Skip to main content
PLOS Pathogens logoLink to PLOS Pathogens
. 2014 Oct 23;10(10):e1004427. doi: 10.1371/journal.ppat.1004427

Sterol Biosynthesis Is Required for Heat Resistance but Not Extracellular Survival in Leishmania

Wei Xu 1, Fong-Fu Hsu 2, Eda Baykal 3, Juyang Huang 3, Kai Zhang 1,*
Editor: David Horn4
PMCID: PMC4207814  PMID: 25340392

Abstract

Sterol biosynthesis is a crucial pathway in eukaryotes leading to the production of cholesterol in animals and various C24-alkyl sterols (ergostane-based sterols) in fungi, plants, and trypanosomatid protozoa. Sterols are important membrane components and precursors for the synthesis of powerful bioactive molecules, including steroid hormones in mammals. Their functions in pathogenic protozoa are not well characterized, which limits the development of sterol synthesis inhibitors as drugs. Here we investigated the role of sterol C14α-demethylase (C14DM) in Leishmania parasites. C14DM is a cytochrome P450 enzyme and the primary target of azole drugs. In Leishmania, genetic or chemical inactivation of C14DM led to a complete loss of ergostane-based sterols and accumulation of 14-methylated sterols. Despite the drastic change in lipid composition, C14DM-null mutants (c14dm ) were surprisingly viable and replicative in culture. They did exhibit remarkable defects including increased membrane fluidity, failure to maintain detergent resistant membrane fraction, and hypersensitivity to heat stress. These c14dm mutants showed severely reduced virulence in mice but were highly resistant to itraconazole and amphotericin B, two drugs targeting sterol synthesis. Our findings suggest that the accumulation of toxic sterol intermediates in c14dm causes strong membrane perturbation and significant vulnerability to stress. The new knowledge may help improve the efficacy of current drugs against pathogenic protozoa by exploiting the fitness loss associated with drug resistance.

Author Summary

Leishmania parasites are transmitted through the bite of sandflies causing a spectrum of serious diseases in humans. Current drugs are inadequate and no safe vaccine is available. These parasites produce different types of sterols from humans, making the sterol synthesis pathway a valuable target of selective inhibitors. However, functions of sterols and sterol synthesis in protozoa are poorly understood, which hinders the development of new and improved treatments. In this study, we investigated the role of sterol C14α-demethylase, a key enzyme in sterol metabolism and the primary target of azole drugs. Loss of sterol C14α-demethylase completely altered the sterol composition in Leishmania, leading to increased membrane fluidity, failure to maintain lipid rafts, and hypersensitivity to heat stress. Despite these defects, null mutants of sterol C14α-demethylase were viable during the promastigote stage (found in sandflies) and could still cause disease in mice (although at a reduced capacity). Our findings provide direct evidence to support the role of specific sterols in membrane stability and stress response. The new knowledge may also help the development of new treatments or improve the efficacy of current drugs against pathogenic protozoa.

Introduction

Leishmaniasis is a group of parasitic diseases infecting 10–12 million people in 88 countries [1]. It is caused by protozoan parasites of the genus Leishmania and transmitted through the bite of sandflies. During their life cycle, Leishmania parasites alternate between motile promastigotes which live in the midgut of sandflies and non-motile amastigotes which reside in the phagolysosome of mammalian macrophages. Depending on parasite species and host genetic factors, symptoms of leishmaniasis include localized skin sores, diffuse cutaneous lesions, severe mucosa destruction, and deadly visceral infections (kala azar) which damage the spleen, liver, and bone marrow [2]. Current treatments are often toxic, difficult to administer, and not cost-effective [3]. With drug resistance on the rise and no safe vaccine available, it is necessary to maintain a steady stream of new inhibitors and new biochemical targets to control these dangerous pathogens [4].

