by disrupting, p52, in P. falciparum an ortholog of the rodent parasite gene, p36p, which we had previously shown can confer long lasting protective immunity in mice. These P. falciparum P52 deficient sporozoites demonstrate gliding motility, cell traversal and an invasion rate into primary human hepatocytes in vitro that is comparable to wild type sporozoites. However, inside the host hepatocyte development is arrested very soon after invasion. This study reveals, for the first time, that disrupting the equivalent gene in both P. falciparum and rodent malaria Plasmodium species generates parasites that become similarly arrested during liver stage development and these results pave the way for further development of GAS for human use.     

Short odds for malaria vaccines

The immunology of falciparum malaria, the lethal type of human malaria, has been transformed by two developments. First, a culture system for the asexual blood stages of Plasmodium falciparum.¹ Secondly, the cloning and expression of genes coding for a large number of the protein antigens of this malaria parasite over the past two years. Data on proteins, protein antigens and epitopes of P. falciparum supplied by gene cloning techniques have been supplemented by monoclonal antibody approaches, peptide synthesis, and high-resolution immunochemistry.     

Transgenic parasites: improving our understanding of innate immunity to malaria

Clinical immunity to Plasmodium falciparum malaria takes years to develop and is never complete. One explanation for these observations is that antigenic variation enables malaria parasites to evade humoral immunity; another is that P. falciparum induces immune dysregulation, which inhibits the development of protective cellular immunity. Research described by D'Ombrain et al. in this Cell Host & Microbe issue probes how the parasite's main virulence factor PfEMP-1 might significantly alter human innate immune responses.     

Plasmodium falciparum: production of human antibodies specific for the MSP-3 protein in the Hu-SPL-SCID mouse

Human immunity against Plasmodium falciparum malaria is mediated by IgG antibodies. One of the major targets of protective antibodies is the MSP-3 protein. Anti-MSP-3 human monoclonal antibodies could therefore be valuable for passive immunotherapy, particularly of drug resistant malaria. Human monoclonal antibodies were previously produced in the Hu-SPL-SCID model reconstituted with human splenocytes, immunized by highly immunogenic neo-antigen or a recall antigen. We report here that this model can also be successfully employed to induce human antibody-secreting cells specific of low immunogenicity neo-antigens, such as MSP-3. These cells represent a new and valuable source of human monoclonal anti-malaria antibodies.     

Host age as a determinant of naturally acquired immunity to Plasmodium falciparum

The usual course of infection by Plasmodium falciparum among adults who lack a history of exposure to endemic malaria is fulminant. The infection in adults living with hyper- to holoendemic malaria is chronic and benign. Naturally acquired immunity to falciparum malaria is the basis of this difference. Confusion surrounds an essential question regarding this process: What is its rate of onset? Opinions vary because of disagreement over the relationships between exposure to infection, antigenic polymorphism and naturally acquired immunity. In this review, Kevin Baird discusses these relationships against a backdrop of host age as a determinant of naturally acquired immunity to falciparum malaria.     

HIV and malaria: a lesson in immunology?

HIV is now common in many areas of Africa that are also highly endemic for malaria. In this article, Geoff Butcher summarizes the available data on the possible interaction o f HIV and malaria, and shows that the course of falciparum malaria is virtually unaffected by the presence of HIV. This raises significant questions for our understanding of immunity to the asexual blood stages of human malaria and the use of animal models in malaria research.     

The Dynamics of Naturally Acquired Immunity to Plasmodium falciparum Infection

Severe malaria occurs predominantly in young children and immunity to clinical disease is associated with cumulative exposure in holoendemic settings. The relative contribution of immunity against various stages of the parasite life cycle that results in controlling infection and limiting disease is not well understood. Here we analyse the dynamics of Plasmodium falciparum malaria infection after treatment in a cohort of 197 healthy study participants of different ages in order to model naturally acquired immunity. We find that both delayed time-to-infection and reductions in asymptomatic parasitaemias in older age groups can be explained by immunity that reduces the growth of blood stage as opposed to liver stage parasites. We found that this mechanism would require at least two components – a rapidly acting strain-specific component, as well as a slowly acquired cross-reactive or general immunity to all strains. Analysis and modelling of malaria infection dynamics and naturally acquired immunity with age provides important insights into what mechanisms of immune control may be harnessed by malaria vaccine strategists.     

Atypical IgG subclass antibody responses to Plasmodium falciparum asexual stage antigens

The ability of Plasmodium falciparum to induce long-term immunity in the absence of continual restimulation has often been questioned. Recently it has been shown that, while a high proportion of individuals living in areas of high malaria endemicity have antibodies to merozoite surface antigen 2 (MSA2; MSP2) of P. falciparum, these antibodies are primarily of the IgG3 subclass. In this article, Antonio Ferrante and Christine Rzepczyk discuss how such atypical antibody responses may in part explain why immunity to malaria has been widely perceived to be short-lived.     

