High efficiency transfection of Plasmodium berghei facilitates novel selection procedures

The use of transfection in the study of the biology of malaria parasites has been limited due to poor transfection efficiencies (frequency of 10(-6) to 10(-9)) and a paucity of selection markers. Here, a new method of transfection, using non-viral Nucleofector technology, is described for the rodent parasite Plasmodium berghei. The transfection efficiency obtained (episomal and targeted integration into the genome) is in the range of 10(-2) to 10(-3). Such high transfection efficiency strongly reduces the time, number of laboratory animals and amount of materials required to generate transfected parasites. Moreover, it allows different experimental strategies for reverse genetics to be developed and we demonstrate direct selection of stably and non-reversibly transformed, fluorescent protein (FP)-expressing parasites using FACS. Since there is no need to use a drug-selectable marker, this method increases the (low) number of selectable markers available for transformation of P. berghei and can in principle be extended to utilise additional FP. Furthermore the FACS-selected, FP-expressing parasites may serve as easily visualized reference lines that may still be genetically manipulated with the existing drug-selectable markers. The combination of enhanced transfection efficiency and a versatile rodent model provides a basis for the further development of novel tools for high throughput genome manipulation.     

Small-scale in vitro culture and purification of Plasmodium berghei for transfection experiment

The standard protocol for genetic modification of the rodent malaria parasite Plasmodium berghei requires infected blood from one or more laboratory mice, followed by large-scale in vitro parasite culture and purification of mature schizonts. Here, protocols are described for small-scale in vitro culture from 20 μL of mouse tail blood and purification of mature P. berghei schizonts sufficient for a single transfection experiment. All procedures are performed in 1.5-mL microcentrifuge tubes. We confirmed that transgenic parasites could be obtained using schizonts prepared by this protocol. This small-scale protocol provides significant advantages, namely reduction of parasite sample, laboratory consumables and mice for transfection experiments.     

Single-dose immunogenicity and protective efficacy of simian adenoviral vectors against Plasmodium berghei

Simian adenoviral vectors (SAd) offer an attractive alternative to standard human adenovirus serotype 5 (AdH5) subunit vaccination, due to pre-existing immunity affecting vaccine performance. We have used a mouse model of liver-stage malaria to test the efficiency of three chimpanzee-origin adenoviral vectors, AdC6, AdC7 and AdC9 containing ME.TRAP as an insert. AdC7 and AdC9 elicited strong immunogenicity ( approximately 20% of CD8(+) T cells in spleen), equivalent to or outperforming AdH5 and inducing sterile protection in 92% (C9), 83% (H5 and C7) and 67% (C6) of the mice, providing the first evidence of single-dose protection to Plasmodium berghei. Protection was afforded by the SAd despite high levels of pre-existing immunity to AdH5. Phenotypic analysis showed that all adenoviral vectors (Ad) elicited CD8(+) T cell responses with an effector memory T cell (T(EM)) phenotype. By contrast, vaccination with poxviral vectors did not confer protection to P. berghei and induced a predominantly CD8(+) central memory T cell (T(CM)) response. Multifunctional CD8(+) T cell responses (co-expressing IFN-gamma, TNF-alpha and IL-2) were also induced by the Ad in higher percentages than the poxviral vectors. Our data suggest that T(EM) cells are important as a first line of defense against fast-replicating pathogens such as murine Plasmodium and demonstrate the potential of replication-defective SAd as future malaria vaccines for humans.     

New selectable markers and single crossover integration for the highly versatile Plasmodium knowlesi transfection system

Plasmodium knowlesi provides a highly versatile transfection system for malaria, since it enables rapid genetic modification of the parasite both in vivo as well as in vitro. However, it is not possible to perform multiple genetic manipulations within one parasite line because of a lack of selectable markers. In an effort to develop additional selectable markers for this parasite, positive and negative selectable markers that have recently been successfully used in Plasmodium falciparum were tested. It was shown that the positive selectable markers human dihydrofolate reductase (hdhfr), blasticidin S deaminase (bsd) and neomycin phosphotransferase II (neo) all conferred drug resistance to P. knowlesi when introduced as episomes. The plasmid containing the hdhfr selectable marker was not only successfully introduced as circular form, but also as linear fragment, demonstrating for the first time single crossover integration in P. knowlesi. Thymidine kinase was tested for its potential as negative selectable marker and it was shown that recombinant P. knowlesi parasites expressing thymidine kinase from episomes were highly sensitive to ganciclovir compared to wild-type P. knowlesi. The availability of new positive selectable markers and a strong candidate for a negative selectable marker for P. knowlesi, in combination with the opportunity to perform targeted single crossover integration in P. knowlesi, significantly increases the flexibility of this transfection system, making it one of the most versatile systems available for Plasmodium.     

