Adenosine Transporters in Bloodstream Forms of Trypanosoma brucei brucei: Substrate Recognition Motifs and Affinity for Trypanocidal Drugs

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Vol. 56, Issue 6, 1162-1170, December 1999

**Adenosine Transporters in Bloodstream Forms of Trypanosoma brucei brucei: Substrate Recognition Motifs and Affinity for Trypanocidal Drugs**

Harry P. de Koning¹ and Simon M. Jarvis

Research School of Biosciences, University of Kent at Canterbury, Canterbury, Kent, UK

	Summary

Top Abstract Introduction Materials and Methods Results Discussion References

Adenosine influx by Trypanosoma brucei brucei P1 and P2 transporters was kinetically characterized. The P1 transporter displayeda higher affinity and capacity for adenosine (K_m = 0.38 ± 0.10µM, V_max = 2.8 ± 0.4 pmol · 10⁷ cells¹ · s¹) than the P2 transporter (K_m = 0.92 ± 0.06 µM, V_max = 1.12 ±0.08 4 pmol · 10⁷ cells¹ · s¹). To formulate a structure-activity relationship for the interactionof adenosine with the transporters, a series of analogs were evaluatedas potential inhibitors of adenosine transport, and the K_i valueswere converted to binding energy. The P1 transporter was foundto be selective inhibited by purine nucleosides (K_i ~ 1 µM forinosine and guanosine), but nucleobases and pyrimidines had littleeffect on P1-mediated transport. The P1 transporter appears toform hydrogen bonds with N3 and N7 of the purine ring as wellas with the 3' and 5' hydroxyl groups of the ribose moiety, withapparent bond energies of 12.8 to 15.8 kJ/mol. The P2 transporter,in contrast, had high-affinity (K_i = 0.2-4 µM) for 6-aminopurines,including adenine, 2'-deoxyadenosine, and tubercidin, but notfor any oxopurines. The main interaction of adenosine with theP2 transporter is suggested to be via hydrogen bonds to N1 andthe 6-amino group. Additional $pi$ - $pi$ interactions of the purine ringand electrostatic interactions with N9 may also be important.The predicted substrate recognition motif of P2, but not of P1,corresponds to parts of the melaminophenylarsenical and diamidinemolecules, confirming the potent inhibition observed with thesetrypanocides for P2-mediated adenosine transport (K_i = 0.4-2.4µM).

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

African trypanosomes are the causative agents of sleeping sickness, and the corresponding diseases in livestock and game animalscontinue to be a major public health and veterinary problem inmany parts of Africa (Wery, 1991; Kuzoe, 1993). These protozoanlive freely in the bloodstream and (in late-stage infections)the cerebrospinal fluid of the host. Treatment of infections withAfrican trypanosomes in humans is limited to chemotherapy withdiamidines (pentamidine), suramin, melaminophenylarsenicals (melarsoprol),and dl- $alpha$ -difluoromethylornithine (DFMO), and only the latter twoare effective against late-stage sleeping sickness (Pepin andMilford, 1994), with melarsoprol being the drug of choice againstthe acute form of the disease caused by Trypanosoma brucei rhodesiense(Bacchi et al., 1990). Because existing trypanocides cause considerableside effects and because resistance to them is a serious problem(Kayembe and Wéry, 1972; Dukes, 1984; Bacchi et al., 1990, 1993;Bacchi, 1993), there is an urgent need for new chemotherapeuticapproaches.

During the past few years, interest in the purine nucleoside transporters of trypanosomes has intensified, for the followingreasons. First, trypanosomes, like all protozoan parasites, areauxotrophic for purines and rely entirely on salvage from thehost environment for their purine supply (Hammond and Gutteridge,1984; Hassan and Coombs, 1988). As the first step in purine salvageis translocation of the purine across the cell membrane, the transportroutes are potential targets for chemotherapy. T. b. brucei bloodstreamforms express at least two different nucleoside transporters (Carterand Fairlamb, 1993), designated P1 and P2, as well as two nucleobasetransporters (De Koning and Jarvis, 1997b, 1998). However, wehave only limited information on the structure-activity relationshipsof the different transporters. Somoza et al. (1998) recently demonstratedthat block of purine salvage in protozoa through rational designof novel drugs is practicable. A second reason for intense interestin T. b. brucei purine nucleoside transporters is that they havebeen implicated in the uptake of trypanocidal drugs, and changesto these carriers can lead to drug resistance (Carter and Fairlamb,1993; Barrett et al., 1995; Carter et al., 1995; Ross and Barns,1996). Purine transporters have also been suggested to be an idealconduit for the internalization of new designer drugs (Tye etal., 1998).

To exploit the trypanosome purine transporter for the delivery of new drugs (e.g., cytotoxic nucleoside analogs), severalconditions must be met to confer selectivity and efficacy; theseinclude 1) high affinity of the trypanocide for the parasite transporter,combined with 2) low affinity for the mammalian transporters,3) low abundance of competing substrates for the trypanosome transportersin its natural environment, and, ideally, 4) concentrative ratherthan equilibrative uptake. Trypanosome purine transporters appearto satisfy at least the last two requirements. Purine concentrationsin the blood are low (up to 1 µM; Plagemann et al., 1988), andT. b. brucei nucleoside and nucleobase transporters are protonmotiveforce driven (De Koning and Jarvis, 1997a,b, 1998; De Koning etal., 1998).

