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

High-level artemisinin-resistance with quinine co-resistance emerges in P. falciparum malaria under in vivo artesunate pressure

BACKGROUND

Humanity has become largely dependent on artemisinin derivatives for both the treatment and control of malaria, with few alternatives available. A Plasmodium falciparum phenotype with delayed parasite clearance during artemisinin-based combination therapy has established in Southeast Asia, and is emerging elsewhere. Therefore, we must know how fast, and by how much, artemisinin-resistance can strengthen.

METHODS

P. falciparum was subjected to discontinuous in vivo artemisinin drug pressure by capitalizing on a novel model that allows for long-lasting, high-parasite loads. Intravenous artesunate was administered, using either single flash-doses or a 2-day regimen, to P. falciparum-infected humanized NOD/SCID IL-2Rγ^-/-immunocompromised mice, with progressive dose increments as parasites recovered. The parasite's response to artemisinins and other available anti-malarial compounds was characterized in vivo and in vitro.

RESULTS

Artemisinin resistance evolved very rapidly up to extreme, near-lethal doses of artesunate (240 mg/kg), an increase of > 3000-fold in the effective in vivo dose, far above resistance levels reported from the field. Artemisinin resistance selection was reproducible, occurring in 80% and 41% of mice treated with flash-dose and 2-day regimens, respectively, and the resistance phenotype was stable. Measuring in vitro sensitivity proved inappropriate as an early marker of resistance, as IC₅₀ remained stable despite in vivo resistance up to 30 mg/kg (ART-S: 10.7 nM (95% CI 10.2-11.2) vs. ART-R₃₀: 11.5 nM (6.6-16.9), F = 0.525, p = 0.47). However, when in vivo resistance strengthened further, IC₅₀ increased 10-fold (ART-R₂₄₀ 100.3 nM (92.9-118.4), F = 304.8, p < 0.0001), reaching a level much higher than ever seen in clinical samples. Artemisinin resistance in this African P. falciparum strain was not associated with mutations in kelch-13, casting doubt over the universality of this genetic marker for resistance screening. Remarkably, despite exclusive exposure to artesunate, full resistance to quinine, the only other drug sufficiently fast-acting to deal with severe malaria, evolved independently in two parasite lines exposed to different artesunate regimens in vivo, and was confirmed in vitro.

CONCLUSION

P. falciparum has the potential to evolve extreme artemisinin resistance and more complex patterns of multidrug resistance than anticipated. If resistance in the field continues to advance along this trajectory, we will be left with a limited choice of suboptimal treatments for acute malaria, and no satisfactory option for severe malaria.

More insights into the pharmacological effects of artemisinin

Artemisinin is one of the most widely prescribed drugs against malaria and has recently received increased attention because of its other potential biological effects. The aim of this review is to summarize recent discoveries of the pharmaceutical effects of artemisinin in basic science along with its mechanistic action, as well as the intriguing results of recent clinical studies, with a focus on its antitumor activity. Scientific evidence indicates that artemisinin exerts its biological activity by generating reactive oxygen species that damage the DNA, mitochondrial depolarization, and cell death. In the present article review, scientific evidence suggests that artemisinin is a potential therapeutic agent for various diseases. Thus, this review is expected to encourage interested scientists to conduct further preclinical and clinical studies to evaluate these biological activities.

Assessment of real-time method to detect liver parasite burden under different experimental conditions in mice infected with Plasmodium yoelii sporozoites

Use of highly specific, sensitive and quantitative Real-Time PCR (qRT-PCR) based methods greatly facilitate the monitoring of experimental drug intervention and vaccination efficacy targeting liver stage malaria parasite. Here, in this study we have used qRT-PCR to detect the growing liver stage parasites following inoculation of Plasmodium yoelii sporozoite. Route of sporozoite administration and size of the sporozoite inoculums are two major determinants that affect the liver stage parasite load and therefore its detection and quantification. Thus, these factors need to be addressed to determine the accuracy of detection and quantification of Real-Time PCR method. Furthermore, applicability of quantitative RT-PCR system needs to be confirmed by analyzing the effect of different antimalarials on liver stage parasite burden. We have observed that parasite burden in mice infected via intravenous route was higher compared to that in subcutaneous, intradermal and intraperitoneal route infected mice. Moreover, this method detected liver stage parasite load with as low as 50 sporozoites. The inhibition studies with primaquine and atovaquone revealed inhibition of liver stage parasite and well correlated with patency and course of blood stage infection. This study characterized the simplicity, accuracy, and quantitative analysis of liver stage parasite development by real time PCR under different experimental conditions. Use of real time PCR method greatly improves the reproducibility and applicability to estimate the efficacy and potency of vaccine or drug candidates targeting liver stage parasite.