Improved Plasmodium berghei lines for conditional mutagenesis

Conditional mutagenesis is a powerful tool for genetic analysis in Plasmodium berghei. It allows the study of proteins that function both during the parasite's pre-erythocytic and erythrocytic development. Currently available parasite lines used for conditional mutagenesis were constructed in the NK65 strain, and express a DNA recombinase under the control of pre-erythrocytic stage-specific promoters. However, the integration of the recombinase in these lines is unstable leading to inconsistent excision of the target gene. We describe improved lines of P. berghei with stably integrated DNA recombinase that allow efficient, stage-specific excision of target genes in the widely used ANKA strain.     

Prevention of experimental cerebral malaria by Flt3 ligand during infection with Plasmodium berghei ANKA

Dendritic cells are the most potent antigen-presenting cells, but their roles in blood-stage malaria infection are not fully understood. We examined the effects of Flt3 ligand, a cytokine that induces dendritic cell production, in vivo on the course of infection with Plasmodium berghei ANKA. Mice treated with Flt3 ligand showed preferential expansion of CD8(+) dendritic cells and granulocytes, as well as lower levels of parasitemia, and were protected from the development of lethal experimental cerebral malaria (ECM). Rag2 knockout mice treated with Flt3 ligand also showed inhibition of parasitemia, suggesting that this protection was due, at least in part, to the stimulation of innate immunity. However, it was unlikely that the inhibition of ECM was due simply to the reduction in the level of parasitemia. In the peripheral T cell compartment, CD8(+) T cell levels were markedly increased in Flt3 ligand-treated mice after infection. These CD8(+) T cells expressed CD11c and upregulated CXCR3, while the expression of CD137, CD25, and granzyme B was reduced. In the brain, the number of sequestered CD8(+) T cells was not significantly different for treated versus untreated mice, while the proportion of CD8(+) T cells that produce gamma interferon (IFN-γ) and granzyme B was significantly reduced in treated mice. In addition, sequestration of parasitized red blood cells (RBCs) in the brain was reduced, suggesting that altered CD8(+) T cell activation and reduced sequestration of parasitized RBCs culminated in inhibition of ECM development. These results suggest that the quantitative and qualitative changes in the dendritic cell compartment are important for the pathogenesis of ECM.     

Pathophysiology of hypoxia in mice infected with Plasmodium berghei

Pathophysiological significance of hypoxia in malarial infection was investigated in mice infected with Plasmodium berghei NK65. Intraperitoneal inoculation of mice with 1×10⁷ parasitized red blood cells resulted in death of the hosts 6–7 days later. Anaemia of infected animals developed on day 4 after inoculation and oxygen affinity of whole blood, measured as P₅₀ act pH, increased simultaneously. This change may be a physiological adaptive response to a reduction in oxygen delivery to the tissues to day 5. However, the blood oxygen supply on day 6 appeared to be deteriorating and this is thought to be an important factor contributing to the death of the host. The value of adenylate energy charge in red cells during malarial infection, however, was comparatively well-maintained. Allopurinol stimulated the multiplication of malaria parasites and seems to have induced collapse in host-parasite balance more rapidly. Decrease in blood pH and in blood oxygen transport may be important factors for the pathogenesis of the allopurinol-treated hosts.     

Presence of contaminating mitochondrial DNA from host reticulocytes in experimental infections of Plasmodium berghei

Superposition of two unrelated processes, namely terminal reticulocyte differentiation and synchronous plasmodial development, takes place in experimental infections of Plasmodium berghei. The first process is shown to be responsible for the appearance of some discrete restriction bands of host origin when DNA is extracted from leucocyte-free blood containing synchronous parasites at early stages of infection. These discrete DNA fragments cross-hybridize with host cell mitochondrial DNA. Purification steps are suggested to reduce this effect, which might be relevant also in the case of other plasmodial species exhibiting preference for reticulocytes as host cell.     