To investigate whether drug delivery through the T. b. brucei purine nucleoside transporters could meet the first two criteriaas well, we determined the kinetic constants for transport andevaluated a series of nucleosides and nucleobases as potentialinhibitors of the P1 and P2 transporters. Based on the inhibitiondata, a structure-activity relationship for the binding of analogsto the transporters was formulated to identify and compare thespecific substrate recognition motifs for the P1 and P2 transporters.In addition, the affinities of existing arsenical and diamidinetrypanocides for the different transporters were determined, aswell as for potentially chemotherapeutic nucleoside analogs suchas tubercidin (7-deazaadenosine), ganciclovir, ribavirin (1- $beta$ -D-ribofuranosyl-1H-1,2,4-triazole-3-carboxamide),and formycins A (3-[ $beta$ -D-ribofuranosyl]-pyrazolo[4,3-d]7-amine-pyrimidine)and B (3-[ $beta$ -D-ribofuranosyl]pyrazolo[4,3-d]6H-7-pyrimidone).

	Materials and Methods

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Trypanosomes. T. b. brucei (strain 427) from frozen stocks were grown in CD rats (Charles River), and blood was collected through exsanguination.Trypanosomes were separated from blood cells on a DE52 (Whatman)anion exchange column (Lanham, 1968), counted in a hemocytometer,washed twice with the assay buffer (33 mM HEPES, 98 mM NaCl, 4.6mM KCl, 0.55 mM CaCl₂, 0.07 mM MgSO₄, 5.8 mM NaH₂PO₄, 0.3 mM MgCl₂,23 mM NaHCO₃, and 14 mM glucose, pH 7.3), and resuspended at 10⁸ cells/ml. The trypanosomes were kept at 25°C at all times. Theseconditions are essential because previous studies have demonstratedthat the membrane depolarizes when the trypanosomes are preparedand stored at 4°C (Defrise-Quertain et al., 1996). At the endof each experiment, cell viability and motility were checked undera phase-contrastmicroscope.

Transport Assays. The uptake of adenosine and hypoxanthine was assessed as previously described (De Koning and Jarvis, 1997a,b; De Koning etal., 1998). Briefly, 100 µl of bloodstream forms of T. b. bruceiin assay buffer (10⁷ cells) was mixed with 100 µl of assay buffer containing [2,8,5'-³H]adenosine (2012 GBq/mmol; NEN, Germany) or [8-³H]hypoxanthine (999 GBq/mmol; Amersham Pharmacia Biotech, UK)and, where appropriate, test compound. The final concentrationsof [³H]adenosine and [³H]hypoxanthine were 0.02 and 0.03 µM, respectively, unless otherwiseindicated. These low concentrations of permeant were chosen toallow uptake to be determined at concentrations below the measuredK_m value of the different transporters. Under these conditions,the initial rate of uptake will approximate the V_max/K_m ratio,and inhibitory effects of the test compounds are readily observed;the IC₅₀ values will approach the K_i values (see eq. 1). If highersubstrate concentrations were used, then higher concentrationsof test compound are required to inhibit the uptake of radiolabeledsubstrate due to competition in binding between substrate andtest compound. It may not always be possible to obtain the necessaryhigh concentrations of the test compound due to insolubility;moreover, there is a risk of misclassifying inhibitory compoundsas noninhibitors. After predetermined times, normally 10 s, uptakewas stopped by the addition of ice-cold buffer containing 1 mMadenosine or 4 mM hypoxanthine, respectively, and centrifugationthrough an oil layer [7:1 (v/v) di-n-butyl phthalate/mineral oil].The resulting pellet was dissolved in 0.5 M NaOH, mixed with scintillationfluid (Optiphase HiSafe III), and counted for radioactivity. Toseparately determine uptake by the P1 and P2 adenosine transporters,adenosine uptake was assessed in the presence of 100 µM adenineor inosine, respectively. Most test compounds, including diminazeneaceturate (Berenil), were purchased from Sigma (Poole, UK). Pentamidineisothionate (Pentacarinat) was obtained from Rhone-Poulenc Rorer(Dagenham, UK). Ribavirin and dilazep were generous gifts fromthe Schering-Plough Research Institute (Kenilworth, NJ) and Hoffman-LaRoche (Basel, Switzerland), respectively. Melarsoprol was obtainedfrom May and Baker Ltd. (Dagenham, UK) as a 3.6% (w/v) solutionin propyleneglycol.