In eukaryotes, sterol biosynthesis is a vital pathway and an important source of antimicrobial targets. It consists of three stages: 1) the synthesis of isopentenyl pyrophosphate from acetyl CoA or an alternative carbon source such as leucine in trypanosomatids [5]; 2) the condensation of isopentenyl pyrophosphate and dimethylallyl pyrophosphate to form squalene; and 3) the cyclization of squalene into lanosterol, which is then converted into final products such as cholesterol, ergosterol, and phytosterol (Fig. S1) [6], [7]. Along with sphingolipids, sterols are tightly packed into ordered membrane microdomains or lipid rafts, which can be isolated as detergent resistant membrane fractions (DRMs) serving as scaffolds to support membrane integrity and signal transduction [8], [9]. In Saccharomyces cerevisiae, ergosterol synthesis is implicated in cell growth, ethanol resistance [10], heat shock response [11], and gene expression [12]. In mammals, cholesterol is a vital constituent of cell membrane and a key component of lipoprotein particles. It is also the precursor for the synthesis for various steroid hormones [13]. Precise functions of sterol synthesis in protozoa, however, are not well-characterized.

Similar to fungi, trypanosomatid pathogens including Trypanosoma brucei, Trypanosoma cruzi, and various Leishmania species synthesize C24-alkylated, ergostane-based sterols [14] (Fig. S1). Although the early steps of sterol synthesis (prior to zymosterol) are conserved in most eukaryotes, structural differences between mammalian enzymes and microbial enzymes can be exploited to produce selective drugs. Enzymes involved in the late steps of sterol pathway could also be valuable targets because mammalian cells do not synthesize ergostane-based sterols. Indeed, multiple classes of compounds targeting sterol biosynthesis exhibit good anti-trypanosomatid activities in vitro although their efficacies in vivo are often unsatisfactory. Examples include 3-(biphenyl-4-yl)-3-hydroxyquinuclidine which blocks the activity of squalene synthase (E.C. 2.5.1.21) [15], terbinafine which inhibits squalene epoxidase (EC 1.14.99.7) [16], [17], various azole drugs which target sterol 14-alpha-demethylase (C14DM, EC 1.14.13.70) [18][20], and azasterol which interferes the C24-alkylation of sterol precursor [21], [22]. Amphotericin B (Amp B) is another antifungal which binds to ergosterol or other ergostane-based sterols leading to pore formation on the plasma membrane [23], [24]. It possesses potent anti-Leishmania activity and is widely used as the drug of choice to treat antimony-resistant parasites [25]. Despite the promise, the underlying mechanism of how the alteration in sterol composition leads to growth retardation and/or parasite death is not well understood, which hinders the development of new and improved treatments [26][28].

The primary target of azole drugs is C14DM (known as CYP51 in animals and ERG11 in yeast), an evolutionarily conserved, heme-dependent, cytochrome P450 enzyme present in fungi, plants, mammals, and trypanosomatids [29] (Fig. S1). The reaction catalyzed by C14DM consists of three steps: the initial oxygenation of 14α-methyl group (–CH3) to 14α-alcohol (–CH2OH), further oxidation to 14α-aldehyde (–CHO), and finally the elimination of formic acid leading to the formation of C14-15 double bond in the sterol core [30]. Mouse C14DM is essential for embryogenesis, as deletion of this gene leads to embryonic lethality at day 15 [31]. In S. cerevisiae, null mutants of ERG11 require exogenous ergosterol to survive and only grow in the absence of oxygen or in the presence of a suppressor mutation in sterol C5-desaturase (ERG3, an enzyme upstream of C14DM) [12], [32][34]. While C14DM appears to be indispensable in mammals and fungi, azole drugs exhibit higher affinity for fungal enzymes over mammalian orthologs which contributes to their selectivity [35].

The C14DMs from several trypanosomatids have been cloned and biochemically characterized [36][38]. Significant efforts have been devoted to identify new and better C14DM inhibitors as anti-T. cruzi agents [18], [39][41]. Biochemical and structural studies of the C14DM from Leishmania infantum indicate that this enzyme prefers C4-monomethylated sterol substrates (such as 4, 14-dimethyl zymosterol), although it also metabolizes C4-dimethylated sterols (e.g. lanosterol) and C4-desmethylated sterols (e.g. 14α-methylzymosterol) with lower efficiency [38] (Fig. S1). This type of substrate preference is similar to the C14DMs in plants and T. brucei [37], [42] but distinct from that in T. cruzi which favors C4-dimethylated sterols [38], [43]. Meanwhile, the C14DMs in mammals and fungi provide rapid demethylation of sterol substrates without obvious restriction (regarding C4-methylation) [38].

