Efficacy of two artemisinin combination therapies for uncomplicated falciparum malaria in children under 5 years, Malakal, Upper Nile, Sudan

Background

The treatment for Plasmodium falciparum malaria in Sudan has been in process of change since 2003. Preceding the change, this study aimed to determine which artemisinin-based combination therapies is more effective to treat uncomplicated malaria in Malakal, Upper Nile, Sudan.

Methods

Clinical trial to assess the efficacy of 2 antimalarial therapies to treat P. falciparum infections in children aged 6–59 months, in a period of 42 days after treatment.

Results

A total of 269 children were followed up to 42 days. Artesunate plus Sulfadoxine/Pyrimethamine (AS+SP) and Artesunate plus Amodiaquine (AS+AQ) were both found to be efficacious in curing malaria infections by rapid elimination of parasites and clearance of fever, in preventing recrudescence and suppressing gametocytaemia. The combination of AS+SP appeared slightly more efficacious than AS+AQ, with 4.4% (4/116) versus 15% (17/113) of patients returning with malaria during the 6-week period after treatment (RR = 0.9, 95% CI 0.81–0.96). PCR analysis identified only one recrudescence which, together with one other early treatment failure, gave efficacy rates of 99.0% for AS+AQ (96/97) and 99.1% for AS+SP (112/113). However, PCR results were incomplete and assuming part of the indeterminate samples were recrudescent infections leads to an estimated efficacy ranging 97–98% for AS+SP and 88–95% for AS+AQ.

Conclusion

These results lead to the recommendation of ACT, and specifically AS+SP, for the treatment of uncomplicated falciparum malaria in this area of Sudan. When implemented, ACT efficacy should be monitored in sentinel sites representing different areas of the country.     

Natural regulatory (CD4+CD25+FOXP+) T cells control the production of pro-inflammatory cytokines during Plasmodium chabaudi adami infection and do not contribute to immune evasion

Different functions have been attributed to natural regulatory CD4+CD25+FOXP+ (Treg) cells during malaria infection. Herein, we assessed the role for Treg cells during infections with lethal (DS) and non-lethal (DK) Plasmodium chabaudi adami parasites, comparing the levels of parasitemia, inflammation and anaemia. Independent of parasite virulence, the population of splenic Treg cells expanded during infection, and the absolute numbers of activated CD69+ Treg cells were higher in DS-infected mice. In vivo depletion of CD25+ T cells, which eliminated 80% of CD4+FOXP3+CD25+ T cells and 60-70% of CD4+FOXP3+ T cells, significantly decreased the number of CD69+ Treg cells in mice with lethal malaria. As a result, higher parasite burden and morbidity were measured in the latter, whereas the kinetics of infection with non-lethal parasites remained unaffected. In the absence of Treg cells, parasite-specific IFN-gamma responses by CD4+ T cells increased significantly, both in mice with lethal and non-lethal infections, whereas IL-2 production was only stimulated in mice with non-lethal malaria. Following the depletion of CD25+ T cells, the production of IL-10 by CD90(-) cells was also enhanced in infected mice. Interestingly, a potent induction of TNF-alpha and IFN-gamma production by CD4+ and CD90(-) lymphocytes was measured in DS-infected mice, which also suffered severe anaemia earlier than non-depleted infected controls. Taken together, our data suggest that the expansion and activation of natural Treg cells represent a counter-regulatory response to the overwhelming inflammation associated with lethal P.c. adami. This response to infection involves TH1 lymphocytes as well as cells from the innate immune system.     

Implications of Glutathione Levels in the Plasmodium berghei Response to Chloroquine and Artemisinin

