Tocopherol biosynthesis in Leishmania (L.) amazonensis promastigotes

Leishmaniasis is a neglected disease caused by a trypanosomatid protozoan of the genus Leishmania. Most drugs used to treat leishmaniasis are highly toxic, and the emergence of drug‐resistant strains has been observed. Therefore, new therapeutic targets against leishmaniasis are required. Several isoprenoid compounds, including dolichols or ubiquinones, have been shown to be important for cell viability and proliferation in various trypanosomatid species. Here, we detected the biosynthesis of tocopherol in Leishmania (L.) amazonensis promastigotes in vitro through metabolic labelling with [1‐(n)‐3H]‐phytol. Subsequently, we confirmed the presence of vitamin E in the parasite by gas chromatography–mass spectrometry. Treatment with usnic acid or nitisinone, inhibitors of precursors of vitamin E synthesis, inhibited growth of the parasite in a concentration‐dependent manner. This study provides the first evidence of tocopherol biosynthesis in a trypanosomatid and suggests that inhibitors of the enzyme 4‐hydroxyphenylpyruvate dioxygenase may be suitable for use as antileishmanial compounds. Database The amino acid sequence of a conserved hypothetical protein [Leishmania mexicana MHOM/GT/2001/U1103] has been deposited in GenBank (CBZ28005.1)

Leishmaniasis is a neglected disease caused by a trypanosomatid protozoan of the genus Leishmania. Most drugs used to treat leishmaniasis are highly toxic, and the emergence of drug-resistant strains has been observed. Therefore, new therapeutic targets against leishmaniasis are required. Several isoprenoid compounds, including dolichols or ubiquinones, have been shown to be important for cell viability and proliferation in various trypanosomatid species. Here, we detected the biosynthesis of tocopherol in Leishmania (L.) amazonensis promastigotes in vitro through metabolic labelling with [1-(n)-3H]-phytol. Subsequently, we confirmed the presence of vitamin E in the parasite by gas chromatography-mass spectrometry. Treatment with usnic acid or nitisinone, inhibitors of precursors of vitamin E synthesis, inhibited growth of the parasite in a concentration-dependent manner. This study provides the first evidence of tocopherol biosynthesis in a trypanosomatid and suggests that inhibitors of the enzyme 4-hydroxyphenylpyruvate dioxygenase may be suitable for use as antileishmanial compounds.