Longevity and composition of cellular immune responses following experimental Plasmodium falciparum malaria infection in humans

Cellular responses to Plasmodium falciparum parasites, in particular interferon-gamma (IFNγ) production, play an important role in anti-malarial immunity. However, clinical immunity to malaria develops slowly amongst naturally exposed populations, the dynamics of cellular responses in relation to exposure are difficult to study and data about the persistence of such responses are controversial. Here we assess the longevity and composition of cellular immune responses following experimental malaria infection in human volunteers. We conducted a longitudinal study of cellular immunological responses to sporozoites (PfSpz) and asexual blood-stage (PfRBC) malaria parasites in na?ve human volunteers undergoing single (n?=?5) or multiple (n?=?10) experimental P. falciparum infections under highly controlled conditions. IFNγ and interleukin-2 (IL-2) responses following in vitro re-stimulation were measured by flow-cytometry prior to, during and more than one year post infection. We show that cellular responses to both PfSpz and PfRBC are induced and remain almost undiminished up to 14 months after even a single malaria episode. Remarkably, not only 'adaptive' but also 'innate' lymphocyte subsets contribute to the increased IFNγ response, including αβT cells, γδT cells and NK cells. Furthermore, results from depletion and autologous recombination experiments of lymphocyte subsets suggest that immunological memory for PfRBC is carried within both the αβT cells and γδT compartments. Indeed, the majority of cytokine producing T lymphocytes express an CD45RO(+) CD62L(-) effector memory (EM) phenotype both early and late post infection. Finally, we demonstrate that malaria infection induces and maintains polyfunctional (IFNγ(+)IL-2(+)) EM responses against both PfRBC and PfSpz, previously found to be associated with protection. These data demonstrate that cellular responses can be readily induced and are long-lived following infection with P. falciparum, with a persisting contribution by not only adaptive but also (semi-)innate lymphocyte subsets. The implications hereof are positive for malaria vaccine development, but focus attention on those factors potentially inhibiting such responses in the field.     

Thioredoxin reductase and glutathione synthesis in Plasmodium falciparum

The malaria parasite Plasmodium falciparum is still a major threat to human health in the non-industrialised world mainly due to the increasing incidence of drug resistance. Therefore, there is an urgent need to identify and validate new potential drug targets in the parasite's metabolism that are suitable for the design of new anti-malarial drugs. It is known that infection with P. falciparum leads to increased oxidative stress in red blood cells, implying that the parasite requires efficient antioxidant and redox systems to prevent damage caused by reactive oxygen species. In recent years, it has been shown that P. falciparum possess functional thioredoxin and glutathione systems. Using genetic and chemical tools, it was demonstrated that thioredoxin reductase, the first step of the thioredoxin redox cycle, and gamma-glutamylcysteine synthetase (gamma-GCS), the rate-limiting step of glutathione synthesis, are essential for parasite survival. Indeed, the mRNA levels of gamma-GCS are elevated in parasites that are oxidatively stressed, indicating that glutathione plays an important antioxidant role in P. falciparum. In addition to this antioxidant function, glutathione is important for detoxification processes and is possibly involved in the development of resistance against drugs such as chloroquine.     

Pregnancy-associated malaria: parasite binding, natural immunity and vaccine development

Humans living in areas of high malaria transmission gradually acquire, during the early years of life, protective clinical immunity to Plasmodium falciparum, limiting serious complications of malaria to young children. However, pregnant women become more susceptible to severe P. falciparum infections during their first pregnancy. Pregnancy associated malaria is coupled with massive accumulation of parasitised erythrocytes and monocytes in the placental intervillous blood spaces, contributing to disease and death in pregnant women and developing infants. Indirect evidence suggests that prevention may be possible by vaccinating women of childbearing age before their first pregnancy. This review aims to introduce the reader to the implications of malaria infection during pregnancy and to analyse recent findings towards the identification and characterisation of parasite encoded erythrocyte surface proteins expressed in malaria-infected pregnant women that are likely targets of protective immunity and have potential for vaccine development.     

Keeping it simple: an easy method for manipulating the expression levels of malaria proteins

The ability to genetically manipulate malaria parasites in recent times has contributed considerably to our understanding of the biology of this deadly pathogen. Epp et al. have now expanded the repertoire of molecular tools available for the transgenesis system for the human malaria parasite Plasmodium falciparum by developing a simple methodology to regulate malaria gene expression. In this article, we comment on this technique and discuss its potential applications in the study of the biology of malaria parasites.     