The goal of our study is to address the following important yet still unanswered questions about sterol metabolism in Leishmania: Is C14DM essential for the promastigote stage (found in sandflies) and amastigote stage (found in mammals)? What is the role of sterol synthesis in the organization of plasma membrane? Is C14DM the primary target of azoles? How to improve the efficacy of current sterol synthesis inhibitors? To answer these questions, we generated and characterized a C14DM-null mutant in Leishmania major. Our results suggest that inactivation of C14DM severely disrupts the membrane stability of Leishmania parasites, probably due to the accumulation toxic sterol intermediates. Although this is not lethal by itself, it leads to extreme vulnerability to heat stress. The new knowledge will not only provide novel insight into the physiological role of sterol synthesis in Leishmania parasites, but also can guide the development of new treatments or to improve the efficacy of current antileishmanial drugs.

Results

Identification and targeted deletion of C14DM in L. major

L. major C14DM was identified from the TriTrypDB (gene ID: LmjF.11.1100) showing 28–33% identity to the C14DMs from human, fungi, and Mycobacterium tuberculosis (Fig. S2). Its syntenic orthologs are present in the genomes of L. braziliensis, L. infantum, L. mexicana, T. brucei, and T. cruzi. The L. major C14DM protein (479 aa) contains a potential N-terminal signal peptide (M1-F24) and motifs predicted to mediate sterol substrate binding (Y102–V113) and heme binding (G415–G424) [44] (Fig. S2).

Using the targeted gene replacement approach [45], we were able to generate null mutants of C14DM (c14dm ) in L. major promastigotes. Southern-blot confirmed the loss of endogenous C14DM alleles in three independent c14dm clones (Fig. 1A–C). Add-back parasites (c14dm /+C14DM) were generated by introducing pXG-C14DM (a high copy number plasmid containing C14DM) into the mutants (Fig. 1B–C). To determine the localization of C14DM, a C14DM-GFP fusion protein was constructed and expressed in c14dm promastigotes. The integrity and functionality of C14DM-GFP were confirmed by western blot and later by lipid analysis (Fig. S3). Immunofluorescence microscopy revealed a significant overlap between GFP fluorescence and the anti-BiP staining [46], but less so with the mitochondrial marker Mitotracker (Fig. 1D–H). These data suggest that C14DM is mainly located in the endoplasmic reticulum (ER) although a fraction of it may also reside in the mitochondrion. This localization is consistent with its predicted role in sterol biosynthesis and previous reports on C14DMs from S. cerevisiae and rat liver [47], [48].

Figure 1. Targeted deletion and cellular localization of C14DM.

Figure 1

(AC) Genomic DNAs from L. major WT, c14dm+/− (heterozygous knockout), c14dm (homozygous knockout) and c14dm /+C14DM (episomal add-back) parasites were subjected to Southern blot analyses, using radioactive probes from an upstream flanking region (A) or the open reading frame (B) of C14DM. (C) DNA loading control for B (ethidium bromide staining). (DH) Immunofluorescence microscopy of c14dm /+C14DM-GFP promastigotes labeled with an ER marker (left panels) or Mitotracker (right panels). (D) GFP fluorescence (scale bars: 10 µm); (E) Anti-BiP staining (left panel; rabbit anti-T. brucei BiP antiserum followed by goat anti-rabbit IgG-Texas Red) or Mitotracker staining (right panel); (F) Merge of D and E; (G) Hoechst staining of DNA; (H) Differential interference contrast (DIC) images.

C14dm promastigotes are viable and replicative but exhibit altered morphology and cytokinesis defect

In S. cerevisiae, deletion of C14DM (Δerg11) led to ergosterol auxotrophy and cell death under aerobic conditions, possibly due to the production of oxygenated sterol intermediates [32][34]. Surprisingly, L. major c14dm promastigotes were fully viable in culture during the replicative log phase although their doubling time (∼12 hours) was longer than that of wild type (WT) parasites (∼7 hours) (Fig. 2A–2B). Despite the slower growth rate, these mutants reached similar densities as WT parasites (2.3–3.0×107 cells/ml) in stationary phase (Fig. 2A). In late stationary phase, c14dm mutants had slightly more dead cells and produced less metacyclics (the non-replicative but highly infective forms [49]) than WT promastigotes (Fig. 2B–C). In addition, more round cells were detected in c14dm mutants (20–30%) than in WT parasites (5–10%) in both log and stationary phase (Fig. 2D).

