Abstract
Parasitic infections induce a magnitude of host responses. At the opposite ends of the spectrum are those that ensure the host's needs to eliminate the invaders and to minimize damage to its own tissues. This review analyzes how parasites would manipulate immunity by activating the immunosuppressive nuclear factor, peroxisome proliferator-activated receptors (PPARs) with type 2 cytokines and free fatty acids from arachidonic acid metabolism. PPARs limit the action of type 1 immunity, in which classically activated macrophages act through the production of proinflammatory signals, to spare the parasites. They also favor the development of alternately activated macrophages which control inflammation so the host would not be destroyed. Possibly, the nuclear factors hold a pivotal role in the establishment of chronic infection by delicately balancing the pro- and anti-inflammatory signaling mechanisms and their ligands may be used as combination therapeutics to limit host pathology.
1. Introduction
Infection is the outcome of a contest between a pathogen and its host. The host responds to an invasion by activation of inflammation and launching of innate and specific immunity. The goal is to eliminate the pathogen. On the other hand, the pathogen seeks to proliferate and spread to a new host when one is destroyed. The task of parasites is particularly challenging because they need to strike a balance between their own and the host's defense so they can continue to take advantage of the host to survive. It is well-known that parasites are mostly immunosuppressive; the mechanisms they use to penetrate immune defense may be unique or shared by many species. Among the many means of surviving host immunity, one that has recently emerged is the activation of PPAR. This strategy promotes parasite survival by increasing energy metabolism and suppressing inflammation to allow invasion and avoid host destruction. The goal of this article is to review our current knowledge on how activation of PPAR may affect the survival of parasites and their hosts.
2. Peroxisome Proliferator-Activated Receptors
PPARs are ligand-activated transcription factors of the nuclear hormone receptor superfamily that consists of over 48 transcription factors. There are three PPAR isoforms—PPARα, PPARβ/δ, and PPARγ also known as NR1C1, NR1C2, and NR1C3, respectively, and they differ in tissue distribution and function [1, 2]. PPARα is expressed in a variety of tissues involved in fatty acid oxidation, mainly the hepatocytes, cardiac myocytes, and proximal tubular epithelial cells of the kidney. It was so named because it was found to induce proliferation of peroxisomes in rodent livers (but not humans) when activated. Whereas PPARα has limited tissue expression, PPARβ/δ is expressed ubiquitously and plays an important role in energy homeostasis. PPARγ is a master regulator of adipocyte differentiation and is an important determinant of insulin sensitivity. Two subtypes are known in mice and four in humans [3, 4]. They are most highly expressed in adipose tissue, the colonic mucosal epithelium, and cells of the immune system.
Structurally, PPARs have a DNA-binding domain, a ligand-binding domain, two activation function sites, as well as sites for phosphorylation and dimerization (Figure 1) [2, 5, 6]. Activation is primarily ligand dependent and heterodimerization with the retinoid X receptor (RXR) is necessary. Figure 2 shows a simplified scheme of PPAR function in genomic expression and transrepression. Endogenous ligands for the PPARs include free fatty acids. Eicosanoids and 9-cis-retinoic acid bind to the PPAR-RXR complex to cause conformational changes that dissociate the corepressor, setting the complex free to interact genomically with the PPAR response element (PPRE), AGGTCANAGGTCA (two AGGTCAs separated by one nucleotide), located at the 5′ end of target genes (Figure 2(a)).
Figure 1.
Domain structure of PPARs. PPARs contain the following functional regions: a N-terminal domain with AF-1 domain (ligand-independent activation domain), a DNA binding domain (DBD) with two zinc fingers, a hinge region, and a C-terminal ligand binding domain (LBD) and AF-2 domain (ligand-dependent activation domain).
Figure 2.
General Schematics of PPAR function. General mechanisms of (a) genomic expression and (b) transrepression of gene expression by PPAR/RXR heterodimers. In (a), upon ligand binding PPAR associates with RXR and coactivator to turn on target genes via the PPAR response element (PPRE). In (b), blocking the dissociation of corepressor from transcription factor at the gene locus, association of transcription factor to PPAR/RXR by tethering, and association of coactivator with PPAR/RXR by squelching, inhibit the transcription of different genes. R = corepressors, filled circle = ligand, A = coactivators, TF = transcription factor. Su indicates modulation by small regulatory protein (sumoylation).