Data Analysis. All experiments were carried out in triplicate. Data were fitted to the appropriate equations with the use of the Enzfitterand Fig.P. software packages (Elsevier Biosoft, Cambridge, UK)to obtain K_m and IC₅₀ values. IC₅₀ values for compounds inhibitingthe uptake of radiolabeled permeants were determined from fulldose-response curves with a minimum of eight points spread overthe relevant range. In all cases, the Hill coefficients were closeto $-$ 1, consistent with competitive inhibition. Moreover, in previousstudies, it has been demonstrated that a number of the compoundstested in the present study, including trypanocides, inhibitedP1- or P2-mediated adenosine transport competitively (Carter andFairlamb, 1993; Carter et al., 1995; De Koning et al., 1998).Thus, all the available evidence suggests that a simple modelof competition with the binding site of the transporter is applicableand that the criteria for use of the Cheng and Prusoff equationto determine K_i value have been met. Hence, K_i values were calculatedfrom the Cheng and Prusoff (1973) equation

K<UP>i</UP>=<UP>IC</UP>50/[1+(<UP>L</UP>/K<UP>m</UP>)] (1)

in which L is the permeant concentration. It should be noted that the K_i value is an affinity constant and implies bindingto the transporter but does not indicate that the ligand is beingtransported across the membrane. Free Gibbs energy $Delta$ G⁰ was calculated from

&Dgr;<UP>G</UP>0=<UP>−RTln</UP>(K<UP>i</UP>) (2)

in which R is the gas constant and T the absolute temperature. Errors given in tables and shown as bars in graphs are standarderrors.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Adenosine Transport in Bloodstream Forms of T. b. brucei. Total uptake of 0.2 µM [³H]adenosine in bloodstream forms of T. b. brucei was determined using a rapid stop/oil spin protocoldeveloped for procyclic forms of T. b. brucei (De Koning et al.,1998). Figure 1 demonstrates that adenosine transport was efficientlyterminated by the addition of ice-cold 1 mM adenosine. Adenosineuptake was found to be linear for at least 50 s, with a rate of0.47 ± 0.024 pmol · 10⁷ cells¹ · s¹ at 0.2 µM [³H]adenosine (Fig. 1). The addition of 1 mM unlabeled adenosinecompletely inhibited the uptake of 0.2 µM [³H]adenosine, indicating that the transport of adenosine occursvia a mediated pathway (Fig. 1).

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Fig. 1. Time course for [³H]adenosine uptake by bloodstream forms of T. b. brucei. Uptake of [³H]adenosine at a final concentration of 0.2 µM ( $black-square$ ) was initiated by the addition of 10⁷ cells to [³H]adenosine layered over an oil mixture. At the indicated times, transport was stopped by the addition of 1 ml ice-cold stop solution (1 mM adenosine in assay buffer) and immediate centrifugation through the oil. Nonmediated influx of adenosine was assessed by determining the rate of 0.2 µM [³H]adenosine uptake in the presence of 1 mM unlabeled adenosine (

). In an additional series ( $triangle$ ), the cells were incubated with 0.2 µM [³H]adenosine for 20 s, stopped with 1 ml of stop solution, and centrifuged at the indicated times (after 0, 10, 30, and 50 s). The rate of uptake after the addition of stop solution was not significantly different from zero.

Adenosine uptake was inhibited to different levels by adenine and inosine (Fig. 2). Adenine (100 µM) inhibited 0.02 µM [³H]adenosine by 22.1 ± 3.0%, with a K_i value of 0.30 ± 0.02 µM(n = 3), whereas 100 µM inosine reduced uptake of [³H]adenosine by 81.2 ± 2.2%, with a K_i value of 0.44 ± 0.10 µM(n = 5). In the presence of 100 µM inosine, the remaining adenosineflux was dose-dependently inhibited by adenine (Fig. 2). Conversely,inosine completely inhibited [³H]adenosine uptake in the presence of 100 µM adenine (not shown).The Hill slopes for inhibition by either purine were consistentlyclose to $-$ 1 (both $-$ 1.0 ± 0.1). These results confirm the conclusionof Carter and Fairlamb (1993)

that bloodstream forms of T. b.brucei express two distinct adenosine transporters, designatedP1 and P2, that are sensitive to inhibition by inosine and adenine,respectively. Figure 3 shows that the P1 transporter had botha higher affinity and a higher capacity for adenosine (K_m = 0.35± 0.14 µM, V_max = 2.2 ± 0.2 pmol · 10⁷ cells¹ · s¹) than the P2 transporter (K_m = 0.94 ± 0.21 µM, V_max = 1.24 ±0.09 4 pmol · 10⁷ cells¹ · s¹). The mean kinetic constants from three separate experimentswere K_m of 0.38 ± 0.10 and 0.92 ± 0.06 µM and V_max of 2.8 ± 0.4and 1.12 ± 0.08 pmol · 10⁷ cells¹ · s¹ for P1 and P2, respectively.

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Fig. 2. Demonstration of two distinct adenosine transporters in bloodstream forms of T. b. brucei. Uptake of 0.02 µM [³H]adenosine over 10 s was measured in the presence of increasing concentrations of inosine ( $black-square$ ), adenine (

), or adenine in the presence of 100 µM inosine ( $triangle$ ). IC₅₀ values were 0.56 ± 0.07, 0.46 ± 0.25, and 0.34 ± 0.01 µM, respectively. Data points are the average of triplicate estimates from a single experiment.