Secreted Antibody Is Required for Immunity to Plasmodium berghei

Infection with Plasmodium berghei is lethal to mice, causing high levels of parasitemia, severe anemia, and death. However, when mice are treated with antimalarial drugs during acute infection, they have enhanced immunity to subsequent infections. With this infection and cure model of immunity, we systematically examined the basis of adaptive immunity to infection using immunodeficient mice. In order to induce adaptive immunity, mice were infected with blood-stage parasites. When the mice developed 2 to 3% parasitemia, they were treated with chloroquine to cure the infection. These convalescent mice were then challenged with homologous blood-stage parasites. Immunized wild-type mice were able to control the level of infection. In contrast, mice lacking mature B cells and T cells were unable to control a challenge infection, indicating the critical role of lymphocytes in immunity to P. berghei. Furthermore, mice lacking secreted antibody were unable to control the level of parasitemia following a challenge infection. Our results indicate that secreted antibody is a requirement for immunity to P. berghei.Each year there are approximately 500 million cases of malaria worldwide, resulting in 2 to 3 million deaths, primarily in children in sub-Saharan Africa (42). Malaria is caused by infection with one of four protozoan Plasmodium species: P. falciparum, P. vivax, P. malariae, and P. ovale. P. falciparum is responsible for the majority of severe disease, which can manifest itself in anemia, cerebral malaria, organ failure, and death. Repeated infection and treatment of individuals in areas of malaria endemicity eventually induce a level of immunity that limits morbidity and results in chronic infection with low levels of parasitemia (41). A fully effective vaccine that reduces parasite burden and severe disease has not been developed.Murine models of malaria have long been used to examine the immune response to Plasmodium parasites and to understand the host factors required for the development of immunity. P. berghei infection in mice is lethal, causing high levels of parasitemia, severe anemia, and body weight loss. However, mice can become resistant to subsequent infections by treatment with antimalarial drugs during acute infection (27). This is known as the infection and cure model, and mice that develop this immunity mimic the human experience of disease in that they are reinfected but experience low-level patent parasitemia and survive. However, it takes years to establish this level of immunity in humans (36), while in mice it is accomplished by only one infection and drug cure, which provides long-lasting protection (12, 13, 48). An understanding of the basis of rodent immunity to blood-stage infection will help to direct future vaccine approaches.The fact that immunity induced by infection and cure is long-lasting suggests that the adaptive immune system is required for immunity. Evidence from previous work indicates a role for B and T cells in immunity. Mice lacking both mature B and T cells (SCID mice) (6), as well as mice deficient in mature B cells (μ-MT mice) (23), were unable to eliminate primary and secondary infection, suggesting that B cells are required for adaptive immunity to Plasmodium species (30, 47). Immunity to P. yoelii, another rodent parasite, can also be induced by infection and cure. In the P. yoelii system, it has been shown that immunity can be passively transferred to naïve recipient mice (17, 21, 34). Hyperimmune serum (from mice infected and challenged multiple times) is most effective; it allowed mice with an active infection to clear blood-stage parasites within 48 h (17). The results from these studies suggest that B cells and antibody are required for immunity, but the requirement for secreted antibody has not been well defined. While all of the studies thus far have relied on mice lacking mature B cells, in this study we were able to examine immunity to P. berghei in a mouse with intact B cells, which express surface immunoglobulin M (IgM) but are unable to secrete antibody (25).Here we use the infection and cure model to examine the requirement for secreted antibody in immunity to P. berghei in the murine host. We establish a model of infection and cure with P. berghei and demonstrate the pivotal requirement for secreted antibody in adaptive immunity to P. berghei.     

Infectivity of Plasmodium berghei sporozoites measured with a DNA probe

A 2.3 kb, 32P-labeled repetitive DNA probe of Plasmodium berghei was used to measure the amount of parasite DNA in the liver of Norway Brown rats and mice infected with sporozoites. Standard hybridization curves were obtained by probing different amounts (100 pg to 1 microgram) of P. berghei DNA immobilized on nitrocellulose filters. Host DNA did not interfere with hybridization specificity and sensitivity. A 100-fold increase in hepatic parasite DNA was detected between 25 h post-infection and the peak of parasite proliferation, detected at 44 h. The amount of parasite DNA increased with the number of injected sporozoites. At 5 h post-infection, a large proportion of parasite DNA was found in the spleen. However, this diminished with time and was negligible in amount at 25 h. A significant number of viable sporozoites were probably cleared in the spleen, since considerably more parasite DNA was found in the livers of splenectomized rats than in sham-operated counterparts. Although older rats develop much lower parasitemias upon inoculation of sporozoites, no significant differences were observed in the amount of parasite DNA in rats, 43 and 152 days old, injected with equal numbers of sporozoites. The higher resistance to malaria displayed by older rats is probably controlled by post-hepatic events. The infectivity of sporozoites for A/J mice was calculated to be about 1/20th that of Norway Brown rats.     

A marker epitope of attenuated Plasmodium berghei

Plasmodium berghei XAT is an irradiation-induced, permanent attenuated derivative from high-virulence P. berghei NK65. Monoclonal antibodies against XAT were developed. By immunofluorescence screening, one monoclonal antibody was identified that was reactive with XAT at the schizont stage but not with NK65 nor with any other stage of intra-erythrocytic development of either parasite. The monoclonal antibody precipitated a 240-kD molecule from metabolically labeled XAT antigens. This molecule was thought to be a marker epitope of the attenuated parasite.     