In contrast to genomic binding, PPARs also interact with other transcription factors through nongenomic trans-repression. In this process, they inhibit transcription by preventing dissociation of corepressors or sequestering the co-activators necessary for the binding of the transcription factor to DNA [7, 8]. Both PPARα and γ suppress inflammation and immunity by inhibiting the activation of major transcription factors that control the expression of cytokines. For example, PPARα can tether on to the nuclear factor-kappa B (NFκB) and prevent its transcription of interleukin-6 (IL-6); sumoylated PPARγ can bind nuclear receptor corepressor (NCoR)-histone deacetylase 3 (HDAC3) complex to prevent it from dissociating from NFκB and thus preventing the gene expression of inducible nitric oxide synthase (iNOS) (Figure 2(b)) [9].
3. Immune Defense against Parasitic Infections
Many parasitic infections are controlled by cell-mediated immunity. For host protection, controlling parasite growth relies on a type 1 response with activation of the classically activated macrophages (caMac, also known as M1), T helper-1 (Th1), Th17, the production of proinflammatory mediators, such as IL-1β, IL-6, tumor necrosis factor α (TNFα), IL-12, IL-23, IL-27, interferon γ (IFNγ), and generation of nitric oxide. On the contrary, a type 2 response with Th2 cells that produce IL-4 and IL-13 would render the host susceptible to infection. These cytokines activate PPARγ, which suppresses production of proinflammatory cytokines, are critical for the formation, activation, and maintenance of a subpopulation of macrophages, alternatively activated macrophages (aaMac, also referred to as M2) [10]. AaMac are found during parasitic infections and have been associated with downregulation of type 1 immunity as well as the survival of both protozoa and helminthes. This emerging subject of investigation has been reviewed recently by Reyes and Terrazas [11] and other investigators [12, 13]. AaMac not only inhibit T cell proliferation, but also promote resolution of inflammation and fibrogenesis. They actively express a set of genes enabling them to regulate anti-inflammatory processes, induce tolerance and wound healing. These anti-inflammatory regulatory mechanisms can act as a counterbalance to limit disease severity and protect the host from detrimental effects of an excessive type 1 response.
4. PPARs Regulate Immune Responses
Given the role of PPARs in metabolism and adipocyte differentiation, it is intriguing that lipid-activated transcription factors such as PPARs have a role in human immune cell regulation. Initial documentation of PPAR activation in the immune system occurred in 1994 [14]. PPARs were originally described in monocytes and macrophages, neutrophils and peripheral blood lymphocytes. They have since been reported to exist in other immune cell types of hematopoietic origin, including T lymphocytes, B lymphocytes, NK cells, dendritic cells, eosinophils, and mast cells. The extensive expression by many immune cell types suggests that this nuclear receptor may play a very important role in the regulation of immune responses [15–20].
Immune regulation through the activation of PPARs can occur in response to various long chain unsaturated fatty acids generated from the cyclooxygenase and lipoxygenase pathways [21]. The eicosanoid 15-deoxy-Delta12,14-prostaglandin J2 (15d-PGJ2) produced during arachidonic acid metabolism can activate PPARγ during inflammatory responses. Additional known ligands for include leukotriene B4, 8(S)-hydroxyecosatetraenoic acid (HETE), 15-HETE, and 13-hydroxyoctadecadienoic acid (13-HODE). Both 15-HETE and 13-HODE can be produced via the action of 12/15 lipoxygenase. Cytokines through induction of cyclooxygenase and lipoxygenase can regulate the expression and activity of PPARγ; for example, IL-4 induces 12/15 lipoxygenase and production of 15-HETE and 13-HODE whereas IL-13 enhances COX-2 expression and production of PGE2 and 15d-PGJ2 [22–24].
PPAR activation is generally known to result in an anti-inflammatory environment and may exert an effect on the immune response by an array of mechanisms [9, 25–28]. PPARα and γ exert anti-inflammatory activities through their ability to antagonize other signaling pathways, in part through the interaction with other transcription factors, including NFκB, activator protein-1 (AP-1), and signal transducers and activators of transcription (STATs). PPARγ agonists inhibit cell-mediated immunity by suppressing the production of inflammatory cytokines like TNFα, IL-6, IL-1β, and IL-12 [29]. They exhibit suppression on effector mechanisms of classically activated macrophage—inhibiting induction of inducible nitric oxide synthase (iNOS), matrix metalloproteinase-9 (MMP-9), and scavenger receptor A [17]. In mouse thioglycolate-elicited macrophages, PPARγ inhibits recruitment of macrophages to the sites of inflammation by repressing the transcription of monocyte chemoattractant protein-1 (MCP-1) and its receptor CC chemokine receptor 2 (CCR2) in macrophages [29].