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Fig. 3. Concentration dependence of adenosine influx by bloodstream forms of T. b. brucei. Initial rates of adenosine uptake were measured by incubating cells for 10 s with 0.02 µM [³H]adenosine and 0 to 100 µM unlabeled adenosine in the presence of 100 µM adenine ( $black-square$ , P1 mediated) or 100 µM inosine (

, P2 mediated). The kinetic constants were determined by nonlinear regression using the Michaelis-Menten equation. Values for this experiment were K_m = 0.35 ± 0.14 µM and V_max = 2.2 ± 0.2 pmol · 10⁷ cells¹ · s¹ for P1 and 0.94 ± 0.21 µM and 1.24 ± 0.09 pmol · 10⁷ cells¹ · s¹ for P2. Data points are the average of triplicate determinations.

Substrate Recognition by P1 and P2 Adenosine Transporters. P1- and P2-mediated transport of 20 nM [³H]adenosine was assessed in the presence of 100 µM adenine or inosine, respectively.A range of potential substrates (naturally occurring purines andpyrimidines as well as purine analogs) was tested for their abilityto inhibit P1 or P2 transport activity. Based on the inhibitiondata, a structure-activity relationship for the binding of nucleosides/nucleobasesto the P1 and P2 adenosine transporters was formulated and a comparisonwas undertaken. The K_i values were determined from full dose-responsecurves and in triplicate (Fig. 4). Table 1 lists the K_i valuesalong with their respective binding energies.

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Fig. 4. Comparison of the effects of selected purine nucleosides on P1- and P2-mediated [³H]adenosine transport. P1-mediated ( $black-square$ ) and P2-mediated (

) adenosine flux were measured in the presence of 100 µM adenine or 100 µM inosine, respectively. Incubation time was 10 s, [³H]adenosine concentration was 0.02 µM, and the data points are the average of triplicate determinations.

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TABLE 1
K_i values for potential inhibitors of P1- and P2-mediated adenosine uptake in T. b. brucei bloodstream forms
Initial rates of transport were measured by incubating 10⁷ cells for 10 s with [³H]adenosine in the presence of increasing amounts of inhibitor (at least 8 points) and 100 µM adenine (P1 mediated) or 100 µM inosine (P2 mediated). Initial rates of uptake were then plotted versus log inhibitor concentrations to determine IC₅₀ values, which were converted to K_i values using a K_m value of 0.38 µM for P1 and a K_m value of 0.92 µM for P2.

P1 Transporter. The P1 transport function was not inhibited by pyrimidine or purine nucleobases when tested at concentrations up to 1 mM.In contrast, adenosine influx via P1 was potently inhibited bya variety of purine nucleosides (Table 1), showing that the ribosemoiety is essential for binding to P1. However, the 2'-hydroxylgroup is not required because 2'-deoxyadenosine has, if anything,a slightly higher affinity than adenosine (0.19 ± 0.02 µM, Fig.4A). Nevertheless, both 3'- and 5'-deoxyadenosine had a markedlyreduced binding affinity for the P1 transporter (K_i = 210 ± 48and 100 ± 7 µM, respectively; Table 1). Clearly, both hydroxylgroups are involved in interactions with the transporter. Forboth ligands, the reduction of the binding energy $Delta$ G⁰ compared with adenosine of 15.1 and 14.1 kJ/mol for 3'- and 5'-deoxyadenosine,respectively, is consistent with the loss of one hydrogen bondbetween substrate and carrier. The involvement of the ribose groupis confirmed by the inability of the acyclic guanosine analogganciclovir to inhibit P1-mediated adenosine uptake. However,the strict selectivity for purines over pyrimidines (Table 1)showed that the aglycon part of the substrate was also involvedin ligand/transporter interactions. This was further illustratedby the observation that ribose alone has no detectable effecton P1-mediated adenosine uptake, even at 1 mM (Table 1).

The group at position 6 of the purine ring did not form part of the binding recognition motif because guanosine (Fig. 4B)and inosine, each with a keto group at this position instead ofthe amine group of adenosine, were potent inhibitors of adenosineinflux. However, the low affinity of 3-deazaadenosine (Fig. 4E)and ribavirin (structure; Fig. 5) demonstrates that the loss innitrogen residue at position 3 is essential for high-affinitybinding to the P1 transporter. The loss in binding energy of 13.5and 10.8 kJ/mol, respectively, suggests the loss of one hydrogenbond between ligand and transporter. The somewhat higher bindingenergy for ribavirin than for 3-deazaadenosine might be explainedif the nitrogen residue at position 4, unique to ribavirin, wasable to form the same hydrogen bond as N3, albeit much weaker.The involvement of N3 in H-bonding is also apparent from the effectof substitutions on the adjacent position 2. Both a chloride (2-chloroadenosine,K_i = 15 ± 5.3 µM) and, to a lesser extent, an amine (guanosine,K_i = 1.8 ± 0.3 µM; Fig. 4B) would reduce the partial negativecharge on N3 and weaken the hydrogen bond. The loss in $Delta$ G⁰ of 9.2 and 4.0 kJ/mol, respectively, does indicate a weakenedrather than a disrupted hydrogen bond. Alternatively, the substitutionson position 2 could interfere with the H-bond to N3 through stericor electrostatic repulsion of the relevant amino acid residueof the transporter.

