Ivo Ploemen

Visualisation and quantitative analysis of the rodent malaria liver stage by real time imaging.

The quantitative analysis of Plasmodium development in the liver in laboratory animals in cultured cells is hampered by low parasite infection rates and the complicated methods required to monitor intracellular development. As a consequence, this important phase of the parasites life cycle has been poorly studied compared to blood stages, for example in screening anti-malarial drugs. Here we report the use of a transgenic P. berghei parasite, PbGFP-Luccon, expressing the bioluminescent reporter protein luciferase to visualize and quantify parasite development in liver cells both in culture and in live mice using real-time luminescence imaging. The reporter-parasite based quantification in cultured hepatocytes by real-time imaging or using a microplate reader correlates very well with established quantitative RT-PCR methods. For the first time the liver stage of Plasmodium is visualized in whole bodies of live mice and we were able to discriminate as few as 1–5 infected hepatocytes per liver in mice using 2D-imaging and to identify individual infected hepatocytes by 3D-imaging. The analysis of liver infections by whole body imaging shows a good correlation with quantitative RT-PCR analysis of extracted livers. The luminescence-based analysis of the effects of various drugs on in vitro hepatocyte infection shows that this method can effectively be used for in vitro screening of compounds targeting Plasmodium liver stages. Furthermore, by analysing the effect of primaquine and tafenoquine in vivo we demonstrate the applicability of real time imaging to assess parasite drug sensitivity in the liver. The simplicity and speed of quantitative analysis of liver-stage development by real-time imaging compared to the PCR methodologies, as well as the possibility to analyse liver development in live mice without surgery, opens up new possibilities for research on Plasmodium liver infections and for validating the effect of drugs and vaccines on the liver stage of Plasmodium.

Assessing the adequacy of attenuation of genetically modified malaria parasite vaccine candidates.

The critical first step in the clinical development of a malaria vaccine, based on live-attenuated Plasmodium falciparum sporozoites, is the guarantee of complete arrest in the liver. We report on an approach for assessing adequacy of attenuation of genetically attenuated sporozoites in vivo using the Plasmodium berghei model of malaria and P. falciparum sporozoites cultured in primary human hepatocytes. We show that two genetically attenuated sporozoite vaccine candidates, Δp52+p36 and Δfabb/f, are not adequately attenuated. Sporozoites infection of mice with both P. berghei candidates can result in blood infections. We also provide evidence that P. falciparum sporozoites of the leading vaccine candidate that is similarly attenuated through the deletion of the genes encoding the proteins P52 and P36, can develop into replicating liver stages. Therefore, we propose a minimal set of screening criteria to assess adequacy of sporozoite attenuation necessary before advancing into further clinical development and studies in humans.

Two Plasmodium 6-Cys family-related proteins have distinct and critical roles in liver-stage development

The 10 Plasmodium 6‐Cys proteins have critical roles throughout parasite development and are targets for antimalaria vaccination strategies. We analyzed the conserved 6‐cysteine domain of this family and show that only the last 4 positionally conserved cysteine residues are diagnostic for this domain and identified 4 additional “6‐Cys family‐related” proteins. Two of these, sequestrin and B9, are critical to Plasmodium liver‐stage development. RT‐PCR and immunofluorescence assays show that B9 is translationally repressed in sporozoites and is expressed after hepatocyte invasion where it localizes to the parasite plasma membrane. Mutants lacking B9 expression in the rodent malaria parasites P. berghei and P. yoelii and the human parasite P. falciparum developmentally arrest in hepatocytes. P. berghei mutants arrest in the livers of BALB/c (100%) and C57BL6 mice (>99.9%), and in cultures of Huh7 human‐hepatoma cell line. Similarly, P. falciparum mutants while fully infectious to primary human hepatocytes abort development 3 d after infection. This growth arrest is associated with a compromised parasitophorous vacuole membrane a phenotype similar to, but distinct from, mutants lacking the 6‐Cys sporozoite proteins P52 and P36. Our results show that 6‐Cys proteins have critical but distinct roles in establishment and maintenance of a parasitophorous vacuole and subsequent liver‐stage development—Annoura, T., van Schaijk, B. C. L., Ploemen, I. H. J., Sajid, M., Lin, J.‐W., Vos, M. W., Dinmohamed, A G., Inaoka, D. K., Rijpma, S. R., van Gemert, G.‐J., Chevalley‐Maurel, S., Kiełbasa, S. M., Scheltinga, F., Franke‐Fayard, B., Klop, O. Hermsen, C. C., Kita, K., Gego, A., Franetich, J.‐F., Mazier, D., Hoffman, S. L., Janse, C. J., Sauerwein, R. W., Khan, S. M. Two Plasmodium 6‐Cys family‐related proteins have distinct and critical roles in liver‐stage development. FASEB J. 28, 2158–2170 (2014). www.fasebj.org

Early interferon-gamma response against Plasmodium falciparum correlates with interethnic differences in susceptibility to parasitemia between sympatric Fulani and Dogon in Mali.