Malaria is one of the most devastating parasitic diseases worldwide. Plasmodium drug resistance remains a major challenge to malaria control and has led to the re-emergence of the disease. Chloroquine (CQ) and artemisinin (ART) are thought to exert their anti-malarial activity inducing cytotoxicity in the parasite by blocking heme degradation (for CQ) and increasing oxidative stress. Besides the contribution of the CQ resistance transporter (PfCRT) and the multidrug resistant gene (pfmdr), CQ resistance has also been associated with increased parasite glutathione (GSH) levels. ART resistance was recently shown to be associated with mutations in the K13-propeller protein. To analyze the role of GSH levels in CQ and ART resistance, we generated transgenic Plasmodium berghei parasites either deficient in or overexpressing the gamma-glutamylcysteine synthetase gene (pbggcs) encoding the rate-limiting enzyme in GSH biosynthesis. These lines produce either lower (pbggcs-ko) or higher (pbggcs-oe) levels of GSH than wild type parasites. In addition, GSH levels were determined in P. berghei parasites resistant to CQ and mefloquine (MQ). Increased GSH levels were detected in both, CQ and MQ resistant parasites, when compared to the parental sensitive clone. Sensitivity to CQ and ART remained unaltered in both pgggcs-ko and pbggcs-oe parasites when tested in a 4 days drug suppressive assay. However, recrudescence assays after the parasites have been exposed to a sub-lethal dose of ART showed that parasites with low levels of GSH are more sensitive to ART treatment. These results suggest that GSH levels influence Plasmodium berghei response to ART treatment.     

Plasmodium berghei NK65: studies on the effect of treatment duration and inoculum size on recrudescence

Recrudescence of Plasmodium berghei NK65 infection was studied to examine factors affecting recrudescence. Treatment with a high dose of chloroquine did not prevent recrudescence, but an extended duration of treatment suppressed the frequency of recrudescence. Infection with a larger number of parasites also resulted in more frequent recrudescences. Recrudescent parasites were as sensitive to chloroquine as those before treatment. Splenectomized mice were administered carbon particles, infected, and treated with chloroquine. Recrudescence was significantly more frequent in these mice than in mice given a sham operation and PBS. The results do not suggest that merozoite stages escape the effect of chloroquine by 'hiding' in phagocytes, but that latent parasites such as dormant ring stages may cause recrudescence.     

Strain-specific spleen remodelling in Plasmodium yoelii infections in Balb/c mice facilitates adherence and spleen macrophage-clearance escape

Knowledge of the dynamic features of the processes driven by malaria parasites in the spleen is lacking. To gain insight into the function and structure of the spleen in malaria, we have implemented intravital microscopy and magnetic resonance imaging of the mouse spleen in experimental infections with non-lethal (17X) and lethal (17XL) Plasmodium yoelii strains. Noticeably, there was higher parasite accumulation, reduced motility, loss of directionality, increased residence time and altered magnetic resonance only in the spleens of mice infected with 17X. Moreover, these differences were associated with the formation of a strain-specific induced spleen tissue barrier of fibroblastic origin, with red pulp macrophage-clearance evasion and with adherence of infected red blood cells to this barrier. Our data suggest that in this reticulocyte-prone non-lethal rodent malaria model, passage through the spleen is different from what is known in other Plasmodium species and open new avenues for functional/structural studies of this lymphoid organ in malaria.     

Host cell preference and variable transmission strategies in malaria parasites

Malaria and other haemosporin parasites must undergo a round of sexual reproduction in their insect vector in order to produce stages that can be transmitted to vertebrate hosts. Consequently, it is crucial that parasites produce the sex ratio (proportion of male sexual stages) that will maximize the number of fertilization and thus, transmission to new vertebrate hosts. There is some evidence to show that, consistent with evolutionary theory, the sex ratios of malaria parasites are negatively correlated to their inbreeding rate. However, recent theory has shown that when fertilization success is compromised, parasites should respond by increasing their investment in sexual stages or by producing a less female biased ration than predicted by their inbreeding rate alone. Here, we show that two species of rodent malaria, Plasmodium chabaudi and Plasmodium vinckei petteri, adopt different strategies in response to host anaemia, a factor though to compromise transmission success: P. chabaudi increases investment in sexual stages, whereas P. vinckei produces a less female biased sex ratio. We suggest that these different transmission strategies may be due to marked differences in host cell preference.     