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Fig. 5. Structural formulas of selected purine (analogs) and trypanocides. Care has been taken to depict the dominant tautomeric forms. Formycins A and B are both 85% in the N(1)H tautomeric form and 15% in the N(2)H form (Bzowska et al., 1992

). Inosine, adenosine, and guanosine do not exhibit appreciable tautomerism (Chenon et al., 1975

; Bzowska et al., 1992

). Note the different IUPAC numbering for purines and the pyrazolo[4,3-d]pyrimidine ring of the formycins.

The low affinity of the P1 transporter for uridine (K_i = 830 ± 86 µM), and the corresponding reduction of 19.2 kJ in $Delta$ G⁰ compared with adenosine, is consistent with the loss of 2 H-bondsto the purine ring. This suggests that part of the imidazole ringis also involved in binding. The identification of which residuesof the imidazole are essential for binding to the transporterwas based on examination of the potency of formycins A and B (analogsof adenosine and inosine, respectively, with the N9 residue shiftedto position 8, see Fig. 5), 8-azidoadenosine, and tubercidin (7-deazaadenosine)to inhibit P1-mediated transport. The affinity of the P1 transporterfor tubercidin (Fig. 4C) was almost 200-fold less than that foradenosine, showing the importance of N7. The $Delta$ G⁰ for tubercidin ( $-$ 23.4 kJ/mol) was similar to the values for 3-deazaadenosine,3'deoxyadenosine, and 5'deoxyadenosine, consistent with each compoundforming one H-bond less than adenosine with the P1 transporter.The P1 transporter displayed a relatively high affinity for formycinA (Fig. 4D) and formycin B (Table 1), indicating that neitherC8 nor N9 is important for ligand binding. However, as a consequenceof the substitution of an imidazole for a pyrazolo ring, the protonationstate of N7 has largely shifted from unprotonated to protonated(Bzowska et al., 1992

; Fig. 5). The energy required to shift thetautomeric equilibrium to N(2)H (equivalent to position 8 in adenosine,Fig. 5) may be responsible for the loss of ~3 kJ/mol in $Delta$ G⁰ of the formycins compared with adenosine (Table 1). The 25-folddecrease in potency of 8-azidoadenosine to inhibit adenosine uptakevia P1 (compared with adenosine) is probably attributable to bothits size and its resonance with the imidazole ring. This resultsin weakening the H-bond to N7 in a similar way as the substitutionson position 2 weaken the H-bond toN3.

P2 Transporter. In contrast to the P1 transporter, the P2 transporter does not require the presence of the ribose moiety for ligand binding.This is evident from the high-affinity interaction of adenine(see earlier), resulting in P2 being a mixed nucleoside/nucleobasetransporter. It is therefore predicted that most substitutionsat position 9 of the purine ring, or small alterations to theribose group, will not significantly increase the K_i value comparedwith adenosine. The K_i value of 0.23 ± 0.04 µM for 2'-deoxyadenosineis consistent with this prediction (Fig. 4A). Indeed, the presenceof a 2' hydroxyl group seems to reduce the binding energy by 3.4kJ/mol.

The strict selectivity of the P2 transporter for purines over pyrimidines or polyamines (Table 1) shows that constituentsof the purine ring are essential for binding to P2. For interactionwith the P2 transporter, the most important feature on the purinering appears to be the amine group at position 6 of adenosine.Purine nucleosides or nucleobases with a substitution at thisposition displayed low affinity for this transporter (Fig. 4Band Table 1). For example, high concentrations of inosine (>250µM), identical to adenosine except for the keto rather than aminegroup at position 6, failed to inhibit P2-mediated adenosine uptake(Fig. 2). However, the P2 transporter does not exhibit a broadpermeant specificity. The polyamines, putrescine and spermidine(Table 1), and amino acids (not shown) had no effect on P2-mediatedadenosine transport. The nitrogen residue at position 1 is partof the P2 binding motif, as shown by the relatively high affinityfor 2-aminopyridine (K_i = 14 ± 4.9 µM; Fig. 4F), which resemblesadenosine only in that it has an amine group in a position orthofrom a pyrimidine nitrogen. The $Delta$ G⁰ for 2-aminopyridine was 6.8 kJ/mol lower than that for adenosine,indicating that the main binding motif for the P2 transporteris H₂N---C(R₁)==N---R₂. Further evidence for the involvement of N1is that oxopurines like guanosine and inosine are almost exclusivelyin the keto rather than the enol tautomeric forms (Chenon et al.,1975

; Fig. 5), which ensures protonation of N1. It is the lossof hydrogen bonds at both positions 1 and 6 that causes the strictselectivity of aminopurines over oxopurines. The aromaticity ofthe ring may also contribute to the ligand/transporter interaction(see Discussion).