INTRODUCTION Interethnic differences in susceptibility to malaria provide a unique opportunity to explore immunological correlates of protection. The Fulani of Sahelian Africa are known for their reduced susceptibility to Plasmodium falciparum, compared with surrounding tribes, yet the immunology underlying this is still poorly understood. METHODS AND RESULTS Here, we show that mononuclear cells from Fulani elicit >10-fold stronger interferon (IFN)-gamma production following a 24-h in vitro coincubation with asexual parasites than cells from sympatric Dogon. This response appears to be specific for P. falciparum among a panel of other human pathogens and is independent of the lower number of regulatory T cell counts present in Fulani. IFN-gamma responses in both tribes were inversely correlated with peripheral parasite density as quantified by nucleic acid sequenced-based amplification, but responses of Fulani remained significantly stronger than those of Dogon after adjustment for concurrent parasitemia, suggesting that hard-wired immunological differences underlie the observed protection. CONCLUSIONS These results underscore the value of early IFN-gamma responses to P. falciparum as a correlate of anti-parasite immunity, not only in this setting but also in the wider context of malaria, and support the development of malaria vaccines aimed at inducing such responses.

Memory-like IFN-γ response by NK cells following malaria infection reveals the crucial role of T cells in NK cell activation by P. falciparum.

NK cells are rapid IFN‐γ responders to Plasmodium falciparum‐infected erythrocytes (PfRBC) in vitro and are involved in controlling early parasitaemia in murine models, yet little is known about their contribution to immune responses following malaria infection in humans. Here, we studied the dynamics of and requirements for in vitro NK responses to PfRBC in malaria‐naïve volunteers undergoing a single experimental malaria infection under highly controlled circumstances, and in naturally exposed individuals. NK‐specific IFN‐γ responses to PfRBC following exposure resembled an immunological recall pattern and were tightly correlated with T‐cell responses. However, although PBMC depleted of CD56+ cells retained 20–55% of their total IFN‐γ response to PfRBC, depletion of CD3+ cells completely abrogated the ability of remaining PBMC, including NK cells, to produce IFN‐γ. Although NK responses to PfRBC were partially dependent on endogenous IL‐2 signaling and could be augmented by exogenous IL‐2 in whole PBMC populations, this factor alone was insufficient to rescue NK responses in the absence of T cells. Thus, NK cells make a significant contribution to total IFN‐γ production in response to PfRBC as a consequence of their dependency on (memory) T‐cell help, with likely positive implications for malaria vaccine development.

A genetically attenuated malaria vaccine candidate based on P. falciparum b9/slarp gene-deficient sporozoites

A highly efficacious pre-erythrocytic stage vaccine would be an important tool for the control and elimination of malaria but is currently unavailable. High-level protection in humans can be achieved by experimental immunization with Plasmodium falciparum sporozoites attenuated by radiation or under anti-malarial drug coverage. Immunization with genetically attenuated parasites (GAP) would be an attractive alternative approach. In this study, we present data on safety and protective efficacy using sporozoites with deletions of two genes, that is the newly identified b9 and slarp, which govern independent and critical processes for successful liver-stage development. In the rodent malaria model, PbΔb9ΔslarpGAP was completely attenuated showing no breakthrough infections while efficiently inducing high-level protection. The human PfΔb9ΔslarpGAP generated without drug resistance markers were infective to human hepatocytes in vitro and to humanized mice engrafted with human hepatocytes in vivo but completely aborted development after infection. These findings support the clinical development of a PfΔb9ΔslarpSPZ vaccine. DOI: http://dx.doi.org/10.7554/eLife.03582.001

Combined DNA extraction and antibody elution from filter papers for the assessment of malaria transmission intensity in epidemiological studies.