The species specificity of immunity generated by live whole organism immunisation with erythrocytic and pre-erythrocytic stages of rodent malaria parasites and implications for vaccine development

A promising strategy for the development of a malaria vaccine involves the use of attenuated whole parasites, as these present a greater repertoire of antigens to the immune system than subunit vaccines. The complexity of the malaria parasite's life cycle offers multiple stages on which to base an attenuated whole organism vaccine. An important consideration in the design and employment of such vaccines is the diversity of the parasites that are infective to humans. The most valuable vaccine would be one that was effective against multiple species/strains of malaria parasite. Here we compare the species specificity of pre-erythrocytic and erythrocytic whole organism vaccination using live parasites with anti-malarial drug attenuation. The cross-stage protection afforded by each vaccination strategy, and the possibility that immunity against one stage may be abrogated by exposure to other stages of both homologous and heterologous parasites was also assessed. The rodent malaria parasites Plasmodium yoelii yoelii and Plasmodium vinckei lentum are to address these questions, as they offer the widest possible genetic distance between sub-species of malaria parasites infectious to rodents. It was found that both erythrocytic and pre-erythrocytic stage immunity generated by live, attenuated parasite vaccination have species-specific components, with pre-erythrocytic stage immunity offering a much broader pan-species protection. We show that the protection achieved following sporozoite inoculation with concurrent mefloquine treatment is almost entirely dependent of CD8(+) T-cells. Evidence is presented for cross-stage protection between erythrocytic and pre-erythrocytic stage vaccination. Finally, it is shown that, with these species, an erythrocytic stage infection of either a homologous or heterologous species following immunisation with pre-erythrocytic stages does not abrogate this immunity. This is the first direct comparison of the specificity and efficacy of erythrocytic and pre-erythrocytic stage whole organism vaccination strategies utilising the same parasite species pair.     

Adaptive immunity is essential in preventing recrudescence of Plasmodium yoelii malaria parasites after artesunate treatment

Artemisinin‐based antimalarials, such as artesunate (ART), alone or in combination, are the mainstay of the therapy against malaria caused by Plasmodium falciparum. However, the emergence and spread of artemisinin resistance threatens the future success of its global malaria eradication. Although much of the reported artemisinin resistance can be attributed to mutations intrinsic to the parasite, a significant proportion of treatment failures are thought to be due to other factors such as the host's immune system. Exactly how the immune system participates in the clearance and elimination of malaria parasites during ART treatment is unknown. Here, we show that a developing primary immune response, involving both B and CD4⁺ T cells, is necessary for the complete elimination but not initial clearance, of Plasmodium yoelii YM parasites in mice treated with ART. Our study uncovers a dynamic interplay between ART and host adaptive immunity in Plasmodium sp. elimination.     

Malarial anaemia: mechanisms and implications of insufficient erythropoiesis during blood-stage malaria

It has been proposed that the basis of severe malarial anaemia, a major cause of morbidity and mortality in endemic areas, is multifactorial. Inappropriately low reticulocytosis is observed in malaria patients suggesting that insufficient erythropoiesis is a major factor. Clinical studies provide conflicting data concerning the production of adequate levels of erythropoietin (EPO) during malaria. Plasmodium chabaudi AS causes non-lethal infection in resistant C57BL/6 mice, and lethal infection in susceptible A/J mice. In P. chabaudi AS infected C57BL/6 and A/J mice, which experience varying degrees of severity of anaemia, kidney EPO production is appropriate to the severity of anaemia and is regulated by haematocrit level. Neutralisation of endogenous EPO during infection leads to lethal anaemia while timely administration of exogenous EPO rescues mice although reticulocytosis is suppressed in proportion to the parasitemia level. Characterisation of alterations in splenic erythroid compartments in naive and P. chabaudi AS infected A/J mice revealed that infection, with or without EPO treatment, leads to sub-optimal increases in TER119+ erythroblasts compared to EPO-treated naive mice. A lower percentage of TER119+ erythroblasts in infected mice undergo terminal differentiation to become mature haemoglobin-producing cells. Furthermore, there is a shift in transferrin receptor (CD71) expression from TER119+ cells to a non-erythroid population. Deficiencies in the number and maturation of TER119+ erythroblasts during infection coincide with blunted proliferation to EPO stimulation in vitro by splenocytes, although a high frequency express EPO receptor (EPOR). Together, these data suggest that during malaria, EPO-induced proliferation of early EPOR+ erythroid progenitors is suppressed, leading to sub-optimal generation of TER119+ erythroblasts. Moreover, a shift in CD71 expression may result in impaired terminal maturation of erythroblasts. Thus, suppressed proliferation, differentiation, and maturation of erythroid precursors in association with inadequate reticulocytosis may be the basis of insufficient erythropoiesis during malaria.     