Although the identified motif described above does confer selective high affinity for the P2 transporter, it does not by itselfensure optimal binding of the ligand (compare the submicromolarK_i values for adenine and adenosine with the micromolar K_i valuefor 2-aminopyridine). Of other elements on the purine ring, N7and N3 were not directly involved in ligand/transporter interactionsbecause tubercidin and 3-deazaadenosine retained high affinity(Fig. 4, C and E, and Table 1). However, the nitrogen residueat position 9 appears to be important because the K_i value forthe adenosine analog formycin A was about 30-fold higher (Fig.4D) than that for other adenosine analogs. The $Delta$ G⁰ for this ligand was 9.1 kJ/mol lower than that for adenosine,less than the loss of an H-bond. Indeed, N9 is incapable of formingH-bonds and must contribute to the ligand binding in a differentway (see Discussion). The affinity for 8-azidoadenosine was evenmore reduced (K_i = 330 ± 140 µM), but the effect of the azidogroup at that position is hard to interpret and may be in partdue to steric interference. Finally, substitutions at position2 may also lead to some loss of affinity, as illustrated by the6-fold increased K_i value for 2-chloroadenosine (Table 1), possiblyas the result of reduced electron density onN1.

Substrate Recognition for H2 Nucleobase Transporter. In addition to the two adenosine transporters described here, bloodstream forms of T. b. brucei express at least two additionalpurine transporters with hypoxanthine as their main substrate(De Koning and Jarvis, 1997b), designated H2 and H3. The H2 transporterseems to be the more important because this carrier mediates morethan 80% of hypoxanthine flux at physiological concentrations,recognizes a wider array of substrates, and has a higher affinityfor all purine nucleobases (De Koning and Jarvis, 1997b). In lightof the identification of the substrate-binding motifs for theadenosine transporters and the importance of establishing theaffinities of the various transporters for diamidine and arsenicaldrugs (see later), we reanalyzed the selectivity profiles of theH2 transporter to identify structures that confer high affinityas far as this can be done with the available data (Table 2).

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TABLE 2
Rank order of inhibitors of the H2 nucleobase transporter of T. b. brucei bloodstream forms

In contrast to the P2 transporter, the H2 transporter was preferentially inhibited by oxopurines, with the inhibition constantfor adenine almost 30-fold less than the K_m value for hypoxanthineinflux (Table 2). This implicates either the 6-keto group asan H-bond acceptor or the N(1)H as an H-bond donor. The differencein binding energy of just 8 kJ/mol between hypoxanthine and adeninewas inconsistent with both groups being involved in binding. Themore likely explanation seems to be a hydrogen bond to the 6-ketogroup because the H2 transporter displayed a 3-fold lower affinityfor guanine compared with hypoxanthine. The involvement of a N(1)HH-bond also seems unlikely because the introduction of an aminesubstitution at position 3 might have strengthened rather thanweaken the interaction by withdrawing electron density fromN1.

Another important feature for H2 recognition appeared to be N7 of the imidazole ring because the shift of this residue toposition 8 caused substantial loss of binding energy (8.6 kJ/mol,allopurinol [4-hydroxypyrazolo(3,4-d)pyrimidine] versus hypoxanthine).This effect is not due to tautomeric shifts on the pyrimidinering (allopurinol, like hypoxanthine, being predominantly in thelactam rather than lactim state; Hänggi et al., 1993

). Similarly,the loss of binding energy for xanthine (10.6 kJ/mol), comparedwith hypoxanthine, is most likely due to the predominance of theN(7)H tautomer for xanthine, which is more stable than the N(9)Htautomer by 9.2 kJ/mol (Rastelli et al., 1997

). Hypoxanthine ismore stable in the N(9)H tautomeric isoform, by about the sameamount of energy (Rastelli et al., 1997

). Finally, the preferenceof this transporter of nucleobases over nucleosides shows thatbulky substitutions on N9 are unfavorable forbinding.

Diamidines and Melaminophenylarsenicals Display High Affinity for P2 Transporter. Alignments of the above ligand recognition profiles with the structural formulae of diamidines such as pentamidine and diminazeneaceturate (berenil) and melaminophenylarsenicals such as melarsoprol(see Fig. 5) would predict that these trypanocides have littleaffinity for the P1 and H2 transporters but may have a high affinityfor the P2. To test this hypothesis, we examined these drugs asinhibitors of [³H]adenosine and H2-mediated [³H]hypoxanthineuptake.

The results depicted in Table 3 show that these predictions were upheld. The P2 transporter displayed high affinity (K_i =0.4-2.4 µM) for all three drugs, whereas the other transportersdisplayed affinities that were typically 2 orders of magnitudelower. One exception was the H2 transporter, which exhibited arelatively high binding affinity for melarsoprol (K_i = 10.1 ±2.6 µM), perhaps as a result of the structural similarity betweenthe melamine group and adenine (K_i 3.2 ± 1.1 µM).

