Analysis of DNA from various species and strains of malaria parasites by restriction endonuclease fingerprinting

1. DNA from various rodent Plasmodium species and strains and from P. falciparum, the human parasite, were analysed by agarose gel electrophoresis following digestion with restriction endonucleases EcoRI, Hind III and Bam Hl. Complex patterns of ethidium-stained bands were obtained, which showed similarity but reproducible differences among the various parasite species (P. chabaudi, P. yoelii, P. berghei and P. falciparum). 2. No differences could be discerned among two cloned strains of P. yoelii (33X, and YM) and among pyrimethamine-resistant (pyrimethamine + chloroquine)-resistant and the drug-sensitive P. chabaudi clone from which the resistant clones were derived. 3. From the known complexity of Plasmodium DNA it could be concluded that the visible bands were derived from repetitive DNA fractions.     

Rodent Plasmodium: population dynamics of early sporogony within Anopheles stephensi mosquitoes

Early sporogony of Plasmodium parasites involves 2 major developmental transitions within the insect vector, i.e., gametocyte-to-ookinete and ookinete-to-oocyst. This study compared the population dynamics of early sporogony among murine rodent Plasmodium (Plasmodium berghei, Plasmodium chabaudi, Plasmodium vinckei, and Plasmodium yoelii) developing within Anopheles stephensi mosquitoes. Estimates of absolute densities were determined for gametocytes, ookinetes, and oocysts for 108 experimental infections. Total losses throughout early sporogony were greatest in P. vinckei (ca. 250,000-fold loss), followed by P. yoelii (ca. 70,000-fold loss), P. berghei (ca. 45,000-fold loss), and P. chabaudi (ca. 15,000-fold loss). The gametocyte-to-ookinete transition represented the most severe population bottleneck. Numerical losses during this transition (ca. 3,000- to 30,000-fold, depending on species) were orders of magnitude greater than losses incurred during the ookinete-to-oocyst transition (3- to 14-fold). There were no significant correlations between gametocyte and ookinete densities. Significant correlations between ookinete and oocyst densities existed for P. berghei, P. chabaudi, and P. yoelii (but not for P. vinckei), and were best described by nonlinear functions (P. berghei = sigmoid, P. chabaudi = hyperbolic, P. yoelii = sigmoid), indicating that conversion of ookinetes to oocysts in these species is density dependent. The upper theoretical limit for oocyst density on the mosquito midgut for P. chabaudi and P. yoelii (ca. 300 oocysts per midgut) was higher than for P. berghei (ca. 30 oocysts per midgut). This study provides basic information about population processes that occur during the early sporogonic development of some common laboratory model systems of malaria.     

Manifestation of cerebral malaria-like symptoms in the WM/Ms rat infected with Plasmodium berghei strain NK65

Conditions required for the induction of cerebral malaria (CM)-like symptoms were investigated using 12 strains of rats and 5 murine malaria strains. Among various combinations, only inbred WM/Ms rats infected with P. berghei (NK65) developed neuropathological complications that closely resembled human CM cases. When young WM/Ms rats were infected with the parasites, neurologic signs were induced followed by death in 5-10 days with almost 100% incidence, whereas aged hosts revealed strong resistance. Histologically, edematous changes, occlusion of vessels, and petechial hemorrhages were found in the brain. There was an optimum dose of parasites to induce the manifestations, and a low incidence was obtained by increased or decreased inoculum size. No correlation was found between the level of parasitemia and incidence of the disease. The other 11 rat strains inoculated with this parasite showed high levels of parasitemia, but most of their infections were self-limiting or malarial death occurred without CM-like signs. Inoculation into WM/Ms rats with other murine malaria parasites, including P. chabaudi, P. vinckei, P. yoelii (17X), and P. yoelii (nigeriensis) failed to induce CM-like manifestations irrespective of the inoculation size and the degree of parasitemia. These results indicated that P. berghei (NK65)-infected WM/Ms rats represent an experimental model for CM and certain appropriate conditions are needed for its development in both parasite and host sides.     