With respect to T cells, PPARs affect activation and effector mechanisms via binding and blocking the action of nuclear factor of activated T cells (NFAT), a transcription factor. Specifically, 13-HODE, an endogenous PPARγ agonist, prevents NFAT association with the IL-2 promoter, thus inhibiting clonal T cell proliferation [20]. PPARα has also been shown to repress production of IFNγ and IL-17 by CD4+ T cells, and PPARγ ligands modulate dendritic cell function to elicit the development of anergic CD4+ T cells.
Whereas PPARs downregulate type 1 immunity they upregulate type 2 responses. A study by Dasgupta et al. [30] showed that gemfibrozil, a PPARα agonist, increases the activity of the transcription factor GATA-3 and inhibits expression of the transcription factor T-box expressed in T cells (T-bet) to cause increase in IL-4 production by Th2 cells. In a positive feedback manner, IL-4 has also been shown to simultaneously increase the expression of PPARγ and 12,15-lipooxygenase, the enzyme involved in the generation of 13-HODE [22].
5. Activation of PPARs in Parasitic Infections
By rendering the host less capable of an inflammatory burst, PPAR activation might favor the establishment of a chronic parasitic infection, making symbiotic survival between host and parasite more likely. Plasmodium falciparum and Schistosoma mansoni infection produce hemozoin, which induces the release of endogenous ligands lipoxin A4 (LXA4), 5,15-diHETE, and 15-HETE, that can activate PPAR. Production of IL-4 and IL-13 in Leishmania and Toxoplasma infections also favors the activation of aaMac whose development is dependent on PPARγ.
5.1. Hemozoin
The Plasmodium protozoa are parasites that cause malaria. During disease pathogenesis, rapid growth of merozoites within red blood cells leads to host cell rupture and as the disease progresses, reinvasion of released parasites heigthens parasitemia. As red blood cells and hemoglobin are destroyed, the malaria parasite produces hemozoin, a molecule formed via heme-catalyzed lipoperoxidation as a detoxification product and released together with other cell debris [31].
Plasmodium hemozoin reacts with membrane phospholipids to generate hydroxy-polyunsaturated fatty acids, which are ligands of PPARγ. The fact that hemozoin activity is dependent on PPARγ has been demonstrated with the PPAR agonist ciglitizone, the antagonist GW9662, and the PPARγ ligand 15-HETE. Hemozoin has long been known to be a potent modifier of myeloid cells. It modulates phagocytosis, activation by inflammatory cytokines, and generation of the oxidative burst in monocytes. It also inhibits granulocyte-macrophage colony stimulating factor (GM-CSF) and IL-4-mediated differentiation of human monocytes into immature dendritic cells. Furthermore, hemozoin-loaded immature dendritic cells are also unable to differentiate into mature dendritic cells. In these cells, the PPARγ mRNA level increases, whereas the expression of MHC class II, costimulatory molecules CD83, CD80, CD54, CD40, CD1a, and CD83-specific mRNA are lowered [32, 33].
In addition to Plasmodium, the metazoan parasite Schistosoma mansoni, commonly known as blood fluke, also produces hemozoin. The adults of this snail-transmitted parasite feed on red blood cells in humans during part of its life cycle and biomineralizes dimeric heme into an inert crystalline pigment that is structurally identical to Plasmodium falciparum hemozoin. The lipid coat of native schistosome hemozoin is a complex mixture of both neutral lipids and polyunsaturated fatty acids. It can generate, by nonenzymatic catalysis, large amounts of lipoperoxidation products, such as monohydroxy derivatives of arachidonic (HETE) and linoleic (HODE) acid and 4-hydroxynonenal (HNE), which are natural ligands of PPAR. Murine RAW 264.7 macrophage-like cells that have phagocytized schistosomal hemozoin are also decreased in lipopolysaccharide-stimulated nitric oxide production [34–36].