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TABLE 3
K_i values for selected trypanocides
Uptake of 20 nM [³H]adenosine and 30 nM [³H]hypoxanthine by T. b. brucei bloodstream forms was performed as described in the legend to Table 1.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, we confirmed the presence of two high-affinity adenosine transporters, designated P1 and P2 (Carter and Fairlamb,1993), in T. b. brucei bloodstream forms. No evidence was obtainedfrom the inhibitor dose-response curves of either P1- or P2-mediatedadenosine transport for the presence of additional transporterscontributing significantly to the influx of adenosine. For example,the Hill slopes were not significantly different from $-$ 1, and100% inhibition was consistently observed. On the basis of inhibitiondata, the binding energies for the interactions of various ligandsfor either transporter were determined, and models were proposedfor the interactions between permeant binding site and adenosine.P1 and P2 differed in their ligand recognition profiles, indicatingthat that the permeant binding pocket for the two adenosine transportersaredistinguishable.

The P1 transporter displayed a high affinity for all natural purine nucleosides (K_i ~ 1 µM) and most purine nucleoside analogstested, whereas P2 recognized only adenosine nucleosides. In addition,the P1 transporter was completely insensitive to inhibition bynucleobases, but P2 displayed a higher affinity for adenine thanfor adenosine (affinity constant of 0.3 versus 0.9 µM). Analysisof the inhibition profiles allowed the identification of the structureswithin the adenosine molecule that engage in the binding of adenosineto the transporter. For the P1 transporter, the loss of 13.4 to15.8 kJ/mol in Gibbs free energy when N3, N7, 3'OH, or 5'OH isreplaced by carbon or hydrogen residues identifies each of thesegroups as a potential acceptor (the nitrogen residues) or donorof a hydrogen bond. The bonding energy of adenosine was determinedto be $-$ 36 kJ/mol, whereas the energy of the four H-bonds is predictedto be $-$ 56 kJ/mol. This apparent difference suggests considerablecooperativity between the bonds and indicates a reason for thefailure of ribose and hypoxanthine to inhibit adenosine uptakevia the P1 transporter, even though each compound has two of fouressential residues to form H-bonds within the putative permeantbindingsite.

The region of adenosine most involved in interaction with the P2 transporter was identified as N(1)---C(6)---NH₂, with N1 actingas a potential H-bond acceptor and the amine group a possibledonor of one or two H-bonds. Cooperation between these bonds wouldresult from the withdrawal of electron density from the aminegroup through the formation of the H-bond to N1. The importanceof this structure in ligand/transporter interaction was demonstratedmost convincingly by the inhibitory effect of 2-aminopyridineon P2-mediated adenosine uptake and fully explains the total preferencefor 6-aminopurines over oxopurines, as the latter molecules, possessinga protonated N1, have a completely reversed H-bond donor/acceptorpair on positions 1 and 6. However, the H-bonding to the above-mentionedstructure is not sufficient to account for the $-$ 34.5 kJ/mol inbinding energy between the P2 transporter and adenosine. The similarbinding energies of 2-aminopyrimidine and formycin A, about 8kJ/mol lower than that for adenosine, identifies N9 as essentialfor high-affinity binding. The lone pair of electrons at N9 wouldbe mostly fed into the $pi$ -system of the pyrimidine ring and beunavailable for H-bonding to the transport protein, thereby creatinga partial positive charge on N9 and making the $pi$ -system more electronrich. In the environment of a hydrophobic binding pocket, eithermight be significant for substrate/carrier binding. Apart fromelectrostatic attractions, $pi$ - $pi$ interactions between aromatic ringscan contribute up to 10 kJ/mol to the binding energy (Hunter etal., 1991). The possibility of $pi$ - $pi$ interactions significantlycontributing to ligand binding by the P2 transporter suggeststhat an aromatic residue may play a significant role in P2/ligandinteractions as shown for hypoxanthine/guanine/xanthine phosphoribosyltransferasesfrom a variety of sources (Eads et al., 1994; Schumacher et al.,1996; Somoza et al., 1996; Vos et al., 1998). Koellner et al.(1998) also concluded that in Escherichia coli purine nucleosidephosphorylase, aromatic interactions between the purine ring andPhe159/Tyr160 direct the base into its bindingposition.

Thus, optimal binding to the P2 transporter requires 1) an amidine group H₂N---C(R₁)==N---R₂, that may be integrated into a pyridineor pyrimidine ring; 2) an aromatic system associated or integratedwith the amidine group; and 3) an electronegative group attachedto the aromatic ring, para to the amidine, that is able to contributeto the $pi$ -system with a lone electron pair. These results are entirelyin agreement with predictions from an earlier study (E. Akuffoand A. H. Fairlamb, unpublished results) based on the abilityof various purines and other molecules to abrogate melarsen-oxide-inducedlysis of T. b. brucei. In addition, the criteria for P2 recognitionare all met by the diamidine drugs pentamidine and berenil, aswell as by the melaminophenylarsenicals (Fig. 5). The melaminering of melarsoprol by itself fulfills all the requirements, andthe relatively large phenylarsenical group does not interferewith the high-affinity binding to the P2 transporter. The findingthat pentamidine showed equally high affinity for this transportersuggests that the amidine group does not need to be integratedin the aromatic ring and that an ether group on the para positionis equally effective as an amine in enhancing binding. The bindingenergy for berenil was somewhat lower than that of the other twodrugs, possibly as a result of its less flexiblestructure.