Database
The amino acid sequence of a conserved hypothetical protein [Leishmania mexicana MHOM/ GT/2001/U1103] has been deposited in GenBank (CBZ28005.1) Human leishmaniasis is a neglected protozoal disease that occurs mostly in tropical and subtropical regions, caused by a protozoan of the genus Leishmania and transmitted by the bite of the female sandfly. It affects either the skin or the internal organs and is estimated that 1.5-2 million of new cases occur annually, with approximately 350 million people currently at risk of acquiring the disease [1].
The drugs that have been used most frequently to treat leishmaniasis are the pentavalent antimonials, sodium stibogluconate and meglumine antimoniate; however, these drugs are considerably toxic and, in some areas, the emergence of resistant strains has been observed [2]. Therefore, the need for studies on new therapeutic targets against leishmaniasis, such as metabolic pathways, has become extremely urgent. Isoprenoids are very diverse and constitute an abundantly present group of natural products [3]. Several essential trypanosomatid metabolites require isoprene biosynthesis by the classical mevalonate pathway located in mitochondria or a leucine alternative pathway in Leishmania mexicana [4][5][6]. Several isoprenoid compounds such as dolichols or ubiquinones have been already shown to be important for cell viability and proliferation in various trypanosomatids [7][8][9]. The combination of inhibitors that act at various points of the isoprenoid pathway seems to be a useful strategy against Trypanosoma cruzi and Leishmania spp. [7][8][9].
Various genes found in trypanosomatids, including Leishmania parasites, are homologous to those found in photosynthetic bacteria, and this is why some authors suggest that these organisms may have a photosynthetic ancestor [10]. In most photosynthetic organisms, isoprenoid precursors such as geranylgeranyl diphosphate are required for carotenoid, phytyl diphosphate (phytyl-PP) and isoprenoid quinones biosynthesis [9,11,12] among others. Furthermore, phytyl-PP provides phytyl moieties as a substrate for tocopherol biosynthesis [12]. The head group aromatic (HGA) precursor of tocopherol biosynthesis is the homogentisate whose origin is through the tyrosine degradation pathways. The L-tyrosine is first transformed into 4-hydroxyphenylpyruvate (HPP) by tyrosine aminotransferase; then, in a second step, 4hydroxyphenylpyruvate dioxygenase (HPPD) catalyses the formation of homogentisate from HPP. HGA is then subject to prenylation with phytyl diphosphate to yield 2methyl-6-phytylplastoquinol (MPBQ) by the enzyme homogentisate prenyltransferase (HPT). In biosynthesis are ring methylations and ring cyclization. Tocopherol cyclase converts MPBQ to dand c-tocopherol; finally, tocopherol methyltransferase adds a methyl group to the sixth position of the chromanol ring converting dand c-tocopherol to band a-tocopherol [13,14].
Tyrosine degradation has been previously demonstrated in Leishmania, and it appears to be an excellent drug target [15]. The degradation starts when the enzyme tyrosine aminotransferase cleaves the amino group of the amino acid. Subsequently, the deaminated tyrosine is reduced by the 4-hydroxyphenylpyruvate dioxygenase (EC: 1.13.11.27), whose activity has been already detected in leishmanial extracts [15]. Thus, vitamin E or tocopherol biosynthesis is an attractive target for investigation because Leishmania lives in a pro-oxidant environment in the vertebrate host and must therefore have an efficient antioxidant defence in order to ensure its survival [16]. Vitamin E acts as an antioxidant and free radical scavenger and, together with other antioxidants, has a role in the defence against oxidative stress [17]. In cultures of embryonic neurons, staurosporine treatment, an oxidative stress and cell death inducer, tocopherol protected the neurons from oxidative damage [18]. In plants, tocopherol and tocochromanols protect thylakoid components from oxidative damage and play roles in electron transport reactions, cell membrane permeability and fluidity, thereby acting as membrane stabilizers [19]. Previously, tocopherol biosynthesis, its antioxidant function and this biosynthesis inhibited by usnic acid were demonstrated in Plasmodium falciparum [20,21]. Here, we reported, for the first time, biochemical evidence indicating that a pathway for vitamin E biosynthesis in Leishmania (L.) amazonensis promastigotes is active. The results also indicate that this biosynthesis can be strongly inhibited by potential HPPD inhibitors.

MTT cell proliferation assay
The MTT assay, adapted for Leishmania spp. [22], was used to assess promastigote viability in different experiments. Briefly, promastigotes were pelleted by centrifugation and washed twice in PBS (137 mM NaCl, 2.7 mM KCl, 10 mM Na 2 HPO 4 and 1.8 mM KH 2 PO 4 , pH 7.4). Finally, parasites were resuspended in PBS, to which 5.0 mgÁmL À1 of MTT was added. After incubation for 60 min at 25°C, 0.1 mL of a 10% of SDS lysis solution was added to stop the reaction [22]. Absorbance was monitored using a fluorometer POLARstar Ò Omega (BMG Labtech, Waltham, MA, USA), at 595 nm and 690 nm as reference. The MTT methodology was used to perform three kinds of experiments as described below. We studied the antileishmanial activity of two HPPD inhibitors. Promastigotes in late logarithmic phase were treated with various concentrations (2.5 lM to 0.078 lM) of usnic acid (UA) or nitisinone (NTBC) (250 lM to 3.9 lM), and parasite viability was evaluated by MTT assay. Control cultures were treated with DMSO and/or acetone as solvent controls, and their effects on parasite viability were assessed daily by MTT measurements as well. The inhibitor concentration where the growth is reduced by half (IC 50 ) was calculated after 72 h of treatment.
In the second step, we studied whether tocopherol could recover HPPD inhibitor effects on parasite viability. Using a concentration of usnic acid or nitisinone where the growth is reduced near by half, promastigotes in late logarithmic phase were treated for 72 h with 0.5 lM usnic acid or for 48 h with 31.25 lM NTBC with or without exogenously added 25 lM a-tocopherol in the complete medium and the parasite viability was evaluated by MTT methodology.
In the third step, we studied staurosporine and tocopherol interactions. Promastigotes in late logarithmic phase were treated with staurosporine 75 nM in TC-100 medium with or without various concentrations of a-tocopherol (30, 60 or 90 lM). We previously observed that the described staurosporine concentrations and periods of treatment produce viability decreases. After 1-h incubation at 25°C, the cells were washed twice and the culture was recovered in complete TC-100 medium. Then, the treatments effects on parasite viability were assessed by MTT measurements.