Interestingly, the kissing bug Rhodnius prolixus, which is the vector for Trypanosoma cruzi, the etiological agent of Chagas' disease, also crystallizes heme into a dark brown pigment. Since this insect feeds on blood meal, a link may be extrapolated between blood-feeding and hemozoin formation. Production of this PPAR activating molecule can be a strategy commonly acquired by blood feeding parasites and blood taking vectors to suppress host immune response [37].
5.2. Polyunsaturated Fatty Acids (PUFA)
The protozoan Toxoplasma gondii infects feline epithelium and grows intracellularly in different mammalian nucleated cells, but it does not feed on or destroy red blood cells and does not produce hemozoin. However, it induces the production of natural ligands for PPAR from platelets. Infection induces platelets to release LXA4, 5,15-diHETE, and 15-HETE at very high levels, two orders of magnitude greater than those used to resolve inflammation [38]. Toxoplasmosis is a chronic disease that is contained by immunity. The disease is only manifested in severely immunocompromised individuals and detrimental to fetus in early gestation. Henderson Jr. and Chi [39] have reported that other PPAR activating lipids, for example, 13-HODE at 10 nanomole concentration has cytotoxicity against the parasite (however, 12-HETE at 1 μM does not). Currently, the role of PPARγ in toxoplasmosis remains to be elucidated. However, it is possible for it to have a role in maintaining a balance that supports host and parasite in dormant, chronic infections.
5.3. Interleukin-4
The pivotal role of PPARγ on IL-4 and aaMac-mediated susceptibility has been demonstrated in Leishmania pathogenesis. Leishmaniasis is transmitted by the sandfly vector carrying parasitic protozoa of the genus Leishmania. Clinically the disease can be manifested in three major types, cutaneous, mucocutaneous, and visceral, each caused by different species of the protozoan genus. In the murine model of the cutaneous infection, BALB/c mice, the Leishmania major susceptible strains, have a T helper 2 (Th2) response whereas the C57BL/6 mice, resistant strains, have a T helper-1 (Th1) response [40]. AaMacs are found in all Th2 cytokine environments. Interestingly, BALB/c mice are more supportive of aaMac maturation than C57BL/6 mice, which are resistant to leishmaniasis [41].
PPARγ expression is strongly associated with maturation of aaMac. Our laboratory investigated visceral leishmaniasis and found that Leishmania donovani induces PPARγ expression in residential macrophages, liver and spleen of BALB/c mice. In addition, oral administration of the PPARγ agonist, curcumin further increases PPARα and PPARγ expression, and the increase is associated with a heavier parasite burden (Figure 3) [42].
Figure 3.
PPAR-mediating suppression of parasiticidal response in leishmaniasis. The sandfly vector carries leishmanial promastigotes to the mammalian host. The parasites then transform into amastigotes within phagolysosomes of host macrophages. Type 1 immunity, with T helper 1 (Th1) releasing interferon γ (IFNγ), leads to classically activated macrophages (caMac). CaMac produce nitric oxide from inducible nitric oxide synthase (iNOS), interleukin-1 (IL-1), tumor necrosis factor (TNF), and reactive oxygen and nitrogen intermediates (ROI, RNI) that act to eliminate the amastigotes. Type 2 immunity, with Th2 releasing IL-4, leads to activation of peroxisome proliferator-activated receptor (PPAR) and alternatively activated macrophages (aaMac). AaMac produce arginase, IL-10, transforming growth factor β (TGFβ), and PPAR that allow amastigote propagation. PPAR agonists (GW7845 and GW0742) and some phytochemicals (curcumin) can activate PPAR and promote aaMac maturation. Activation of PPAR allows parasite survival as a chronic parasitic infection.
Consistent with our findings, cutaneous Leishmania infection is less severe in mice whose PPARγ gene has been knocked out in their macrophages (Mac-PPAR KO). Mac-PPAR KO mice had significantly less footpad swelling 5–7 weeks after injection of L. major promastigotes. Lesions in Mac-PPAR KO started to stabilize after 7 weeks, but the footpads of wild type mice continued to enlarge and rapidly underwent necrosis. The loss of PPARγ is associated with loss of aaMac, as cells that express their phenotypic marker, arginase I, are decreased. The production of nitric oxide and IL-6, correspondingly, is increased as well [41].
