Heme Binding Contributes to Antimalarial Activity of Bis-Quaternary Ammoniums

Quaternary ammonium compounds have received recent attentiondue to their potent in vivo antimalarial activity based on theirability to inhibit de novo phosphatidylcholine synthesis. Herewe show that in addition to this, heme binding significantlycontributes to the antimalarial activity of these compounds.For the study, we used a recently synthesized bis-quaternaryammonium compound, T16 (1,12-dodecanemethylene bis[4-methyl-5-ethylthiazolium]diodide), which exhibits potent antimalarial activity (50% inhibitoryconcentration, $~$ 25 nM). Accumulation assays reveal that thiscompound is readily concentrated several hundredfold (cellularaccumulation ratio, $~$ 500) into parasitized erythrocytes. Approximately80% of the drug was shown to be distributed within the parasite, $~$ 50% of which was located in the parasite food vacuoles. T16uptake was affected by anion substitution (permeation increasingin the order Cl^- < Br^- = NO₃^- < I^- < SCN^-) and wassensitive to furosemide—properties similar to substratesof the induced new permeability pathway in infected erythrocytes.Scatchard plot analysis of in situ T16 binding revealed high-affinityand low-affinity binding sites. The high-affinity binding siteK_d was similar to that measured in vitro for T16 and ferriprotoporphyrinIX (FPIX) binding. Significantly, the capacity but not the K_dof the high-affinity binding site was decreased by reducingthe concentration of parasite FPIX. Decreasing the parasiteFPIX pool also caused a marked antagonism of T16 antimalarialactivity. In addition, T16 was also observed to associate withparasite hemozoin. Binding of T16 to FPIX in the digestive foodvacuole is shown to be critical for drug accumulation and antimalarialactivity. These data provide additional new mechanisms of antimalarialactivity for this promising new class of antimalarial compounds.

INTRODUCTION

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Introduction

Worldwide resistance to traditional antimalarial drugs suchas chloroquine and pyrimethamine sulfadoxine raises the urgencyfor the development of new drugs aimed at new drug targets (18).Inhibition of phosphatidylcholine synthesis—which leadsto the inhibition of membrane biogenesis during the asexualintraerythrocytic stage of the human malaria parasite Plasmodiumfalciparum—has recently attracted attention as a potentiallynew chemotherapeutic target (18, 26). Over recent years, numerous(>600) compounds have been rationally synthesized to mimiccholine structure. The resulting compounds from these structure-activitystudies are quaternary and bis-quaternary ammoniums with leadcompounds that exert potent (i.e., low nM) in vitro activityagainst P. falciparum and P. vivax (2, 5, 6, 26) as well asgood in vivo activity against P. falciparum and P. cynomolgiin aotus and rhesus monkeys, respectively (26).

Biochemical investigations show that in P. knowlesi, the protein-mediatedtransport of choline into the infected erythrocyte is a rate-limitingstep for phosphatidylcholine synthesis (1). In this malariaparasite, the in vitro and in vivo activity exerted by the quaternaryand bis-quaternary ammonium compounds can be directly correlatedto a reduction in the transport of choline and subsequent reductionof phospholipid metabolism (1, 2). However, questions concerningthe mechanism of entry of these drugs into infected erythrocyteshave not been addressed. Based on kinetic and pharmacologicalinhibitor profiles of isosmotic hemolysis and radiolabel fluxexperiments, several quaternary ammonium compounds have beendemonstrated to permeate P. falciparum-infected erythrocytesvia the parasite-induced new permeation pathway (NPP [11, 22]).Similarly, diamidine compounds, which—being highly chargedand hydrophilic—are structurally comparable to the bis-quaternaryammonium compounds, have also been demonstrated to enter thehost erythrocyte via the NPP (23). In this study, we have investigatedthe mechanism of entry and antimalarial activity of a newlysynthesized bis-quaternary ammonium compound, T16 (1,12-dodecanemethylenebis[4-methyl-5-ethylthiazolium] diodide; Fig. 1), which exhibitspotent in vitro activity (50% inhibitory concentration [IC₅₀], $~$ 25 nM). Here we show that T16 is a substrate for the NPP, resultingin T16's entry into infected red blood cells. Subsequently,accumulation of T16 occurs in the parasite and in the digestivefood vacuole. Binding of T16 to ferriprotoporphyrin IX (FPIX)(10) in the digestive food vacuole is shown to be critical fordrug accumulation and antimalarial activity. These data providenew mechanisms of antimalarial activity for this promising newclass of antimalarial compounds.