Figure 2. C14dm mutants are viable but show defects in growth rate, cell shape and differentiation.

Figure 2

(A) L. major promastigotes were inoculated at 1.0×105 cells/ml and culture densities were measured every 24 hours. After entering stationary phase (72 hours post inoculation, marked by the arrow in A), percentages of dead cells (B), metacyclics (C) and round cells (D) were determined daily. Error bars represent standard deviations from 3 experiments (*: p<0.05, **: p<0.01). Black circle: WT; white circle: c14dm ; black triangle: c14dm /+C14DM.

DNA staining revealed that 15–32% of c14dm promastigotes had two kinetoplasts (containing mitochondrial DNA) and two nuclei (2K2N), whereas only 3–8% of WT parasites were 2K2N (Fig. 3). Similar results were observed in a cell cycle analysis of permeabilized promastigotes labeled with propidium iodide (Fig. S4). These data suggest that sterol synthesis is involved in maintaining normal cytokinesis in Leishmania. Defects manifested by c14dm (growth delay, altered morphology, reduced metacyclogenesis, and overabundance of 2K2N cells) were completely reversed when C14DM expression was restored (c14dm /+C14DM in Figs. 23 and Fig. S4). Therefore, although C14DM is not required for promastigote survival or proliferation in culture, it is involved in the control of cell shape, differentiation, and division in L. major.

Figure 3. C14dm promastigotes exhibit cytokinesis defects.

Figure 3

Log phase promastigotes of WT (AB), c14dm (CF), and c14dm /+C14DM (GH) were stained with Hoechst 33242 and analyzed by fluorescence microscopy. E and F are enlargements of the boxed regions in C and D, respectively. DNA staining results were shown in A, C, E and G. DIC images were shown in B, D, F, and H. (I) Percentages of 2 kinetoplastids-2 nuclei (2K2N) cells were determined in log and day 2 stationary phase (S2) promastigote cultures. Black bars: WT, white bars: c14dm , grey bars: c14dm /+C14DM (*: p<0.05). Experiments were repeated three times (∼200 cells were counted for each cell type in every experiment) and error bars represent standard deviations. Examples of 2K2N cells are marked by arrows in E and F.

C14dm promastigotes have drastically altered sterol composition and show increased resistance to itraconazole (ITZ) and Amp B

The effect of C14DM deletion on sterol synthesis was assessed by gas chromatography-mass spectrometry (GC-MS). Briefly, promastigote lipids were examined by total ion current (“A” in Fig. S5Fig. S8), selected ion spectra (“B–F” in Fig. S5Fig. S8), and the full mass spectra of major sterol species were acquired by electron ionization (Fig. S9). In WT parasites, four major sterol species were identified based on their retention time, formula weights, and electron impact mass spectra as the following: 5-dehydroepisterol (50–57%), ergosterol (22–28%), cholesta-5,7,24-trienol (6–10%), and cholesterol (3–5%) (Fig. 4A, 4E, Fig. S5 and Table S1). Deletion of C14DM led to a complete loss of ergostane-based sterols (5-dehydroepisterol, ergosterol, and episterol) and cholesta-5,7,24-trienol, but the level of cholesterol (salvaged from the medium) was not significantly affected (Fig. 4B, 4E, Fig. S6, and Table S1). Meanwhile, c14dm mutants possessed a new, highly conspicuous sterol peak with a retention time of 14.76–14.78 on GC spectrum (Fig. 4B and Fig. S6). Selected ion analysis revealed that this peak was comprised of two lipid species with formula weights of 398.6 and 412.6 (Fig. S6C and 6F). Based on the role of C14DM in sterol synthesis, these lipids are predicted to be 14-methyl fecosterol (FW = 412.6, XII in Fig. S1) and 14-methyl zymosterol (FW = 398.6, XI in Fig. S1). Together these 14-methylated sterols constitute >95% of total sterols in c14dm (Fig. 4B, 4E, and Table S1). Very similar results were observed when WT parasites of L. major, L. donovani, L. mexicana, and L. amazonensis were cultured in the presence of ITZ (3.3–200 nM), a C14DM inhibitor, for 2 days (Fig. 4C, 4E, Fig. S7, and Table S1). Parasites with episomal C14DM expression (c14dm /+C14DM and c14dm /+C14DM-GFP) had WT-like sterol composition, not elevated amounts of ergostane-based sterols (Fig. 4D, 4E, Fig. S8, Fig. S3B, and Table S1). This may reflect a limitation of substrates and/or a feedback regulation mechanism. It is also worth mentioning that deletion or overexpression of C14DM had no significant impact on the overall abundance of total sterols in Leishmania promastigotes (Table S1).