Metabolic labelling and tocopherol inhibition assays
Cultures of L. amazonensis promastigotes, mainly in late logarithmic phase, were labelled with [1-(n)-3 H]-phytol (3.125 lCiÁmL À1 ) in complete TC-100 medium for 18-24 h and were then recovered. Subsequently, the parasite cultures were centrifuged at 800 g for 10 min at 4°C. The parasites were purified as described above, and each was subjected to vitamin E extraction.
For tocopherol inhibition assays, similar amounts of promastigotes, primarily in late logarithmic phase, were treated or not with 0.25 lM usnic acid for 72 h or 31.25 lM nitisinone for 48 h. The parasites were incubated with the radiolabelled precursor [ 3 H]-phytol (0.75 lCiÁmL À1 ) for the last 18-24 h before starting the extraction procedure. Biosynthesis of tocopherols of the same amount of treated and untreated parasites was compared by metabolic labelling and RP-HPLC (system I) as described below.

Vitamin E extraction
A 3 mL volume of 0.2 M HClO 4 in cool methanol was added to 5-10 9 10 8 promastigote pellets lyophilized in glass tubes. After mixing for 1 minute in a vortex, 3 mL of petroleum ether (bp 60-80°C) was added 3 times. The sample was mixed for 1 minute on a vortex and centrifuged at 2700 g for 20 minutes at 4°C. The petroleum ether phase was collected, and the extraction procedure was repeated again twice. The supernatants were transferred to glass tubes and evaporated in a stream of nitrogen at room temperature. The residues were resuspended in 400 lL of each HPLC initial mobile phase (see below) and subjected to RP-HPLC [23,24] and/or mass spectrometry analysis [25].

Reversed-phase high-performance liquid chromatography
Two reversed-phase high-performance liquid chromatography (RP-HPLC) systems (see below) were standardized in order to resolve satisfactorily the investigated isoprenoid compounds in L. amazonensis labelled with [ 3 H]-phytol. We determined the retention time of isoprenoid compounds as aand c-tocopherol monitoring at 295 nm. The isoprenoid compounds aand c-tocopherols were co-injected as internal standards with the extracts of labelled parasites to assess their retention time. In experiments employing metabolically labelled precursors, each fraction was collected per minute. The subsequent fractions were dried, resuspended in 600 lL of scintillation liquid mixture (PerkinElmer Life Sciences, MA, USA) and counted with a Beckman 5000 b-radiation scintillation counter Ò (Beckman, CA, USA). The stationary phase was a Phenomenex Luna Ò C18 column (250 mm 9 4.6 mm 9 5 um) (Phenomenex, Torrance, CA, USA) coupled to pre-C18 column (Phenomenex), detector UV-Vis or a diode array detector (DAD) (Gilson 170) and a fraction collector FC203B. For data processing, we used TRILUTION TM (Middleton, WI, USA) LC 3.0 System Software.
System I: The mobile phase consisted of a linear gradient system between acetonitrile (A) and methanol (B). The initial condition was 50% (A) at 0 min, reaching 70% (A) at 28 min and maintained for 10 min longer. The proportion returned to 50% (A) at 40 min with a flow rate of 1 mLÁmin À1 , and the fractions were collected per minute.
System II: The isocratic mobile phase consisted of methanol/ethanol 50:50 (v/v) with a flow rate of 1 mLÁmin À1 . Fractions were collected per minute.