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FIG. 1. Chemical structure of T16 (1,12-dodecanemethylene bis[4-methyl-5-ethylthiazolium] diodide) and [³H]T16.

MATERIALS AND METHODS

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Materials and Methods

Reagents. T16 and [³H]T16 were synthesized in house. Ro 40-4388 was kindlyprovided by R. G. Ridley and R. Moon of Hoffman LaRoche. [³H]hypoxanthinewas purchased from Amersham. Tissue solubilizer was purchasedfrom BDH. All other reagents were purchased from Sigma-AldrichChemical Company.

Parasite, culture, and drug sensitivity assays. P. falciparum strain TM6 (chloroquine resistant, IC₅₀ $>=$ 100 nM), was obtained from P. Tan-Ariya (Mahidol University,Bangkok, Thailand) and maintained in continuous culture. Culturescontained a 2% suspension of O⁺ erythrocytes in RPMI 1640 medium(R8758, glutamine, and NaHCO₃) supplemented with 10% pooledhuman AB⁺ serum, 25 mM HEPES (pH 7.4), and 20 µM gentamicinsulfate (25). Radiolabel uptake experiments were performed onmature trophozoites synchronized by treatment with sorbitol(15). The sensitivity of P. falciparum-infected erythrocytesto T16 was determined by using the [³H]hypoxanthine incorporationmethod (8) with an inoculum size of 0.5% parasitemia (ring stage)and 1% hematocrit. IC₅₀s were calculated by using the four-parameterlogistic method (Grafit program; Erithacus Software, Surrey,United Kingdom). The effect of the combination of T16 and Ro40-4388 on parasite growth was tested by titration of the twodrugs at fixed ratios proportional to their IC₅₀s. The fractionalinhibitory concentrations of the resulting IC₅₀s were plottedas isobolograms (3).

Uptake of [³H]T16 into uninfected and parasitized erythrocytes. Uninfected erythrocytes or erythrocytes infected with synchronizedcultures of P. falciparum were suspended (typically [3 to 5]x 10⁸ cells ml^-1) in HEPES (25 mM, pH 7.4)-buffered RPMI 1640medium containing 50 nM [³H]T16 (specific activity, 69 Ci mmol^-1).At specific time intervals, aliquots of the suspension wereoverlaid onto oil (400 µl of dibutyl phthalate) in a microcentrifugetube and centrifuged at 10,000 x g for 20 s, thereby sedimentingthe cells below the oil. Cell pellets were lysed by the additionof distilled water (100 µl) and then solubilized and decolorizedby the addition of a cocktail (100 µl) containing fiveparts tissue solubilizer, two parts H₂O₂ (30%), and two partsglacial acetic acid. Samples were then counted by liquid scintillationcounting. T16 binding affinity was measured after 2 h in 25mM HEPES-buffered RPMI 1640 medium (pH 7.4) containing 50 nM[³H]T16 and various concentrations of unlabeled T16, in thepresence or absence of Ro 40-4388.

Specific uptake of [³H]T16 into infected erythrocytes was calculatedby subtracting the counts attributable to an equal number ofuninfected erythrocytes. The cellular accumulation ratio (CAR)is defined here as the ratio of the amount of [³H]T16 in infectederythrocytes to the amount of [³H]T16 in the same volume ofthe suspending solution after incubation. The volumes of infectedand uninfected erythrocytes were assumed to be equal (75 fl[20]). The intracellular drug concentration was calculated bymultiplying the CAR by the suspending solution drug concentrationafter incubation.