Interdependence of CD4+ T cells and malarial spleen in immunity to Plasmodium vinckei vinckei. Relevance to vaccine development

We studied immunity to the blood stage of the rodent malaria, Plasmodium vinckei vinckei, which is uniformly lethal to mice. BALB/c mice develop solid immunity after two infections and drug cure. The following experiments define the basis of this immunity. Transfer of pooled serum from such immune mice renders very limited protection to BALB/c mice and no protection to athymic nu/nu mice. Moreover, B cell-deficient C3H/HeN mice develop immunity to P. vinckei reinfection in the same manner as immunologically intact mice, an observation made earlier. In vivo depletion of CD4+ T cells in immune mice abrogates their immunity. This loss of immunity could be reversed through reconstitution of in vivo CD4-depleted mice with fractionated B-, CD8-, CD4+ immune spleen cells; however, adoptive transfer of fractionated CD4+ T cells from immune spleen into naive BALB/c or histocompatible BALB/c nude mice does not render recipients immune. In vivo depletion of CD8+ T cells did not influence the parasitemia in nonimmune or immune mice. Splenectomy of immune mice completely reverses their immunity. Repletion of splenectomized mice with their own spleen cells does not reconstitute their immunity. We conclude that some feature of the malaria-modified spleen acts in concert with the effector/inducer function of CD4+ T cells to provide protection from P. vinckei. To be consistent with this finding, a malaria vaccine may require a combination of malaria Ag to induce immune CD4+ T cells and an adjuvant or other vaccine vehicle to alter the spleen.     

Rodent malaria parasites Plasmodium chabaudi and P. vinckei do not increase their rates of gametocytogenesis in response to mosquito probing

Several vector-borne infectious agents facultatively alter their life history strategies in response to local vector densities. Some evidence suggests that malaria parasites invest more heavily in transmission stage production (gametocytogenesis) when vectors are present. Such a strategy could rapidly increase malaria transmission rates, particularly when adult mosquitoes begin to appear after dry seasons. However, in contrast to a recent experiment with a rodent malaria (Plasmodium chabaudi), we found no change in gametocytogenesis in either P. chabaudi or in another rodent malaria, P. vinckei, when their mouse hosts were exposed to mosquitoes. Positive results in the earlier study may have been because mosquito-feeding caused anaemia in hosts, a known promoter of gametocytogenesis. The substantial evidence that malaria and a variety of other parasites facultatively alter transmission strategies in response to a variety of environmental influences makes our results surprising.     

Free-flow electrophoresis for the separation of malaria infected and uninfected mouse erythrocytes and for the isolation of free parasites (Plasmodium vinckei): a new rapid technique for the liberation of malaria parasites from their host cells.

After aggregation of erythrocytes from malaria infected mice, the parasites (Plasmodium vinckei) could be set free using gentle mechanical forces. The mixture of freed parasites, infected and non-infected erythrocytes, and membraneous material was separated by free-flow electrophoresis. The free parasites produced were very pure and infectious. Morphological and enzymatic data on the separated fractions are presented. Free-flow electrophoresis also allowed the separation of infected and uninfected erythrocytes.     

Coincident parasite and CD8 T cell sequestration is required for development of experimental cerebral malaria

Cerebral malaria (CM) is a fatal complication of Plasmodium falciparum infection. Using a well defined murine model, we observed the effect on disease outcome of temporarily reducing parasite burden by anti-malarial drug treatment. The anti-malarial treatment regime chosen decreased parasitaemia but did not cure the mice, allowing recrudescence of parasites. These mice were protected against CM, despite their parasitaemia having increased, following treatment cessation, to levels surpassing that associated with CM in mice not treated with the drug. The protection was associated with reduced levels of cytokines, chemokines, CD8⁺ T cells and parasites in the brain. The results suggest that the development of the immunopathological response that causes CM depends on a continuous stimulus provided by parasitised red blood cells, either circulating or sequestered in small vessels.     