Host immune response is severely compromised during lethal Plasmodium vinckei infection

Cytokines and immune effector cells play an important role in determining the outcome of infection with various intracellular pathogens, including protozoan parasites. However, their role during lethal and nonlethal malaria needs further validation. In the present study, we examined the role of cytokines and various immune effector cells during lethal and nonlethal malaria caused by Plasmodium vinckei in AKR mice. We show that lethal P. vinckei infection (PvAS) in AKR mice is characterized by increased parasite growth, decreased production of pro-inflammatory cytokines, and attenuated cell proliferation and nitric oxide (NO) synthesis resulting in increased parasitemia which ultimately leads to death of all animals by day 5 post infection. In contrast, AKR mice infected with lethal parasite (PvAR) showed elevated levels of pro-inflammatory cytokines, heightened cell proliferation, and NO synthesis leading to complete parasite clearance by day 22 post infection. Flow cytometric analysis performed on splenocytes from PvAS- and PvAR-infected mice shows that host immunity is severely compromised in PvAS-infected mice as was evident by decreased percentages of CD4(+) and CD8(+) T cells, B cells, plasma cells, dendritic cells (DCs), and macrophages (MΦs) which was in complete contrast to PvAR-infected animals which exhibited elevated numbers of all the cell types analyzed. Taken together, findings of the present study show that coordinated actions of pro-inflammatory cytokines and other immune effector cells are essential to control lethal malarial infection and their attenuation leads to increased parasite growth and, ultimately, death of animals.

Arteether resistance reversal by ketoconazole/fluconazole in rodent malaria parasite Plasmodium vinckei

Artemisinin and its derivative arteether (ART) are fast acting antimalarial drugs against chloroquine-resistant. There are several partner drugs that are identified as a potential drug for artemisinin combination therapy (ACT) to develop as the antimalarial drug. Limited studies have been carried out in ART drug combination that may have more promising as ACT for resistant Plasmodium parasite. Here, we are the first to show the ART drug resistance reversal in Plasmodium vinckei by using antifungal azole compounds ketoconazole (KTZ) and fluconazole (FCZ). Our previous study has shown that higher antioxidant enzyme, glutathione, and less hemozoin may be correlated with ART resistance in P. vinckei (PvAR). We further hypothesized that glutathione and heme catabolism may be interfered by KTZ and FCZ, resulting in an increased efficacy of ART in PvAR parasite. The results of present study demonstrate synergetic effect of KTZ and FCZ against PvAR parasite, since none of the mice developed infection up to day 10 after combination with ART. These results further showed that ED90 of ART was reduced from 17.23 to 2.19 and 2.56 mg/kg when used in combination with KTZ and FCZ, respectively. Resultant, activity enhancement index (AEI) of ART is significantly increased to 8.60 and 6.73 with partner agents. These studies propose the possibility of ART drug combination that may be helpful in prolonging the life of drug and a promising lead to reduce the chance of resistance development of artemisinin and its derivative.

Evolutionary biology and the avoidance of antimicrobial resistance

Evolutionary biologists have largely left the search for solutions to the drug resistance crisis to biomedical scientists, physicians, veterinarians and public health specialists. We believe this is because the vast majority of professional evolutionary biologists consider the evolutionary science of drug resistance to be conceptually uninteresting. Using malaria as case study, we argue that it is not. We review examples of evolutionary thinking that challenge various fallacies dominating antimalarial therapy, and discuss open problems that need evolutionary insight. These problems are unlikely to be resolved by biomedical scientists ungrounded in evolutionary biology. Involvement by evolutionary biologists in the science of drug resistance requires no intellectual compromises: the problems are as conceptually challenging as they are important.