A number of compounds were tested for their ability to inhibit[³H]T16 uptake. These included choline, Ro 40-4388, furosemide,phloredzin, and niflumate. All compounds were preincubated withinfected and noninfected erythrocytes for 5 min prior to incubation(1 h) with [³H]T16. Control samples were treated with dimethylsulfoxide when appropriate. To determine the effect of anionsubstitution on [³H]T16 uptake, cells were suspended in theappropriate solutions (i.e., the same buffers as those usedby Kirk and Horner [14]) for 10 min, and uptake was measuredas described above.

Uptake of [³H]T16 into infected erythrocytes and its distribution into trophozoites and food vacuoles. Uninfected and P. falciparum-infected (4 to 10% parasitemia)erythrocytes (typically [5 to 9] x 10⁸ cells ml^-1) suspendedin HEPES-buffered RPMI 1640 medium (25 mM, pH 7.4) were incubatedwith 25 nM [³H]T16 (specific activity, 69 Ci mmol^-1) for 1 h.Uninfected erythrocytes and an aliquot of the infected erythrocyteswere overlaid onto oil (400 µl of dibutyl phthalate) andcentrifuged at 10,000 x g for 20 s. The cell pellets were thenprocessed, and the radioactivity was determined as describedabove. Preparation of free parasites, from an aliquot of infectederythrocytes, was performed by centrifugation (3,000 x g, 5min) and resuspension of the pellet in 5 vol of 0.15% (wt/vol)saponin in phosphate-buffered saline (PBS) for 1 min, followedby three washes by centrifugation and resuspension in HEPES-bufferedRPMI 1640 medium. An aliquot of this preparation containingthe free parasites was overlaid onto oil (a 5:4 mixture of dibutylphthalate-dioctyl phthalate) and centrifuged (10,000 x g, 20s). The pellet of free parasites was then processed, and theradioactivity was measured as described above. Preparation offood vacuoles from an aliquot of free parasites was performedbased on the method of Saliba et al. (19). Free parasites werehypotonically lysed by the addition of 10 vol of H₂O in thepresence of DNase 1 (10 µg ml^-1) and triturated four timesthrough a 27-gauge 1.2-cm needle. The food vacuoles were thenwashed by centrifugation in HEPES-buffered RPMI 1640 mediumand overlaid onto a cushion (1 ml) of 0.85 M sucrose and centrifugedat 10,000 x g for 10 min. The pellet was then processed, andthe radioactivity was measured as described above.

UV and visible spectral scans. FPIX or protoporphyrin IX (PIX) solutions (3 mM) in 0.1 M NaOHwere prepared on the day of experimentation. Before scanning,samples were diluted (3 µM) in 0.2 M HEPES (pH 7.0) inthe presence and absence of 3 µM T16. Samples were scannedagainst the appropriate blank control in a Hewlett-Packard 8452Adiode array spectrophotometer (Palo Alto, Calif.).

Determination of binding affinity (K_d) of T16 for FPIX-loaded ghost membranes. The binding affinity of [³H]T16 to FPIX-loaded ghost erythrocyticmembrane (12) was measured as described previously for [³H]chloroquine(4).

Binding and incorporation of [³H]T16 to FPIX and hemozoin crystal. In order to determine whether T16 could bind or be incorporatedinto hemozoin crystal (ß-hematin), T16 was incubatedwith FPIX-loaded ghost erythrocyte membrane in conditions thatpermitted hemozoin formation (4). For this experiment, erythrocyteghost membrane (100 µl [12]) and FPIX (100 µl ofa 3 mM solution in 0.1 M NaOH) were mixed with an aliquot (10µl) of 1 M HCl and made up to a final volume of 0.9 mlwith 0.5 mM Na acetate (pH 5.2). [³H]T16 (in distilled water)was then added (100 µl) to this assay mixture, givinga final [³H]T16 concentration of 50 nM. Controls were made withoutFPIX and/or without erythrocyte ghost membrane. Samples werewell mixed and incubated at 37°C for 48 h. Following incubation,the samples were pelleted by centrifugation (14,000 x g, 10min) and resuspended in 1 ml of 0.2 M sucrose. These suspensionswere then applied to a discontinuous sucrose gradient composedof five cushions (1 ml each) of 0.2, 0.8, 1.2, 1.6, and 2.0M sucrose. After centrifugation (100,000 x g for 1 h), the phaseswere collected separately and processed for radioactive countingas described above. Previous experiments had established thathemozoin crystals but not FPIX sediments to the 2.0 M fraction.