BackgroundInforming and evaluating malaria control efforts relies on knowledge of local transmission dynamics. Serological and molecular tools have demonstrated great sensitivity to quantify transmission intensity in low endemic settings where the sensitivity of traditional methods is limited. Filter paper blood spots are commonly used a source of both DNA and antibodies. To enhance the operational practicability of malaria surveys, a method is presented for combined DNA extraction and antibody elution.MethodsFilter paper blood spots were collected as part of a large cross-sectional survey in the Kenyan highlands. DNA was extracted using a saponin/chelex method. The eluate of the first wash during the DNA extraction process was used for antibody detection and compared with previously validated antibody elution procedures. Antibody elution efficiency was assessed by total IgG ELISA for malaria antigens apical membrane antigen-1 (AMA-1) and merozoite-surface protein-1 (MSP-142). The sensitivity of nested 18S rRNA and cytochrome b PCR assays and the impact of doubling filter paper material for PCR sensitivity were determined. The distribution of cell material and antibodies throughout filter paper blood spots were examined using luminescent and fluorescent reporter assays.ResultsAntibody levels measured after the combined antibody/DNA extraction technique were strongly correlated to those measured after standard antibody elution (p < 0.0001). Antibody levels for both AMA-1 and MSP-142 were generally slightly lower (11.3-21.4%) but age-seroprevalence patterns were indistinguishable. The proportion of parasite positive samples ranged from 12.9% to 19.2% in the different PCR assays. Despite strong agreement between outcomes of different PCR assays, none of the assays detected all parasite-positive individuals. For all assays doubling filter paper material for DNA extraction increased sensitivity. The concentration of cell and antibody material was not homogenously distributed throughout blood spots.ConclusionCombined DNA extraction and antibody elution is an operationally attractive approach for high throughput assessment of cumulative malaria exposure and current infection prevalence in endemic settings. Estimates of antibody prevalence are unaffected by the combined extraction and elution procedure. The choice of target gene and the amount and source of filter paper material for DNA extraction can have a marked impact on PCR sensitivity.

Reduced Plasmodium berghei sporozoite liver load associates with low protective efficacy after intradermal immunization

Studies in animal models suggest that protection against malaria induced by intradermal (ID) administration of sporozoites is less effective compared to intravenous injection (IV). We investigated in a murine model the protective efficacy and immune responses after ID or IV immunization of sporozoites. Mice were immunized via either IV or ID route with Plasmodium berghei sporozoites in combination with chloroquine treatment (CPS) (allowing full liver stage development) or by γ‐radiation‐attenuated sporozoites (RAS) (early liver stage arrest). While IV immunization with both RAS and CPS generated 90–100% protection, ID immunization resulted in reduced levels of protection with either immunization strategy in both Balb/cByJ (50%) and C57BL/6j mice (7–13%). Lower protection by ID routing associated with a 30‐fold lower parasite liver load [P < 0.001 (χ2 = 49.08, d.f. = 1)] assessed by real‐time in vivo imaging of bioluminescent P. berghei parasites. Unlike IV, ID immunization did not result in expansion of CD8+ T cells with effector memory phenotype and showed lower IFNγ responses irrespective of the immunization regime. In conclusion, protection against sporozoite infection is likely dependent on parasite liver infection and subsequently generated cellular immune responses.

Plasmodium liver load following parenteral sporozoite administration in rodents

One of the bottlenecks in the development of a whole sporozoite malaria vaccine is the route and method of sporozoite administration. Immunization and challenge of human volunteers by mosquito bites is effective, but cannot be used as a vaccine. Intravenous immunization with sporozoites is effective in rodents and non-human primates, and being studied in humans, but is not yet used for licensed vaccines for infectious diseases. Intradermal and subcutaneous immunization regimens show a strong decrease in protective efficacy, which in rodents, is associated with a decreased degree of parasite liver infection during immunization. The objective of this study was to explore alternative routes of sporozoite administration to increase efficiency of liver infection. Using in vivo imaging, we found that IM injection of sporozoites resulted in a greater parasite liver load compared to ID and SC injection. The use of small inoculation volumes and multiple injections further increased the subsequent liver load. These observations were corroborated in a Plasmodium yoelii model using cryopreserved sporozoites administered ID. Our findings provide a rationale for the design of clinical trials to optimize needle and syringe administration of Plasmodium falciparum sporozoites.

Evaluation of immunity against malaria using luciferase-expressing Plasmodium berghei parasites

BackgroundMeasurement of liver stage development is of key interest in malaria biology and vaccine studies. Parasite development in liver cells can be visualized in real-time, both in culture and in live mice, using a transgenic Plasmodium berghei parasite, Pb GFP-Luccon, expressing the bioluminescent reporter luciferase. This study explores the benefit of using these parasites for the evaluation of immunity against malaria, compared to qRT-PCR techniques in vivo and in vitro.MethodsMice were immunized with either radiation attenuated sporozoites (RAS) or wildtype sporozoites under chloroquine prophylaxis (CPS) and challenged with Pb GFP-Luccon. The in vitro transgenic sporozoites neutralization assay (TSNA) was adapted by replacing Pb CS(Pf) parasites for Pb GFP-Luccon parasites.ResultsApplication of Pb GFP-Luccon transgenic parasites provides live quantitative visual information about the relation between parasite liver load and protection. Moreover, fast and reproducible results are obtained by using these parasites in the transgenic sporozoites neutralization assay, measuring functional antibody-mediated immune responses.ConclusionsPb GFP-Luccon parasites are a straightforward and valuable tool for comprehension of the biological and immunological principles underlying protection against malaria.