Parasitic pattern of rodent Plasmodium in blood from mouse tail and from Anopheles blood meal

During the course of the infection of mice by rodent malaria parasites (P. yoelii yoelii, P. vinckei petteri, and P. chabaudi chabaudi) the parasitic pattern in the blood smears differed according to the site of sampling: mosquito blood meal (usually actively sucked from capillaries) or mouse tail (issued from larger vessels). There were fewer old trophozoites and mature schizonts, and more immature schizonts, in the mosquito blood meal than in the tail blood of mice. It is suggested that the erythrocyte containing a schizont becomes less rigid when merozoites formation begins. The greater abundance in the mosquito blood meal of the gametocytes infective stage (0-I for P. yoelii, II for P. vinckei), previously shown, could be due to a particular flexibility of this stage, a character progressively selected.     

Studies on enzyme variation in the murine malaria parasites Plasmodium berghei, P. yoelii, P. vinckei and P. chabaudi by starch gel electrophoresis.

Electrophoretic variation of the enzymes glucose phosphate isomerase, 6-phosphogluconate dehydrogenase, lactate dehydrogenase and glutamate dehydrogenase (NADP-dependent) has been studied in the African murine malaria parasites Plasmodium berghei, P. yoelii, P. vinckei and P. chabaudi and their subspecies. Horizontal starch gel electrophoresis was used throughout. The number of isolates examined in each subspecies varied from 1 (P. y. nigeriensis) to 24 (P. c. chabaudi). Extensive enzyme variation was found among isolates of most of the subspecies from which more than two such isolates were available for study. It is clear that the phenomenon of enzyme polymorphism is of common occurrence among malaria parasites. With the exception of P. berghei and P. yoelii, of which all isolates share an identical electrophoretic form of lactate dehydrogenase, no enzyme forms are shared between any of the 4 species of murine plasmodia. By contrast, within each species common enzyme forms are shared among each of the subspecies. The subspecies are nevertheless, distinguished from each other by the electrophoretic forms of at least one enzyme. The distribution and reassortment of enzyme variation among isolates of a single subspecies is in accordance with the concept of malaria parasites as sexually reproducing organisms. The study of variation among parasites present in individual wild-caught rodent hosts demonstrates that natural malarial infections usually comprise genetically heterogeneous populations of parasites. Nevertheless, the number of genetically distinct types of parasite of any one species present in a single infected host appears to be small. Generally not more than 2 or 3 clones of parasite of distinct genetic constitution are present in a single infected animal.     

Systemic tumor necrosis factor generated during lethal Plasmodium infections impairs dendritic cell function

Dendritic cells (DCs) initiate innate and adaptive immune responses including those against malaria. Although several studies have shown that DC function is normal during malaria, other studies have shown compromised function. To establish why these studies had different findings, we examined DCs from mice infected with two lethal species of parasite, Plasmodium berghei or P. vinckei, and compared them to DCs from nonlethal P. yoelii 17XNL or P. chabaudi infections. These studies found that DCs from only the lethal infections became uniformly mature 7 days after infection and were functionally impaired as they were unable to endocytose latex particles, secrete IL-12, or present OVA to transgenic OTII T cells. These changes coincided with a peak in levels of systemic TNF-alpha. Because TNF-alpha is known to mature DCs, we used TNF-KO mice to determine the role of this cytokine in the loss of DC function. In the TNF-KO mice, phenotype, Ag presentation, and IL-12 secretion by DCs were restored to normal following both lethal infections. This study shows that the systemic production of TNF-alpha contributes to poor DC function during lethal infections. These studies may explain, at least in part, immunosuppression that is associated with malaria.     