Rapid response to selection, competitive release and increased transmission potential of artesunate-selected Plasmodium chabaudi malaria parasites

The evolution of drug resistance, a key challenge for our ability to treat and control infections, depends on two processes: de-novo resistance mutations, and the selection for and spread of resistant mutants within a population. Understanding the factors influencing the rates of these two processes is essential for maximizing the useful lifespan of drugs and, therefore, effective disease control. For malaria parasites, artemisinin-based drugs are the frontline weapons in the fight against disease, but reports from the field of slower parasite clearance rates during drug treatment are generating concern that the useful lifespan of these drugs may be limited. Whether slower clearance rates represent true resistance, and how this provides a selective advantage for parasites is uncertain. Here, we show that Plasmodium chabaudi malaria parasites selected for resistance to artesunate (an artemisinin derivative) through a step-wise increase in drug dose evolved slower clearance rates extremely rapidly. In single infections, these slower clearance rates, similar to those seen in the field, provided fitness advantages to the parasite through increased overall density, recrudescence after treatment and increased transmission potential. In mixed infections, removal of susceptible parasites by drug treatment led to substantial increases in the densities and transmission potential of resistant parasites (competitive release). Our results demonstrate the double-edged sword for resistance management: in our initial selection experiments, no parasites survived aggressive chemotherapy, but after selection, the fitness advantage for resistant parasites was greatest at high drug doses. Aggressive treatment of mixed infections resulted in resistant parasites dominating the pool of gametocytes, without providing additional health benefits to hosts. Slower clearance rates can evolve rapidly and can provide a strong fitness advantage during drug treatment in both single and mixed strain infections.

mRNA expression of cytokines and its impact on outcomes after infection with lethal and nonlethal Plasmodium vinckei parasites

Cytokines play an important role in the defense against malaria and some have long been documented to influence the course of malaria infection in rodents and humans. The present study was conducted to determine the mRNA expression pattern of a few prominent cytokines at different time points during the course of infection with a nonlethal and lethal Plasmodium vinckei rodent malaria parasite, using highly sensitive real-time PCR. Analysis of mRNA expression of cytokines in spleen from infected mice revealed that the principal difference was an early depletion in pro-inflammatory cytokine's mRNA expression in mice infected with lethal P. vinckei (PvAS) parasites. In addition, an increase in anti-inflammatory cytokines particularly IL-10 mRNA expression levels was found in the same group of mice. In contrast, the significant rise in pro-inflammatory cytokine's mRNA expression levels was recorded at day 1 onwards after infection with nonlethal P. vinckei (PvAR). The maximum fold change was recorded for IFN-γ and IL-10, when compared to baseline value. TGF-β did not seem to play any major role in P. vinckei infection.

Plasmodium vinckei: infectivity of arteether-sensitive and arteether-resistant parasites in different strains of mice

Malaria is one of the most lethal parasitic infections in the world. The lethality of the parasite depends on the rate of multiplication of the parasite within host erythrocytes. Different strains of the malaria parasite often respond in a different way to the same strain of mice or vice versa. In the present study, we investigated the course of infection of the arteether-sensitive and arteether-resistant Plasmodium vinckei parasites in Swiss albino AKR (inbred) and AJ (outbred) mice. The higher parasite burden and mortality were observed in the sensitive parasite-infected mice, whereas the infection with the resistant parasite was non-lethal. Resistant parasite-infected mice developed a moderate level of parasitemia that decreased gradually throughout the infection. The microscopic examination suggests that the resistant parasite invades reticulocytes more efficiently than normocytes, regardless of the mouse strain examined. Since the reticulocytes are rare in blood circulation, it limits the increase in parasite proliferations, while arteether-sensitive parasites can invade both mature normocytes and reticulocytes, resulting in the mortality of the mice. However, treatment with phenylhydrazine in Swiss mice results in reticulocytosis, which transforms the non-lethal resistant parasites to produce lethal infections. Our findings demonstrate that the characteristic response during infections with the arteether-resistant strain is dependent on the availability of reticulocytes in peripheral blood circulation. We can use this model for identifying the interaction between host and artemisinin derivative-resistant parasites.

Implication of intracellular glutathione and its related enzymes on resistance of malaria parasites to the antimalarial drug arteether

The control of malaria has been complicated by the increasing resistance of malarial parasites to multiple drugs. However, artemisinin-based drugs offer hope in the fight against drug-resistant parasites. The mode of action of these drugs remains unclear, but evidence suggests a role for free radicals in their mechanism of action. In this study, we examined the relationship between the intracellular levels of glutathione (GSH) and antioxidant enzymes and resistance to the artemisinin-based drug arteether in experimentally selected arteether-resistant Plasmodium vinckei. GSH plays a critical role in the detoxification and protection of cells against oxidative stress. Our comparative studies showed a significant (2.9-fold) increase in the GSH level in arteether-resistant parasites as compared to arteether-sensitive parasites. Simultaneously, significantly increased activities of glutathione reductase, glutathione-S transferase and glucose-6-phosphate dehydrogenase and decreased activity of superoxide dismutase were recorded in resistant parasites; the activity of glutathione peroxidase was comparable in arteether-sensitive and -resistant parasites. Artemisinin derivatives act by generating free radicals and our results indicate that glutathione's antioxidant effects may counteract that drug effect and thereby contribute to the parasites' resistance to arteether and other artemisinin-based antimalarials.