In situ binding of [³H]T16 to hemozoin. Synchronized P. falciparum-infected erythrocytes at the trophozoitestage were incubated for 2 h at 37°C in the presence of50 nM of [³H]T16. After incubation, cells were washed once inPBS and were saponin treated by incubation at a hematocrit of10% for 5 min at 4°C in PBS containing 0.06% (wt/vol) saponin.After centrifugation at 4,000 x g for 10 min, the pellet waswashed twice in PBS and the free parasites were resuspendedin 1 ml of 0.2 M sucrose and sonicated in a probe type sonicator(Vibra Cell, Bioblock Scientific) for 30 s at 4°C. The suspensionwas then overlaid onto discontinuous sucrose gradients, ultracentrifuged,and treated as described above for radioactive counting.

RESULTS

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Results

T16 is a NPP substrate that selectively accumulates in the malaria parasite and is distributed in the digestive food vacuole. The uptake of [³H]T16 into uninfected and infected erythrocytessuspended in HEPES-buffered RPMI 1640 solution (pH 7.4) wasmonitored over several hours. Uninfected erythrocytes were observedto accumulate relatively low levels of T16 (CAR < 2; Fig.2); in contrast, P. falciparum-infected erythrocytes showedhigh levels of accumulation. At equilibrium, the level of T16in infected erythrocytes was approximately 500 times that ofthe surrounding suspension (Fig. 2). Measurement of [³H]T16distribution into parasitized erythrocytes after a 1-h incubationperiod revealed that the fraction accumulated by the intracellularparasite accounted for 77% ± 10% (n = 3) of the totaluptake. Further analysis revealed that 40% ± 3% (n =3) of the total uptake ( $~$ 50% of the parasite-specific uptake)was localized in the parasite's food vacuoles.

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FIG. 2. Time course of 50 nM [³H]T16 uptake into uninfected (•) and P. falciparum-infected ( ${circ}$ ) erythrocytes suspended in HEPES-buffered RPMI 1640 medium (pH 7.4). Data are the means ± standard error of three independent experiments.

The uptake of [³H]T16 into infected erythrocytes was observedto be inhibited by furosemide, phloredzin, and niflumate (Table1) —known inhibitors of the parasite-induced NPP (13).Uptake of [³H]T16 into infected erythrocytes also showed a markeddependence on the nature of the counterion present in solution,increasing in the order Cl^- < Br^- = NO₃^- < I^- < SCN^-(Fig. 3), a physiological property characteristic of the transportof cations through the NPP (13, 14).

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TABLE 1. Effect of inhibitors on [³H]T16 uptake in P. falciparum-infected erythrocytes

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FIG. 3. Effect of anion substitution from the suspending solution on the uptake (increase relative to chloride [n-fold]) of 50 nM [³H]T16 into P. falciparum-infected erythrocytes. Data represent the means ± standard error of three independent experiments.

T16 binds to FPIX. The total binding of [³H]T16 to infected erythrocytes plottedon a Scatchard plot is shown in Fig. 4. This biphasic curveis indicative of at least two binding sites—one of highaffinity and one of low affinity. Nonlinear-regression analysisof the high-affinity binding site reveals a K_d for T16 of 0.73± 0.26 µM (standard error [SE]; n = 5).

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FIG. 4. Scatchard plot of the total binding of [³H]T16 onto P. falciparum-infected erythrocytes. Shown is a single representative plot from five similar experiments. The curved line suggests the presence of at least two components—a high-affinity T16 binding site and a low-affinity T16 binding site.