Gas chromatography-mass spectrometry
To investigate the presence of a-tocopherol, the fractions resulting from RT-HPLC (System I) of L. amazonensis extracts were analysed by gas chromatography-mass spectrometry (GC-MS) to confirm the presence of a-tocopherol and derivatized as described by Van Pelt, 1998 [23]. We used a Y2K ion trap mass spectrometer (MS) PolarisQ System Ò (Finnigan, ThermoQuest Inc., San Jose, CA) equipped with a nanosource type electron impact ionization (EI) and coupled with a TRACE GC Ò (Finnigan, ThermoQuest Inc., San Jose, CA) equipped with a 30 m 9 25 mm 9 0.25 lm DB-5-ms column. The mobile phase was helium at a flow rate of 1 mLÁmin À1 .
The GC-MS analysis conditions were an initial oven temperature of 120°C for 2 minutes followed by a ramp of 20°CÁmin À1 until 320°C. This temperature was maintained for 3 minutes and then cooled to initial conditions. The injector temperature was 230°C, and the transfer line temperature was 295°C. For MS analysis, the temperature of ion source was 200°C, and two segments were acquired, first monitoring a range of m/z 150 to 505 (full scan) and second monitoring the fragmentation (MS/MS) of ion at m/z 502 corresponding to the derivatized a-tocopherol. The excitation energy scale for fragmentation was 0.3 and 1 V. The monitored fragment ions of a-tocopherol were at m/z 236, 237 and 277. The mass spectra were analysed using the version 1.3 XCALIBUR Ò (Waltham, MA, USA) data analysis program.

Reactive oxygen species measurement
Reactive oxygen species (ROS) production was measured using CellROX Ò Oxidative Stress Reagent fluorogenic probes to measure ROS in live cells [26]. The untreated promastigotes (negative control) are treated with UA 0.5 lM for 96 h with or without 25 lM a-tocopherol, washed with PBS and loaded with 5 lM of the CellROX Green Reagent in PBS for 30 min at 25°C. Fluorescence was monitored using a fluorometer POLARstar Ò Omega (BMG Labtech), at 485 nm and 520 nm for excitation and emission, respectively.

Statistical analysis
Statistical significance was determined by Student's t-test or ANOVA using GRAPHPAD PRISM Ò Software (GraphPad Software, Inc., La Jolla, CA, USA). The obtained P-values are indicated throughout Results section. Parasite growth inhibition assays were also analysed using GRAPHPAD PRISM Ò Software. IC 50 values were estimated fitting the data to a nonlinear regression (dose-response slope/variable sigmoid equation). We only considered as dose-response functions those assays with an R-squared values ≥ 0.95. All experiments were performed in three independent biological assays and each one in three or two independent technical replicates as indicated for each one experiment.

Biosynthesis of vitamin E
The cand a-tocopherols biosynthesized by L. amazonensis promastigotes were identified by two RP-HPLC systems. The parasite labelled with [1-(n)-3 H]-phytol was analysed by the RP-HPLC (system I) and a radioactive fraction with a coincident retention time with a-tocopherol (20 and 21 min) and c-tocopherol (22/23 and 24 min) standards (Fig. 1). Furthermore, a radioactive fraction was detected in the retention time of 34 and 35 minutes (unknown peak). Using another RP-HPLC system (system II), a radioactive fraction with a coincident retention time with a-tocopherol standards was also detected in promastigotes (Fig. S1).