Plasmodium berghei K173: selection of resistance to naphthoquine in a mouse model

Naphthoquine (NQ), as a component of ARCO® which composed of NQ and artemisinin, is a new 4-aminoquinoline antimalarial synthesized by our institute. Here, a naphthoquine-resistant line of rodent malaria parasite was selected through exposing Plasmodium berghei Keyberg 173 strain to progressively increased drug pressure. The selected strain showed a more than 200-fold decreased susceptibility to NQ with a stable resistance phenotype after 10 serial passages without drug pressure or when cryopreserved over a period of 12 months. In a cross-resistance assay, the susceptibility of NQ-resistant parasites to chloroquine was decreased by 14.5-fold. These findings imply NQ-resistant parasites might be selected by long-term usage of NQ in epidemic areas and the efficacy of NQ or ARCO® in chloroquine-resistant Plasmodium falciparum epidemic areas should be monitored closely.

Discovery, mechanisms of action and combination therapy of artemisinin

Despite great international efforts, malaria still inflicts an enormous toll on human lives, especially in Africa. Throughout history, antimalarial medicines have been one of the most powerful tools in malaria control. However, the acquisition and spread of parasite strains that are resistant to multiple antimalarial drugs have become one of the greatest challenges to malaria treatment, and are associated with the increase in morbidity and mortality in many malaria-endemic countries. To deal with this grave situation, artemisinin-based combinatory therapies (ACTs) have been introduced and widely deployed in malarious regions. Artemisinin is a new class of antimalarial compounds discovered by Chinese scientists from the sweet wormwood Artemisia annua. The potential development of resistance to artemisinins by Plasmodium falciparum threatens the usable lifespan of ACTs, and therefore is a subject of close surveillance and extensive research. Studies at the Thai-Cambodian border, a historical epicenter of multidrug resistance, have detected reduced susceptibility to artemisinins as manifested by prolonged parasite-clearance times, raising considerable concerns on resistance development. Despite this significance, there is still controversy on the mode of action of artemisinins. Although a number of potential cellular targets of artemisinins have been proposed, they remain to be verified experimentally. Here, we review the history of artemisinin discovery, discuss the mode of action and potential drug targets, and present strategies to elucidate resistance mechanisms.

Plasmodium berghei ANKA: selection of resistance to piperaquine and lumefantrine in a mouse model

We have selected piperaquine (PQ) and lumefantrine (LM) resistant Plasmodium berghei ANKA parasite lines in mice by drug pressure. Effective doses that reduce parasitaemia by 90% (ED(90)) of PQ and LM against the parent line were 3.52 and 3.93 mg/kg, respectively. After drug pressure (more than 27 passages), the selected parasite lines had PQ and LM resistance indexes (I(90)) [ED(90) of resistant line/ED(90) of parent line] of 68.86 and 63.55, respectively. After growing them in the absence of drug for 10 passages and cryo-preserving them at -80 degrees C for at least 2 months, the resistance phenotypes remained stable. Cross-resistance studies showed that the PQ-resistant line was highly resistant to LM, while the LM-resistant line remained sensitive to PQ. Thus, if the mechanism of resistance is similar in P. berghei and Plasmodium falciparum, the use of LM (as part of Coartem) should not select for PQ resistance.

Artemisinins: their growing importance in medicine

Artemisinins are derived from extracts of sweet wormwood (Artemisia annua) and are well established for the treatment of malaria, including highly drug-resistant strains. Their efficacy also extends to phylogenetically unrelated parasitic infections such as schistosomiasis. More recently, they have also shown potent and broad anticancer properties in cell lines and animal models. In this review, we discuss recent advances in defining the role of artemisinins in medicine, with particular focus on their controversial mechanisms of action. This safe and cheap drug class that saves lives at risk from malaria can also have important potential in oncology.