FPIX, which is continuously generated by the intraerythrocyticmalaria parasite during hemoglobin digestion, is known to bea receptor to several cationic aromatic antimalarial drugs,such as chloroquine (4) and the diamidines (23). We thereforeinvestigated whether FPIX was the high-affinity receptor forT16 binding. T16 was shown in vitro to bind to a molar equivalentof FPIX, thus producing a marked increase in the Soret peakof FPIX (Fig. 5A). In addition, a small blueshift in the spectralprofile of PIX in the presence of equimolar T16 (Fig. 5B) wasalso observed.

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FIG. 5. UV and visible spectral scans of (A) 3 µM FPIX ( ${lambda}$ _max, 395 nm in aqueous HEPES [pH 7.0]) and (B) 3 µM PIX ( ${lambda}$ _max, 410 nm in aqueous HEPES [pH 7.0]) in the presence (dashed line) or absence (solid line) of 3 µM T16. Data are representative of three independent experiments.

Binding of [³H]T16 to FPIX was also measured in FPIX-loadederythrocyte ghost membranes. Binding isotherms revealed thatthe T16 radioligand bound to FPIX with an affinity (K_d) valueof 2 µM (Fig. 6). This value is similar to that obtainedfor the high-affinity in situ binding (K_d, 0.7 µM), suggestingthat FPIX is an intracellular high-affinity receptor for T16.

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FIG. 6. Nonlinear-regression analysis of [³H]T16 binding to FPIX-loaded ghost erythrocyte membrane. Data points are from two independent experiments performed in triplicate.

Further confirmation was provided with the use of the plasmepsinI inhibitor Ro 40-4388 (16). This inhibitor prevents hemoglobindigestion by the parasite, thereby reducing the amount of freeFPIX (4). We were able to show that [³H]T16 uptake is inhibitedby 10 µM Ro 40-4388 (Table 1). Treatment of infected erythrocyteswith Ro 40-4388 would have had the consequence of reducing thenumber of binding sites available to T16 (by reducing the amountof free FPIX [4]) without affecting the affinity of the T16-FPIXbinding. Scatchard plots of the high-affinity binding in thepresence of Ro 40-4388 do indeed show this (Fig. 7), therebyconfirming that FPIX is critical for driving T16 accumulation.

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FIG. 7. Scatchard plot of the high-affinity binding of [³H]T16 to P. falciparum-infected erythrocytes in the presence (•) and absence ( ${circ}$ ) of 10 µM Ro 40-4388. Data points are means of duplicate observations from three separate experiments.

Binding of T16 to FPIX is critical for antimalarial activity. Reducing the parasite FPIX pool also had an effect on the antimalarialactivity of T16. This is indicated in the isobole analysis experimentsshown in Fig. 8, in which the reduction of the FPIX pool byuse of the protease inhibitor Ro 40-4388 resulted in a markedantagonism of T16 activity.

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FIG. 8. Isobole plot of T16 in vitro antimalarial activity in combination with Ro 40-4388.

In vitro and in situ interaction of [³H]T16 with hemozoin. Hemozoin was grown in vitro in the presence of [³H]T16 and thereafterseparated by a discontinuous sucrose gradient. Analysis of thesucrose fractions revealed that 55% of [³H]T16 was recoveredfrom the 0.2 M fraction (Fig. 9A). Control experiments (withoutFPIX and/or erythrocyte ghost membrane—see Materials andMethods) revealed that this fraction contains free [³H]T16 and(solubilized) FPIX-associated [³H]T16. The remaining (45%) [³H]T16was recovered from the 2.0 M sucrose fraction containing thehemozoin-associated [³H]T16 (Fig. 9A). These data indicatedthat T16 can readily interact in vitro with the growing hemozoincrystals. In order to determine whether [³H]T16 interacts withhemozoin crystals in situ, an enriched (saponin freed) trophozoitesuspension was incubated with [³H]T16 (2 h) and subsequentlysonicated and separated by discontinuous sucrose gradients.Analysis of the sucrose fractions indicated that 35% of therecovered [³H]T16 was associated with hemozoin (localized inthe 2.0 M fraction, Fig. 9B). A further 35% [³H]T16 was recoveredin the 0.2 M fraction, signifying free T16 and FPIX-associatedT16. In addition, 20% of the recovered [³H]T16 was localizedin the 0.8 M fraction, which may reflect protein-associatedT16. Together, these data show that in addition to binding toFPIX, T16 is also able to interact with hemozoin and/or withthe hemozoin formation process.