Molecular karyotyping of the rodent malarias Plasmodium chabaudi, Plasmodium berghei and Plasmodium vinckei

The molecular karyotypes of four isolates of Plasmodium chabaudi, three of the subspecies P. chabaudi adami and one P. chabaudi chabaudi, as well as P. berghei and P. vinckei were studied by means of pulsed field gradient (PFG) gel electrophoresis. Each species appears to have 14 chromosomes, ranging in size from approximately 730 kb to greater than 2000 kb. The three P. chabaudi adami isolates did not appear any more similar to each other than to the P. c. chabaudi isolate. The chromosome locations of genes for a heat shock protein (hsp) 70, ribosomal RNA (rRNA), the precursor to the major merozoite surface proteins, dihydrofolate reductase and P. falciparum antigen 352 as well as four cloned DNA markers and a telomere probe were determined. However, a number of probes representing cloned P. falciparum antigens failed to hybridize to P. chabaudi DNA. Hence genes for malaria antigens appear to be much more divergent than genes for housekeeping functions.     

Transgenic Plasmodium berghei sporozoites expressing beta-galactosidase for quantification of sporozoite transmission

Malaria transmission occurs during a blood-meal of an infected Anopheles mosquito. Visualization and quantification of sporozoites along the journey from the mosquito midgut, where they develop, to the vertebrate liver, their final target organ, is important for understanding many aspects of sporozoite biology. Here we describe the generation of Plasmodium berghei parasites that express the reporter gene lacZ as a stable transgene, under the control of the sporozoite-specific CSP promoter. Transgenic sporozoites expressing beta-galactosidase can be simply visualized and quantified in an enzymatic assay. In addition, these sporozoites can be used to quantify sporozoites deposited in subcutaneous tissue during natural infection.     

The putative gene for the first enzyme of glutathione biosynthesis in Plasmodium berghei and Plasmodium falciparum

The putative gene for gamma-glutamylcysteine synthetase, the rate-limiting enzyme in glutathione biosynthesis, has been characterized both in Plasmodium berghei and Plasmodium falciparum. Protein sequence comparison between these two species reveals large conserved regions sharing more than 80% similarity, separated by less conserved portions. When the comparison is extended to known gamma-glutamylcysteine synthetases from other eukaryotes, a number of high similarity blocks are observed which may help in identifying sequence essential for protein function.     

Immunization efficacy of cryopreserved genetically attenuated Plasmodium berghei sporozoites

Parasitology Research - Malaria is transmitted through the injection of Plasmodium sporozoites into the skin by Anopheles mosquitoes. The parasites first replicate within the liver before infecting...     

Purification and characterization of DNA polymerases from Plasmodium berghei

DNA polymerases from the malaria parasite Plasmodium berghei were purified more than 50-fold. Several distinct enzymatic activities were isolated that could be distinguished by the use of various specific DNA polymerase inhibitors. In particular, subdivision into an aphidicolin-sensitive and an aphidicolin-resistant group was possible. Further analysis allowed a better comparison with host DNA polymerases and indicated that one aphidicolin-sensitive DNA polymerase resembled DNA polymerase alpha displaying processive DNA synthesis and using RNA primers, whereas another aphidicolin-sensitive DNA polymerase was distributive and only used DNA primers. Marked differences from the host enzymes do exist, however, such as insensitivity to BuPdGTP. Another P. berghei DNA polymerase was isolated that showed characteristics of a DNA polymerase beta-like enzyme, but which differed from host DNA polymerase beta in its insensitivity to dideoxynucleotides.     

Localization of organellar proteins in Plasmodium falciparum using a novel set of transfection vectors and a new immunofluorescence fixation method

The apicoplast and mitochondrion of the malaria parasite Plasmodium falciparum are important intracellular organelles and targets of several anti-malarial drugs. In recent years, our group and others have begun to piece together the metabolic pathways of these organelles, with a view to understanding their functions and identifying further anti-malarial targets. This has involved localization of putative organellar proteins using fluorescent reporter proteins such as green fluorescent protein (GFP). A major limitation to such an approach is the difficulties associated with using existing plasmids to genetically modify P. falciparum. In this paper, we present a novel series of P. falciparum transfection vectors based around the Gateway recombinatorial cloning system. Our system makes it considerably easier to construct fluorescent reporter fusion proteins, as well as allowing the use of two selectable markers. Using this approach, we localize proteins involved in isoprenoid biosynthesis and the posttranslational processing of apicoplast-encoded proteins to the apicoplast, and a protein putatively involved in the citric acid cycle to the mitochondrion. To confirm the localization of these proteins, we have developed a new immunofluorescence assay (IFA) protocol using antibodies specific to the apicoplast and mitochondrion. In comparison with published IFA methods, we find that ours maintains considerably better structural preservation, while still allowing sufficient antibody binding as well as preserving reporter protein fluorescence. In summary, we present two important new tools that have enabled us to characterize some of the functions of the apicoplast and mitochondrion, and which will be of use to the wider malaria research community in elucidating the localization of other P. falciparum proteins.