Comparative histopathology of mice infected with the 17XL and 17XNL strains of Plasmodium yoelii

Plasmodium yoelii 17XL was used to investigate the mechanism of Plasmodium falciparum-caused cerebral malaria, although its histological effect on other mouse organs is still unclear. Here, histological examination was performed on mice infected with P. yoelii 17XL; the effect of P. yoelii 17XL infection on anemia and body weight loss, as well as its lesions in the brain, liver, kidney, lung, and spleen, also was investigated. Plasmodium yoelii 17XL-infected red blood cells were sequestered in the microcirculation of the brain and in the kidney. Compared with the nonlethal P. yoelii 17XNL strain, infection by P. yoelii 17XL caused substantial pulmonary edema, severe anemia, and significant body weight loss. Although P. yoelii 17XNL and 17XL produced a similar focal necrosis in the mouse liver, infection of P. yoelii 17XL induced coalescing of red and white pulp. Mortality caused by P. yoelii 17XL may be due to cerebral malaria, as well as respiratory distress syndrome and severe anemia. Plasmodium yoelii 17XL-infected rodent malaria seems to be a useful model for investigating severe malaria caused by P. falciparum.     

Malaria renders mice susceptible to mosquito feeding when gametocytes are most infective

Mice infected with Plasmodium berghei, P. chabaudi, or P. yoelii became lethargic and ceased to display normal antimosquito behavior. Periods of reduced defensiveness corresponded with maximum mosquito engorgement and with periods of maximum gametocyte infectivity to mosquitoes. Increased feeding success of mosquitoes during periods of peak gametocyte infectivity may be important to the natural maintenance of these malaria parasites.     

Prostaglandin derivatives inhibit the growth of malarial parasites in mice

New prostaglandin oligomeric derivatives, termed MR-256 and MR-356, were found to inhibit the growth of murine malarial parasites, P. chabaudi and P. vinckei, within red blood cells in vivo. When mice were infected with P. chabaudi, both MR-256 and MR-356 suppressed the growth of parasites, but MR-356 had a greater inhibitory effect than MR-256. With P. vinckei, MR-356 also inhibited the growth of parasites, and improved the survival rate. The effect of MR-256 was much less. A possible inhibitory mechanism of action of these drugs is discussed.     

Passive immunization against murine malaria with an IgG3 monoclonal antibody

Spleen cells of BALB/c mice that were immune to the 17X strain of P. yoelii were fused with P3X63Ag8 myeloma cells. Two hundred fifty-three of 1053 hybrid cells produced antibodies reactive with disrupted 17X parasites in a solid phase radioimmunoassay. One of these antibodies, McAb 302, reacted with the merozoites of the 17X (nonlethal) and 17XL (lethal) variants of P. yoelii. Of greater significance, McAb 302 passively protected mice against challenge infection with the lethal variant. Mice treated with this antibody before infection developed low-grade parasitemia (less than 0.3%) of short duration when challenged with P. yoelii 17XL . In contrast, control mice that had been untreated or injected with ascites fluid lacking McAb 302 uniformly died with fulminating malaria upon challenge with the same parasite. In other experiments, McAb 302 was shown capable of controlling blood parasite levels when administered to mice with patent P. yoelii 17XL infections. Although all control mice died, mice protected with a single dose of McAb 302 ultimately cleared their infections. Regardless of how passive immunization was performed, mice given McAb 302 were resistant to subsequent challenge with P. yoelii 17XL , indicating they had developed significant immunity during their initial controlled infections. McAb 302 also showed pronounced passive protective activity against the nonlethal 17X strain of P. yoelii, which is a parasite of reticulocytes. The protection afforded by McAb 302 was specific, because mice passively immunized with this antibody died when challenged with the unrelated P. vinckei. McAb 302 was shown to possess the IgG3 isotype and precipitated a 230-kd protein plus several smaller polypeptides from metabolically labeled parasite antigen preparation derived from both variants of P. yoelii. It did not react with similar preparations of other murine plasmodial species.     

A comparative study of the kinetic changes of hemopoietic stem cells in mice infected with lethal and non-lethal malaria.