Identification of a-tocopherol by GS-MS/MS
In addition to metabolic labelling, qualitative GC-MS/ MS analysis was employed for RP-HPLC fractions of unlabelled promastigotes. Figure 2A shows the chromatogram and fragmentation spectra of the a-tocopherol standard. The characteristic ions of atocopherol standard are the molecular ion at m/z 502 and the fragmentary ions at m/z 236 and 277. All were detected in promastigote forms (Fig. 2B). The ion at m/z 236 corresponds to the benzene portion with or without a proton, and the fragmentary ion at m/z 277 corresponds to the benzene portion plus the cyclized portion of the phytyl side chain.

Usnic acid and nitisinone effects on vitamin E biosynthesis
Parasite growth was inhibited in a concentrationdependent manner with an IC 50 value of 0.433 lM (AE 0.071) of usnic acid (Fig. 3A) and an IC 50 value of 47.87 lM (AE 10) of nitisinone (Fig. 3B) at 72 h of treatment.
The effects of usnic acid or nitisinone on vitamin E biosynthesis at the promastigote stage were further investigated using a drug concentration and a treatment period that produced a visible but weak decrease in parasite growth. Our results show a significant decrease in a-tocopherol (59.05 AE 6.42) and c-tocopherol (58.18 AE 3.44) biosynthesis in usnic acid-treated promastigotes (Fig 4A). When promastigotes were treated with nitisinone, the level of inhibition was lower, 24 AE 5.89 for a-tocopherol and 15.10 AE 1.24 for c-tocopherol (Fig. 4B). The most prominent inhibitory effect of nonspecific inhibitor usnic acid, decreasing almost all fractions, may indicate a general effect on parasite metabolism.
We attempted to reverse this growth inhibition by usnic acid and nitisinone by the exogenous addition of a-tocopherol compared with parasites treated only with tocopherol. Our results show that exogenously added a-tocopherol partially reversed growth inhibition in a dose-dependent manner (Fig. 5A,B). This finding suggests the vitamin E biosynthesis in the   parasite and that usnic acid or nitisinone may affect it. Moreover also, the exogenous addition of a-tocopherol protects the parasites treated with 75 nM of staurosporine (st) (an inhibitor of protein kinases that induces ROS production and cell death) [18], reversed partially the viability of the parasites in a dose-dependent manner (Fig. 6).

The function of vitamin E in Leishmania (L.) amazonensis
To assess whether vitamin E biosynthesis in L. amazonensis parasites acts against oxidative stress, we measured intracellular ROS levels in parasites treated with usnic acid, the HPPD inhibitor that showed the strongest tocopherol inhibitory activity. Usnic acid  treatment increased intracellular ROS content, compared to untreated promastigotes. However, we still do not know whether the principal usnic acid ROS effects are due to tocopherol biosynthesis inhibition or whether other mechanisms are also involved. Moreover, this effect was reversed when exogenously atocopherol was supplemented in the culture medium (Fig. 7).

Predicted amino acid sequences of conserved hypothetical proteins in Leishmania mexicana and Leishmania donovani
On BLAST analysis, we found the LMXM 26_1830 conserved putative protein in the genome of L. mexicana with closest similarity of 4-hydroxyphenylpyruvate dioxygenase superfamily and LMXM_28_1320 putative prenyltransferase protein of L. mexicana and LDBPK_28_1430 putative prenyltransferase protein of Leishmania donovani. Using the program T-COFFEE WS, the alignment of Arabidopsis thaliana HPPD with the predicted amino acid sequence of LMXM26_1830 showed the conserved regions with amino acid residues with similarity of HPPD (Fig. S2), and using Chlamydomonas reinhardtii homogentisate phytyltransferase (EC:2.5.1.115) (HPT1) as a query, with predicted amino acid sequence of LMXM_28_1320 putative prenyltransferase protein of L. mexicana and LDBPK_28_1430 putative prenyltransferase protein of L. donovani, it showed the conserved prenyl-DP and divalent cationbinding domains in the N-terminal region in similarity of HPT1 [27].
The alignment of putative prenyltransferase of L. mexicana and L. donovani with three HPT1 from different origins, Arabidopsis thaliana HPT1, Synechocystis sp. PCC 6714 HPT1 and Chlamydomonas reinhardtii HPT1, showed a conserved amino acid residues for catalytic activity in haem-O-synthase, which are conserved in HPT1 [27] (Fig. S3).