PPARγ and PPARδ regulate expression of the arginase I gene, a key marker, in aaMac. The PPARγ agonist GW7845 and PPARδ agonist GW0742 activate arginase in murine macrophages, and this activation only occurs in wild type macrophages that have PPARγ or PPARδ, but not in cells where either of their genes has been knocked out [43]. Arginase decreases the amount of arginine, the substrate for NOS to produce nitric oxide. Since intracellular killing of amastigotes requires nitric oxide, both cutaneous and visceral infections are unrestrained in iNOS knockout mice [44–46].
5.4. Interleukin-13
IL-13, another Th2 cytokine that shares a common receptor chain with IL-4, exerts similar effects on macrophages [13]. Functionally, it inhibits the activation of caMac and the production of Th1 cytokines and reactive nitrogen species. The effect of IL-13 is also mediated via the PPARγ pathway. In Toxoplasma-infected macrophages, IL-13 activates PPAR by inducing the production of 15d-PGJ2. Exogenous addition of PPARγ agonists, rosiglitazone or 15d-PGJ2, mimics IL-13 in that it induces CD36, the scavenger receptor whose transcription is turned on by PPARγ [47]. This effect can be further extended to aaMac; IL-13−/− mice are incapable of generating cells that express the aaMac phenotype (chitinase-like lectin YM1 or CD20) [48]. CD36 is classified as a class 2 scavenger receptor [49–51]. It is present on the cell surface of many cell types, including monocytes and macrophages. The molecule recognizes oxidized low density lipoprotein (LDL), oxidized phospholipids and lipoproteins, apoptotic cells, and microbial pathogens. With respect to parasites, Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP-1), commonly found in the schizont stage, ring stage and early gametocytes (stage I and IIA), serves as a ligand for CD36. Binding to CD36 is necessary for phagocytosis of P. falciparum-parasitized erythrocytes by human and rodent monocytes/macrophages [52–57]. The function of PPARγ in CD36-mediated phagocytosis is illustrated by the fact that IL-13-induced clearance of the parasitized erythrocytes is blocked by anti-CD36 and GW9662, a PPARγ antagonist [47]. The activity, however, is enhanced by the agonists 15d-PGJ2 and ciglitazone [52]. The role of PPARγ in CD36-medited phagocytosis is also confirmed by the observations that mice treated with rosiglitazone have reduced parasitemia of Plasmodium chabaudi, whereas this reduction is not seen in CD36 knockout animals [57]. CD36-mediated phagocytosis will facilitate removal of neutrophils and dead tissues to resolve inflammation as well as clearing of the parasite [52]. Consistent with this concept that PPAR and aaMac resolve inflammation, Herbert et al. [58] reported that in the absence of IL-4/IL-13-induced aaMac, mice with their macrophage-specific IL-4 receptor knockout (LysMCreIL-4R−/flox ) die of schistosomiasis. The mutant mice have increased Th1 cytokines and nitric oxide, hepatic and intestinal histopathology due to lack of aaMac to protect against tissue injury. Correspondingly, BALB/c mice with their T helper-1 responses and immunopathology down-modulated by aaMac survive Schisotsoma mansoni infection better [59].
Henceforth, in sum, studies have revealed that PPARγ suppresses immune reaction to parasitic infection; however, it also plays a role, perhaps through a CD36-dependent manner, in reducing parasitemia as well as resolving inflammation.
6. Effect of Pharmacological PPAR Ligands on Parasitic Infections
The anti-inflammatory actions of PPARγ have received great attention because of the availability of synthetic PPARγ activator molecules and their clinical use. The FDA has approved several synthetic PPAR ligands as therapeutic drugs [59, 61]. For example, clofibrate, an agonist of PPARα, and its related compounds are used for the treatment of dyslipidemia. Rosiglitazone (drug name Avandia) and pioglitazone (drug name Actos), agonists of PPARγ, are used in the management of type 2 diabetes. The drugs improve insulin sensitivity by controlling metabolic and endocrine functions of the adipose tissue. PPARs are attractive drug targets for energy homeostasis and control of lipid and glucose metabolism, as well as possible body weight control. Dual agonists of PPARs have been sought, even though troglitazone and muraglitazar (dual agonist for PPARα/γ), originally approved by FDA were later withdrawn due to liver toxicity and increased cardiovascular risks, respectively [62, 63]. PPARγ remains a promising target; safer therapeutics may still become a reality in the future.