The kinetic changes of hemopoietic stem cells in bone marrow and spleen were compared between lethal Plasmodium berghei- and non-lethal P. yoelii 17x-infected mice. P. yoelii 17x-infected mice showed more severe splenomegaly than those infected with P. berghei. P. yoelii 17x-infected mice also showed a greater degree of sustained increase in number of multipotent hemopoietic stem cells (colony-forming units in spleen: CFU-S) and committed stem cells for granulocytes and macrophages (CFU-GM) and for erythrocytes (CFU-E) than P. berghei-infected mice. Such an increase was predominantly seen in the spleen of P. yoelii 17x-infected mice. In P. berghei-infected mice, the number of CFU-S, CFU-GM and also CFU-E only transiently increased and then decreased to a subnormal level at the late stage of infection. The proportion of cycling CFU-S was higher in P. berghei-infected mice than in P. yoelii 17x-infected mice. The IL-3 producing activity per spleen was much higher in P. yoelii 17x-infected than in P. berghei-infected mice at any point in time during the infection. Thus, hemopoietic changes seen after malaria infection seem to be closely related to the pathogenicity of the malaria parasite.     

Coinfection with nonlethal murine malaria parasites suppresses pathogenesis caused by Plasmodium berghei NK65

Mixed infection with different Plasmodium species is often observed in endemic areas, and the infection with benign malaria parasites such as Plasmodium vivax or P. malariae has been considered to reduce the risk of developing severe pathogenesis caused by P. falciparum. However, it is still unknown how disease severity is reduced in hosts during coinfection. In the present study, we investigated the influence of coinfection with nonlethal parasites, P. berghei XAT (Pb XAT) or P. yoelii 17X (Py 17X), on the outcome of P. berghei NK65 (Pb NK65) lethal infection, which caused high levels of parasitemia and severe pathogenesis in mice. We found that the simultaneous infection with nonlethal Pb XAT or Py 17X suppressed high levels of parasitemia, liver injury, and body weight loss caused by Pb NK65 infection, induced high levels of reticulocytemia, and subsequently prolonged survival of mice. In coinfected mice, the immune response, including the expansion of B220(int)CD11c(+) cells and CD4(+) T cells and expression of IL-10 mRNA, was comparable to that in nonlethal infection. Moreover, the suppression of liver injury and body weight loss by coinfection was reduced in IL-10(-/-) mice, suggesting that IL-10 plays a role for a reduction of severity by coinfection with nonlethal malaria parasites.     

Haptoglobin and malaria

Haptoglobin gene knockout mice and wild-type controls were infected with Plasmodium berghei ANKA or Plasmodium chabaudi. The peak parasitaemia and parasite burden were higher in Hp-/- mice than in Hp+/+ mice. The increase in spleen weight following malaria infection was smaller in Hp-/- mice than in Hp+/+ animals. The occurrence of cerebral malaria in P. berghei ANKA infection was not different in Hp gene knockout mice and their controls.     

Immunity to Plasmodium berghei yoelii in mice. II. Specific and nonspecific cellular and humoral responses during the course of infection.

The kinetics of various specific and nonspecific immunologic responses were examined in BALB/c mice infected with 17X nonlethal Plasmodium berghei yoelii (a self-limiting infection). The sequence of events after infection was characterized by rapid sensitization of splenic T cells to malaria antigen and polyclonal B cell activation, followed by a period of depressed splenic proliferative responses in vitro to mitogens (PHA and LPS) and malaria (specific) antigen. At the same time, suppressed primary in vitro splenic PFC responses to trinitrophenyl-aminoethylcarbamylmethyl-Ficoll (TNP-F) were seen. This suppression was an active process requiring adherent cells. During this period, levels of antimalarial antibody also increased exponentially. As the infection was cleared, splenic malaria antigen-specific proliferative responses were again observed and splenic PFC and in vitro mitogen responses returned to preinfection levels after variable periods of time. Both splenic proliferative responses to malaria antigen and antimalarial antibody responses remained persistently elevated. In addition, some responses were examined in mice infected with 17X lethal P.b. yoelii (a fatal infection); in comparison to the early responses of mice infected with the nonlethal substrain, there was a decrease and delay in the development of a splenic T cell response to malaria antigen and a blunted antimalarial antibody response.     