The interaction of melaminophenylarsenicals and diamidines with the P2 transporter could be due to the binding of these compoundsto the permeation site, without necessarily being transportedinto the cell. However, earlier studies have shown that both adenosineand adenine, but not inosine, protected bloodstream forms of trypanosomesfrom melarsen-oxide-induced lysis in vitro (Carter and Fairlamb,1993). This result was consistent with melaminophenylarsenicalsentering trypanosomes via the P2 transporter, and this notionwas further supported by the observation that P2 transporter activitywas absent in a melarsoprol-resistant strain (Carter and Fairlamb,1993). In subsequent studies, a P2-like transporter has also beenimplicated in the uptake of berenil in Trypanosoma equiperdum(Barrett et al., 1995), of cymelarsan in Trypanosoma evansi (Rossand Barns, 1996), and of pentamidine in T. b. brucei (Carter etal., 1995). Thus, we conclude that the above drugs are specificpermeants for the P2 transporter and the structural rationalefor the high-affinity interaction of these compounds with theP2 transporter have been defined in thisstudy.

The identification of those structures that are essential for high-affinity binding with the trypanozoon transporters enablesthe selection or design of novel trypanocides that will be takenup with high efficiency. Because all the T. b. brucei nucleosideand nucleobase transporters investigated to date are proton symporters(De Koning and Jarvis, 1997a,b, 1998; De Koning et al., 1998),these substrates should be efficiently concentrated intracellularly.However, for such compounds to be therapeutically relevant, theyshould also display selectivity for the parasite transportersover the corresponding host transporters. Two equilibrative (designatedei and es) and five concentrative nucleoside (designated N1-N5)transporters have been identified in mammalian cells, with substrateaffinities for naturally occurring nucleosides of 10 to 300 µMand 5 to 50 µM, respectively (for a review, see Griffith and Jarvis,1996). Not only are these affinities one to two orders of magnitudelower than those of the T. b. brucei purine transporters (Tables1 and 4; De Koning and Jarvis, 1997a,b, 1998), the substraterecognition profiles of the mammalian transporters are also significantlydifferent. For example, all the mammalian transporters for purinenucleosides recognize at least some pyrimidine nucleosides (Griffithand Jarvis, 1996) and require a ribose moiety for transport, whereasthe T. b. brucei purine transporters do not bind pyrimidines andthe affinity for the P2 transporter is actually slightly reducedby the presence of a ribose moiety. On this basis, the prospectof selective uptake of toxic chemotherapeutic compounds by theP1 and P2 transporters of trypanosomes seems hopeful. The T. b.brucei transporters, particularly P1, would recognize cytotoxicnucleosides, such as formycin A, ribavirin, and tubercidin, attherapeutic levels (Table 1), whereas the mammalian transportersgenerally have low affinity for such agents (Griffith and Jarvis,1996; Jarvis et al., 1998). Indeed, it was recently demonstratedby Tye et al. (1998) that a melamine moiety can be used to deliverpotentially cytotoxic polyamine analogs to trypanosomes. However,these compounds, although inhibitors of P2-mediated adenosineuptake, showed only weak trypanocidal activity in vitro.

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TABLE 4
Comparison of the functional properties of nucleoside transporter subtypes in bloodstream forms of T. b. brucei and mammalian cells

In conclusion, the different pattern of binding forces involved in P1 and P2 transporter/substrate interactions suggests thattheir binding pockets may be quite dissimilar. With the recentcloning of the mammalian nucleoside transporters, a number ofstudies have appeared using chimeric transporters or site-directedmutants that have started to define the essential residues onthe equilibrative and active nucleoside carriers for transportselectivity or inhibitor sensitivity (Wang and Giacomini 1999a,b;Sundaram et al., 1998). The present study approaches this problemfrom the substrate rather than the protein side and has resultedin formulating a structure-activity relationship for the bindingof adenosine to the P1 and P2 tansporters. With efforts to clonethe T. b. brucei nucleoside transporters under way, these transportersshould provide excellent models to further study transporter structureandmechanism.

	Acknowledgments

We thank Drs. Philip J. Blower and David W. Parkin for helpful discussions and Bryan Cover, Lee Byrne, Sam Ellis, and DavidLam for technicalassistance.

	Footnotes

Received April 1, 1999; Accepted August 25, 1999

¹ Current address: Institute of Biomedical and Life Sciences, Division of Infection and Immunity, Joseph Black Building, Universityof Glasgow, Glasgow G12 8QQ,UK.

This work was supported by the Wellcome Trust (Grant 041181/Z/94).

Send reprint requests to: Dr. Simon M. Jarvis, Research School of Biosciences, University of Kent at Canterbury, Canterbury, Kent CT2 7NJ, UK. E-mail: S.M.Jarvis{at}ukc.ac.uk

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