Potentially, PPAR ligands may be used in parasitic diseases. To date, in experimental models PPAR ligands have been shown to alleviate host tissue destruction by immune response, as seen in malaria and schistosomiasis. Recently, Lena Serghides and colleagues have shown that rosiglitazone, the PPARγ agonist, is useful in alleviating cerebral malaria in a murine model [57]. Among the variety of symptoms of malaria, cerebral malaria is the deadliest complication that affects an estimated total of 785,000 children in Africa each year. Acutely manifested, the Plasmodium falciparum parasites induce fever, changes in mental status, and coma. The sequestration of parasitized red blood cells (PRBCs) and non-PRBCs in the cerebral capillaries and venules reduces microvascular blood flow and induces hypoxia in the brain. Furthermore, the parasites stimulate the host macrophages to release TNFα, IL-1, and uncontrolled production of nitric oxide, which diffuses through the blood-brain barrier and acts on synaptic function, leading to a state of reduced consciousness. Cotreatment of rosiglitazone (50 mg/kg of chow) with Plasmodium berghei-parasitized erythrocytes to susceptible mice leads to animal survival.
Similarly, PPAR ligands may be useful in human schistosomiasis, a chronic infection that can cause liver fibrosis. In a murine experimental model of hepatic fibrosis induced by Schistosoma japonicum, Chen and colleagues [60] reported that coadministration of rosiglitazone (4 mg/kg), daily for 6 weeks (at 4 weeks after infection) with the antischistosomal drug praziquantel (500 mg/kg) alleviates the symptoms of liver fibrosis. This was demonstrated by a decrease of fibrosis markers, type I and III collagen, and smooth muscle α actin. The decrease in fibrosis is accompanied by reduced binding activity of the transcription factor NFκB and lowered levels of TNFα and IL-6 in the serum. Like cerebral malaria data, these findings also suggest that the PPARγ ligand rosiglitazone may be clinically useful for treatment of liver fibrosis due to schistosomal infection.
7. Conclusion and Future Prospects
In conclusion, to date, the role of PPARγ in parasitic diseases remains largely unexplored. Recent evidence suggests that PPARγ activation may increase replication of parasites as well as maintain survival of the host (Table 1). Perhaps it is a measure by which a chronic infection can be established. In a strong cell-mediated immunity, a typical type 1 immune response induces the production of TNFα, IFNγ, and nitric oxide which eliminates parasites. However, the host will severely suffer from tissue destruction during this process, as can be seen in cerebral malaria, when the children may be comatose, and in late stages of visceral leishmaniasis, when the patients may be cachexic and their liver and spleen are enlarged. A type 2 response with IL-4 and IL-13 which induces immunosuppressive PPARs would allow the parasites to infect, but spare the host of devastating tissue destruction. In leishmaniasis, for example, activation of PPARγ by curcumin suppresses IFNγ and nitric oxide production and increases parasite burden. It may be of interest that curcumin is prevalently used for medicine, cosmetics, and cooking in India, where visceral leishmaniasis is endemic. Perhaps, through PPARγ the host can resolve inflammation and repair tissues to strive for a balance between the host and the parasite that favors mutual survival.
Table 1.
Effect of PPAR modulation on the outcome of parasitic infections.
| Parasite | Animal model | Treatment | PPAR status | Outcome | Reference |
|---|---|---|---|---|---|
| Increase in parasite load | |||||
| Leishmania major | Murine cutaneous leishmaniasis | Gene knockout | PPARγ−/− macrophages | Decreased footpad swelling | [41] |
| Leishmania donovani | Murine visceral leishmaniasis | Curcumin | PPARγ ↑ PPARα ↑ | Increased parasite load | [42] |
| Decrease in host tissue damage | |||||
| Schistosoma japonicum | Murine hepatic fibrosis | Rosiglitazone (Praziquantel) | PPARγ ↑ | Decreased fibrosis | [60] |
| Plasmodium berghei | Murine cerebral malaria | Rosiglitazone | Not stated | Increased survival | [57] |
| Plasmodium chabaudi | Murine malaria | Rosiglitazone | Not stated | Decreased parasitemia | [57] |
Acknowledgments
Marion Chan was funded by NIH Grant R01AI45555, R21AR051761 and American Institute for Cancer Research. Kyle W. Evans received stipends from NIH Grant T32AI07101 and Pennsylvania Department of Health (Tobacco Settlement Formula Fund). Dunne Fong was supported by funding from the Department of Defense. We also thank Ms. Grace P. Fong for illustration and graphics.
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