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FIG. 9. (A) Binding of [³H]T16 to FPIX and hemozoin in vitro and subsequent separation by discontinuous sucrose gradient. (B) Binding of [³H]T16 to freed (saponin treated) Plasmodium falciparum trophozoites and subsequent separation by discontinuous sucrose gradient. Control experiments indicate that free [³H]T16 and [³H]T16-FPIX complexes were restricted to the 0.2 M fraction and that [³H]T16-hemozoin complexes were restricted to the 2 M fraction.

DISCUSSION

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Discussion

In this study we have described the transport, accumulation,and antimalarial activity of a novel bis-quaternary ammoniumcompound, T16. We have shown that this compound does not accumulateexcessively in uninfected erythrocytes (CAR, $~$ 2; Fig. 2), whereasaccumulation in P. falciparum-infected erythrocytes is veryhigh (CAR, $~$ 500; Fig. 2)—probably accounting for the observedpotent (low nM) antimalarial activity.

Transport of T16 through the host's erythrocyte plasma membraneis facilitated by passage via the parasite-induced NPP. Thisargument is supported by the partial inhibition of [³H]T16 uptakeby the NPP inhibitors—furosemide, phloredzin and niflumate(Table 1)—as well as the observed stimulation of uptakeby substitution of the counteranion in the bathing solution(Fig. 3). The NPP has been shown to favor the passage of low-molecular-weightanions (13) and has been characterized by patch clamp analysisas an inwardly rectified anion channel (7). Nevertheless, itis not unprecedented that a positively charged drug such asT16 could be transported through the NPP. Small cations (e.g.,K⁺, Na⁺, Rb⁺, choline⁺, and carnithine⁺ [13]) as well as largercations (e.g., pentamidine [23] and tetrapentyl ammonium [22])have previously been shown to act as NPP substrates, albeitwith permeation rates several orders of magnitude lower thanthat of Cl^-.

Once inside the host cell, T16 was shown to accumulate largely( $~$ 80% of total uptake) inside the intracellular parasite. Themechanism by which T16 crosses the parasite's plasma membraneis as yet unclear; however, the observation that choline exertedan inhibitory effect on [³H]T16 uptake (Table 1) suggests thatcholine and T16 may share a common pathway into the parasite.Alternatively, a similar competition of these substrates forthe NPP may have resulted in the inhibition of [³H]T16 uptake.

The uptake of T16 was shown to be concentrative, suggestingeither active transport or intracellular binding. As $~$ 50% ofthe total [³H]T16 uptake in the parasite was localized in thefood vacuole, we investigated whether T16 could bind to FPIX,a well-known food vacuole-residing drug-binding target (e.g.,chloroquine [4]). T16 was shown to be able to bind in vitroto FPIX, effecting a large increase in the Soret peak of FPIX(Fig. 5A). T16 was also shown to bind to FPIX when loaded intoerythrocyte ghost membranes (Fig. 6), with an affinity (K_d,2 µM) that is comparable to that measured in situ (K_d,0.7 µM; Fig. 4).