Immune regulation of protection and pathogenesis in Plasmodium falciparum malaria

The immune mechanisms whereby malaria parasites are eliminated by the human host or how they may avoid the immune response are poorly understood. Individuals living in malaria-endemic areas gradually acquire immunity. It is well established that this immunity involves both cell-mediated and humoral mechanisms and that T cells are the major regulators in both these events. The existence of functionally distinct P. falciparum-specific CD4+ T-cell subsets in humans has been shown in several studies. However, in contrast to what is the case in murine models there is no definitive link between the activation of various T cells and the course of human P. falciparum blood-stage infection. In the present paper we will review recent findings which illustrate how the balance between functionally different T-cell subsets affects the development of malaria immunity but also may contribute to its pathogenicity. An example of the latter is the deposition of IgE-containing immune complexes in small vessels, probably leading to local overproduction of tumor-necrosis factor (TNF), a pathogenic factor in malaria.     

Evidence that the erythrocyte invasion ligand PfRh2 is a target of protective immunity against Plasmodium falciparum malaria

Abs targeting blood-stage Ags of Plasmodium falciparum are important in acquired immunity to malaria, but major targets remain unclear. The P. falciparum reticulocyte-binding homologs (PfRh) are key ligands used by merozoites during invasion of erythrocytes. PfRh2a and PfRh2b are functionally important members of this family and may be targets of protective immunity, but their potential role in human immunity has not been examined. We expressed eight recombinant proteins covering the entire PfRh2 common region, as well as PfRh2a- and PfRh2b-specific regions. Abs were measured among a cohort of 206 Papua New Guinean children who were followed prospectively for 6 mo for reinfection and malaria. At baseline, Abs were associated with increasing age and active infection. High levels of IgG to all PfRh2 protein constructs were strongly associated with protection from symptomatic malaria and high-density parasitemia. The predominant IgG subclasses were IgG1 and IgG3, with little IgG2 and IgG4 detected. To further understand the significance of PfRh2 as an immune target, we analyzed PfRh2 sequences and found that polymorphisms are concentrated in an N-terminal region of the protein and seem to be under diversifying selection, suggesting immune pressure. Cluster analysis arranged the sequences into two main groups, suggesting that many of the haplotypes identified may be antigenically similar. These findings provide evidence suggesting that PfRh2 is an important target of protective immunity in humans and that Abs act by controlling blood-stage parasitemia and support its potential for vaccine development.     

Naturally acquired immune responses against Plasmodium falciparum sporozoites and liver infection

Malaria is a vector-borne infectious disease caused by infection with eukaryotic pathogens termed Plasmodium. Epidemiological hallmarks of Plasmodium falciparum malaria are continuous re-infections, over which time the human host may experience several clinical malaria episodes, slow acquisition of partial protection against infection, and its partial decay upon migration away from endemic regions. To overcome the exposure-dependence of naturally acquired immunity and rapidly elicit robust long-term protection are ultimate goals of malaria vaccine development. However, cellular and molecular correlates of naturally acquired immunity against either parasite infection or malarial disease remain elusive. Sero-epidemiological studies consistently suggest that acquired immunity is primarily directed against the asexual blood stages. Here, we review available data on the relationship between immune responses against the Anopheles mosquito-transmitted sporozoite and exo-erythrocytic liver stages and the incidence of malaria. We discuss current limitations and research opportunities, including the identification of additional sporozoite antigens and the use of systematic immune profiling and functional studies in longitudinal cohorts to look for pre-erythrocytic signatures of naturally acquired immunity.     

Interethnic differences in antigen-presenting cell activation and TLR responses in Malian children during Plasmodium falciparum malaria

The Fulani ethnic group from West Africa is relatively better protected against Plasmodium falciparum malaria as compared to other sympatric ethnic groups, such as the Dogon. However, the mechanisms behind this lower susceptibility to malaria are largely unknown, particularly those concerning innate immunity. Antigen-presenting cells (APCs), and in particular dendritic cells (DCs) are important components of the innate and adaptive immune systems. Therefore, in this study we investigated whether APCs obtained from Fulani and Dogon children exhibited differences in terms of activation status and toll-like receptor (TLR) responses during malaria infection. Lower frequency and increased activation was observed in circulating plasmacytoid DCs and BDCA-3+ myeloid DCs of infected Fulani as compared to their uninfected counterparts. Conversely, a higher frequency and reduced activation was observed in the same DC subsets obtained from peripheral blood of P. falciparum-infected Dogon children as compared to their uninfected peers. Moreover, infected individuals of both ethnic groups exhibited higher percentages of both classical and inflammatory monocytes that were less activated as compared to their non-infected counterparts. In line with APC impairment during malaria infection, TLR4, TLR7 and TLR9 responses were strongly inhibited by P. falciparum infection in Dogon children, while no such TLR inhibition was observed in the Fulani children. Strikingly, the TLR-induced IFN-γ release was completely abolished in the Dogon undergoing infection while no difference was seen within infected and non-infected Fulani. Thus, P. falciparum infection is associated with altered activation status of important APC subsets and strongly inhibited TLR responses in peripheral blood of Dogon children. In contrast, P. falciparum induces DC activation and does not affect the innate response to specific TLR ligands in Fulani children. These findings suggest that DCs and TLR signalling may be of importance for the protective immunity against malaria observed in the Fulani.