Curcumin-arteether combination therapy of Plasmodium berghei-infected mice prevents recrudescence through immunomodulation

Earlier studies in this laboratory have shown the potential of artemisinin-curcumin combination therapy in experimental malaria. In a parasite recrudescence model in mice infected with Plasmodium berghei (ANKA), a single dose of alpha,beta-arteether (ART) with three oral doses of curcumin prevented recrudescence, providing almost 95% protection. The parasites were completely cleared in blood with ART-alone (AE) or ART+curcumin (AC) treatments in the short-term, although the clearance was faster in the latter case involving increased ROS generation. But, parasites in liver and spleen were not cleared in AE or AC treatments, perhaps, serving as a reservoir for recrudescence. Parasitemia in blood reached up to 60% in AE-treated mice during the recrudescence phase, leading to death of animals. A transient increase of up to 2–3% parasitemia was observed in AC-treatment, leading to protection and reversal of splenomegaly. A striking increase in spleen mRNA levels for TLR2, IL-10 and IgG-subclass antibodies but a decrease in those for INFγ and IL-12 was observed in AC-treatment. There was a striking increase in IL-10 and IgG subclass antibody levels but a decrease in INFγ levels in sera leading to protection against recrudescence. AC-treatment failed to protect against recrudescence in TLR2^−/− and IL-10^−/− animals. IL-10 injection to AE-treated wild type mice and AC-treated TLR2^−/− mice was able to prolong survival. Blood from the recrudescence phase in AE-treatment, but not from AC-treatment, was able to reinfect and kill naïve animals. Sera from the recrudescence phase of AC-treated animals reacted with several parasite proteins compared to that from AE-treated animals. It is proposed that activation of TLR2-mediated innate immune response leading to enhanced IL-10 production and generation of anti-parasite antibodies contribute to protective immunity in AC-treated mice. These results indicate a potential for curcumin-based combination therapy to be tested for prevention of recrudescence in falciparum and relapse in vivax malaria.     

Dormancy in the Copepoda — an overview

Dormancy affects copepods in their anatomy, physiology, genetics, population biology, community ecology, evolution and local and geographic distribution. It is known from freeliving representatives of three copepod taxa, namely the Harpacticoida, Cyclopoida and Calanoida. Species showing dormancy occur in various realms and habitats, both freshwater and marine, being benthic, planktic or ice-dwelling. Depending on the taxon, dormancy occurs at various times of the year, prevailing in higher and temperate latitudes. Copepod dormancy is expressed in various ontogenetic stages, such as resting eggs, arrested larval development, juvenile and adult encystment, or arrested development of nonencysted copepodids or adults. Ecologically, dormancy is an energy saving trait, allowing the individual to bridge periods of environmental harshness. Adverse environmental conditions could be abiotic (e.g. desiccation, temperature, oxygen availability) or biotic in nature (e.g. food availability, predation). Diapause s. str. is initiated, maintained and terminated by triggering factors (e.g. photoperiod, temperature, chemical cues, population density/physiological factors). The dormant state and emergence patterns directly affect reproduction, population dynamics, community composition, coexistence and distribution of copepods, as well as the phenology of their predators and living food items. Populations having dormancy, in most cases belong to and affect communities of two realms: the water column and the bottom. Dormant stages may provide means for dispersal as well as for staying in special localities. The variability of dormancy permits flexible and complex life histories. Dormancy is subjected to and on the other hand affects copepod evolution.     

Plasmodium vinckei: selection of a strain exhibiting stable resistance to arteether

A strain of rodent malaria parasite Plasmodium vinckei showing >12-fold resistance to arteether has been selected after exposure to sub-curative doses of drug in 44 sequential passages over a period of 700 days. Experimentally induced resistance was found to be stable after drug free maintenance of parasites for 11 serial passages over a period of 100 days. Cross-sensitivity studies have shown that apart form resistance to related derivatives like artemether and artesunic acid, the derived parasites also show resistance to quinine and mefloquine.