The plasmepsin inhibitor Ro 40-4388 has previously been shownto reduce the intracellular pool of FPIX (4). Upon treatmentwith Ro 40-4388, the in situ binding of T16 was shown to bereduced without an effect on the binding affinity (Fig. 7).This result indicates that FPIX is likely to be the target high-affinitybinding site of T16. Isobole analysis revealed that Ro 40-4388antagonized T16 activity, indicating that binding of T16 toFPIX is essential for antimalarial activity (Fig. 8). Similarantagonism with Ro 40-4388 has been demonstrated for other FPIX-bindingdrugs such as chloroquine and pentamidine (4, 23). We shouldstate here, however, that bis-quaternary compounds have notshown any cross-resistance with chloroquine (26) and that resistancemodulators such as verapamil (10 µM) have no effect onthe activity of T16 against chloroquine-resistant isolates (datanot shown). Therefore, although heme binding contributes toT16 antimalarial activity, chloroquine resistance mechanisms—whichessentially affect access to heme by modulating the transmembranetransport of chloroquine—do not affect T16 activity. Thislast point is further illustrated in the P. falciparum (chloroquineresistant) TM6 strain, in which differences in IC₅₀s betweenchloroquine (128 nM) and T16 (25 nM) are not reflected by differencesin heme affinity (K_d, 139 nM for chloroquine and 700 nM forT16).

Understanding what happens to the parasite once T16 is boundto FPIX and concentrated is not entirely clear. FPIX-bindingdrugs such as chloroquine are believed to exert their antimalarialactivity by preventing the formation and growth of the hemozoin(ß-hematin) crystal, thereby allowing FPIX to buildup to toxic levels (9, 17, 21). In the case of chloroquine,hemozoin production is prevented by chloroquine-FPIX complexesincorporating in the growing polymer (hemozoin), resulting inthe termination of chain extension (24). Our results showing[³H]T16 association with hemozoin (Figs. 9A and 9B) suggestthat a similar mechanism may operate for T16; however, confirmationof this phenomenon would require a more detailed chemical analysisof the T16-hemozoin complex—which is outside the scopeof this study. The structure of T16 also points to a secondpossible mode of action of antimalarial activity. As shown inFig. 1, T16 has two positively charged heads linked by a hydrophobichydrocarbon chain, properties resembling those of a cationicdetergent. From our data, we can estimate that during a typicalin vitro antimalarial activity assay, upon exposure to an IC₅₀of T16 ( $~$ 25 nM), the concentration of T16 found in the food vacuole(assuming the food vacuole volume is $~$ 3% that of the infectederythrocyte [27]) at equilibrium ( $~$ 500 CAR) would reach approximately170 µM. At this relatively high concentration, it is possiblethat T16 disrupts the food vacuole membrane in a detergentlikemanner, thereby nonspecifically affecting any number of membrane-boundproteins.

Finally, it should be noted that $~$ 50% of the T16 residing inthe parasite was not found in the food vacuole. Previous experimentswith bis-quaternary ammonium compounds in P. knowlesi have correlatedthe in vitro and in vivo antimalarial activity to a reductionin phospholipid metabolism (1, 2). The remaining non-heme-bindingfraction of intracellular T16 may therefore be potentially boundto a target site affecting phospholipid metabolism.

Bis-quaternary ammonium compounds are emerging as potentiallyexciting drug alternatives to conventional antimalarial chemotherapy.The antimalarial activity of these compounds has been attributedto the inhibition of the parasite's phosphatidylcholine metabolism.Here we show that in addition to this mechanism, the potentantimalarial activity of bis-quaternary ammonium compounds,e.g., T16, can be attributed to the drug's ability to be transportedvia the parasite-induced NPP, its compartmentalization intothe parasite's food vacuole, and finally, its binding to FPIXand to the growing malaria pigment (hemozoin). Binding of T16to FPIX has been shown to be important for the high accumulationlevel of the drug and for the antimalarial activity.

ACKNOWLEDGMENTS

This work was supported by the European Union (QLK2-CT-2000-01166),CNRS/DGA (GDR 1077), and MENRT (PRFMMIP and VIHPAL). E. Richieris a recipient of a PAL+/MRT fellowship. P.G.B. and S.A.W. receivesupport from the Wellcome Trust.

We thank Jean Louis Morgat for assistance in the synthesis ofthe radioactive molecule.

FOOTNOTES

* Corresponding author. Mailing address: Liverpool School of Tropical Medicine, Pembroke Place, Liverpool, L35 QA, United Kingdom. Phone: 44 (0) 151 705 3286. Fax: 44 (0) 151 705 3371. E-mail: saward{at}liv.ac.uk.

REFERENCES

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