Immunoregulation in murine malaria. Susceptibility of inbred mice to infection with Plasmodium yoelii depends on the dynamic interplay of host and parasite genes

Inbred and H-2 congenic mouse strains were tested for their ability to resist infections with the non-lethal 17X or with the lethal YM isolates of Plasmodium yoelii. DBA/2 and B10.D2 mice, which best resisted infections with non-lethal P. yoelii, were exquisitely susceptible to infection with lethal isolates of this malaria species. In contrast, B6 and B10 mice, which were susceptible to infection with non-lethal P. yoelii, were resistant to infection with the lethal isolates. This reversal of host response phenotype was influenced by H-2 genes, as evidenced by the divergent responses of the H-2 congenic strains B10 and B10.D2. However, a survey of mouse strains sharing common H-2 genes, but expressing different genetic backgrounds, demonstrated that genes outside the H-2 complex also influence the outcome of P. yoelii infections. By enumerating the numbers of P. yoelii-specific antibody-secreting cells in the spleens of infected mice, it was demonstrated that B6 mice, although susceptible to infection with non-lethal P. yoelii, nonetheless made a far stronger anti-parasite response after infection than did resistant DBA/2 mice. Using FACS analysis it was shown that infected B6 mice also produced large amounts of antibodies which bound to the surface of uninfected RBC. Thus, in B6 mice infected with non-lethal P. yoelii, a strong parasite-induced immune response was associated with susceptibility rather than resistance to infection. When T cell-deficient nude mice and their normal littermates were infected with the different isolates of P. yoelii, the nude mice had lower levels of parasitemia and higher RBC counts during the early stages of these infections, and lived longer than did normal littermates after infection with the lethal isolate. These data and the data from studies of B6 and DBA/2 mice support the idea that a strong immune response may be associated with susceptibility rather than resistance to P. yoelii, at least during the early stages of the infection. The finding that a single strain of mouse may present as resistant to infection with one P. yoelii isolate yet be exquisitely susceptible to infection with another suggests that the outcome of these murine malaria infections is dependent on a dynamic interplay between host and parasite genes. Thus, when genetic variability exists in both the host and the parasite populations, as would occur in nature, there may be little directed evolutionary change toward one phenotype or another.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies of murine malaria antigens using monoclonal antibodies. Production, selection, and characterization of antibodies

A panel of ten monoclonal antibodies made against Plasmodium chabaudi and Plasmodium yoelii infected mouse erythrocytes were used for characterization of antigens present in murine malaria. Screening of the antibodies in ELISA with different fractions of infected erythrocytes revealed both species-specific and fraction-specific monoclonal antibodies (MAbs), but also MAbs cross-reacting between the species. Two MAbs bound normal erythrocyte components. Subcellular localization of the target antigens was studied by immunofluorescence and their molecular identity by immunoblotting after SDS-PAGE. Of the MAbs to P. yoelii, one reacted with a cytoplasmic granule component of 137 k and two others reacted with vacuole-associated antigens of 26 k and 25/70/73 k, respectively. The latter antibodies cross-reacted with P. chabaudi antigens. Of the MAbs to P. chabaudi, all were species specific, one reacting with parasite surface antigens of 79 and 250 k and two with a vacuole-associated antigen of 70 k.     

Action of adrenalin on the circulation of the murine Plasmodium developing stages, in different blood compartments

Adrenalin was used to investigate in vivo the circulation of the different stages of rodent Plasmodium present in the blood. A single dose of adrenalin injected to mice infected with P. yoelii resulted immediately in i) a diminution of the parasitaemia of approximately 50% in the peripheral large vessels (estimated in tail blood films), as well as in the capillaries (estimated in smears of blood collected from a fed Anopheles), and ii) an increased parasitaemia in blood collected by cardiac puncture from the right heart. The numbers of young stages of P. yoelii in the peripheral blood were initially somewhat reduced but, unexpectedly, midterm trophozoites were preferentially expelled from the peripheral blood into major organs like the heart. With P. vinckei, parasitaemia decreased only when midterm trophozoites predominated, and with P. chabaudi no effect was observed at any time. We propose that midterm trophozoites, by their increased surface area, as compared to rings, and their flexibility which contrasts with the rigid schizonts, are particularly susceptible to haemodynamic perturbations.