Discussion
The present study showed for the first time that the parasite L. amazonensis promastigotes biosynthesizes vitamin E. Although vitamin E biosynthesis is characteristic of photosynthetic eukaryotes [28], it was also demonstrated in P. falciparum [20,21]. In L. amazonensis, using two different RP-HPLC systems and the metabolic precursor [1-(n) -3H]-phytol, two fractions with the same retention time as the aand c-tocopherol standards were detected in the promastigotes. The eluted compound identities, studied by GC-MS/MS, indicated the presence of a-tocopherol isomers. Moreover, tocopherols were not detectable in complete culture medium, reinforcing the findings of tocopherol biosynthetic pathway in the parasite (data not shown). The presence of c-tocopherol in promastigotes provides further evidence, since c-tocopherol is an intermediate compound for the formation of a-tocopherol as shown in Arabidopsis spp. [29] and Synechocystis spp. [30] among other photosynthetic organisms. In Arabidopsis spp., phytol released from chlorophyll can be converted into phytyl-P and phytyl-PP and subsequently employed for tocopherol synthesis through a salvage pathway [31]. Radiolabelled phytol incorporation into tocopherol also demonstrates that the parasite must possess a salvage pathway as does Arabidopsis spp., by incorporating and recycling phytol for tocopherol isoprenylation among other phytylated compounds. Leishmania donovani and photosynthetic green sulfur bacteria remain the only known organisms that biosynthesize chlorobiumquinone, an isoprenoid naphthoquinone containing carbonyl group in the isoprenoid side chain. This compound is thought to prevent oxidative stress derived from the parasite-host relationship [32]. Chlorobiumquinone and tocopherol biosynthesis in various Leishmania species may be considered a trypanosomatid photosynthetic ancestor. This theory is also supported by genetic studies based on gene homology [32].
Our results also indicate that this biosynthesis can be strongly inhibited by the HPPD irreversible enzyme-binding inhibitor usnic acid [20,21,33] and moderately by HPPD inhibitor nitisinone [34][35][36], possibly due to its reversible enzyme-binding in most studied organisms [37][38][39]. The 4-hydroxyphenylpyruvate dioxygenase catalyses the conversion of p-hydroxyphenylpyruvic acid to homogentisic acid [37], a direct precursor of vitamin E and plastoquinone in most photosynthetic organisms [38] except in cyanobacteria, where plastoquinone is thought to be biosynthesized  by an alternative pathway [39]. Therefore, inhibition of 4-hydroxyphenylpyruvate dioxygenase enzyme decreases vitamin E and plastoquinone biosynthesis in most photosynthetic organisms [38,39]. Because plastoquinone is a required cofactor for phytoene desaturation, its inhibition also produces a carotenoid biosynthesis decrease in most photosynthetic organisms [38,39]. Norris et al. and Dahnhardt [38,39] showed that vitamin E but not plastoquinone biosynthesis is disrupted in mutants that lack the encoding gene of HPPD, proving its importance for compound formation.
4-hydroxyphenylpyruvate dioxygenase may be considered a 'double-edged sword', because it has effects at various Leishmania metabolic steps as well in several blood-feeding arthropods [15,40]. Tyrosine degradation has already been demonstrated to be necessary for Leishmania parasites, and dehydrogenase activity for p-hydroxybenzoate degradation has been previously detected in parasite extracts [15]. Tyrosine degradation appears to be an excellent drug target against Leishmania [15]; therefore, HPPD inhibitors may also act at this point. Surprisingly, tyrosine catabolism appears to be an essential treat to blood-feeding arthropods. Nitisinone is a commercially available low-toxicity compound that has been already investigated as a selective insecticide; it has an ability to hinder transmission of blood-feeding arthropoddependent infectious diseases [40].
Leishmania (L.) amazonensis showed growth inhibition upon drug treatment with usnic acid or nitisinone. Moreover, this inhibition was partially reversed by the addition of a-tocopherol, suggesting that vitamin E biosynthesis is commonly present by the Leishmania parasite and that HPPD inhibitors may specifically affect this biosynthetic pathway. The strong decrease in vitamin E biosynthesis when parasites were treated with usnic acid and the weak decrease following nitisinone treatment suggest an inhibitory activity on 4hydroxyphenylpyruvate dioxygenase as described by Meazza et al. [41], Romagni et al. [33], Ellis et al. [34] and Laschi et al. [35] in other cell systems. The antileishmanial activity of usnic acid has been previously tested in L. amazonensis in vivo. Intralesional administration was observed at a significant effect that reduced the weight of lesions and parasite loads in infected footpads [42] in T. cruzi cultivated in vitro [43]. The parasites of L. amazonensis live in a pro-oxidant environment and therefore have evolved extensive detoxifying and protective mechanisms against ROS [16]. Nevertheless, tocopherol can efficiently scavenge various radicals released during parasite oxidative stress [44].
Staurosporine is an inhibitor of protein kinases, and its growth inhibitory effects in the parasite were also partially reversed in a dose-dependent manner (Fig. 6). Staurosporine rescue suggests that tocopherol may protect against glutathione depletion and staurosporine-induced oxidative stress and cell death as it happens in other cell systems; nevertheless, further studies are needed to better understand this phenomenon [18,45,46]. Usnic acid treatment produced important effects on ROS production that can be protected by tocopherol. These findings suggest that tocopherol may be involved in parasitic usnic acid-induced oxidative stress defence; however, we still do not know whether usnic acid-induced effects on ROS levels occur because of tocopherol biosynthesis inhibition or whether other mechanisms are involved as well. Similar results regarding tocopherol functions were previously investigated in other cell systems. For example, in P. falciparum biochemical studies confirmed vitamin E biosynthesis, which can be inhibited by usnic acid, and that the vitamin E produced endogenously is active as an antioxidant [20,21]. A study involving the Euglena gracilis W 14 ZUL strain found that an organic carbon source resulted in increased mitochondrial activity, ROS and tocopherol biosynthesis [47]. Another group showed increased vitamin E biosynthesis in Rosmarinus officinalis L. under water stress that was related to limited photosynthesis and higher oxygen formation [48]. Synechocystis spp. tocopherol-deficient mutants were challenged with various combinations of chemicals and/or abiotic stresses to induce formation of various ROS types. The study showed that, compared with the wild-type, mutants of Synechocystis spp. challenged with linolenic acid and high luminosity accumulated a higher level of lipid peroxides [49].
In conclusion, more experiments should be performed to conclude that promastigotes of L. amazonensis have an active pathway for tocopherol biosynthesis as well as an active phytol metabolism. Ultrastructural, biochemical and biological analyses are required to elucidate completely the physiologic role of tocopherol in L. amazonensis, as well as its biosynthetic pathway. Our experiments suggest that tocopherol may play an important antioxidant role in L. amazonensis. Based on these results, a new drug target is proposed for the development of antileishmanial drugs.

Supporting information
Additional supporting information may be found online in the Supporting Information section at the end of the article. Fig. S1. Radioactive elution profile employing radiolabelled precursor and/or RP-HPLC system. Fig. S2. Amino acid sequence alignment of Arabidopsis thaliana HPPD with predicted amino acid sequence of LMXM_26_1830 conserved hypothetical protein of Leishmania mexicana.