Figure 4. Accumulation of 14-methylated sterol intermediates and depletion of ergostane-based sterols in c14dm mutants.

Figure 4

(AD) Partial GC chromatograms of lipids from WT (A), c14dm (B), WT + 0.2 µM ITZ (C), and c14dm /+C14DM (D) promastigotes. Cholesta-3,5-diene (retention time = 11.82–11.83 minutes) was added to Leishmania samples prior to lipid extraction as an internal standard (arrowheads). Complete chromatograms were provided in Fig. S58. These analyses were repeated 3 times and percentages of major sterol species were quantified. Results from one representative experiment were summarized in E. The Roman numerals (VIII–XIII) represent sterol species (Fig. S1) and their corresponding peaks are indicated by arrows in AD.

To test whether C14DM is the primary target of ITZ in Leishmania, promastigotes were inoculated in 0–10 µM of ITZ and culture densities were determined after 48 hours. For L. major WT and c14dm /+C14DM parasites, a dose-dependent response was observed (Fig. 5A); the IC25, IC50, and IC90 (concentrations required to inhibit growth by 25%, 50%, or 90%) were estimated to be 0.12 µM, 0.40 µM, and 10 µM, respectively (Fig. 5A and Table 1). Based on our sterol analysis, ITZ could shut down C14DM in WT L. major at fairly low concentrations (50 nM–0.2 µM) but only caused mild growth retardation (Fig. 4C, Table S1 and unpublished data). For c14dm parasites, ITZ had negligible effect on growth at ≤0.2 µM, but did cause dose-dependent inhibition at >0.2 µM similar to WT parasites (Fig. 5A). For these mutants, the IC25, IC50, IC90 were around 0.60 µM, 2.0 µM, and 10 µM, respectively (Fig. 5A and Table 1). These data suggest that ITZ's mode of action is two-fold: at low concentrations (<0.2 µM), the drug mainly exerts its effect by blocking C14DM; and at high concentrations (>0.2 µM), it affects other targets beyond C14DM (Fig. 5A).

Figure 5. C14dm mutants are more resistant to ergosterol synthesis inhibitors.

Figure 5

Log phase promastigotes (black circle: WT; white circle: c14dm ; black triangle: c14dm /+C14DM) were inoculated in M199 media (2×105 cells/ml) in various concentrations of ITZ (A) or Amp B (B). Culture densities were determined after 48 hours and percentages of growth were calculated using cells grown in the absence of drugs as controls. Experiments were repeated three times and error bars represent standard deviations.

Table 1. Susceptibility of c14dm mutants to ITZ and Amp B.

Drug IC25 (µM ± SD) IC50 (µM ± SD) IC90 (µM ± SD)
WT c14dm Ratio WT c14dm Ratio WT c14dm Ratio
ITZ 0.12±0.10 0.60±0.20 1/5 0.40±0.10 2.0±0.3 1/5 10±1.4 10.0±1.0 1
Amp B 0.01±0.006 0.1±0.1 1/10 0.025±0.01 0.9±0.3 1/36 0.05±0.015 5.0±0.4 1/100

L. major WT or c14dm promastigotes were inoculated in M199 medium at 2.0×105 cells/ml in various concentrations of ITZ or Amp B. Culture densities were examined after 48 hours and IC values to achieve 25%, 50%, and 90% inhibition were determined by comparing to control cells grown in the absence of inhibitors. SD: standard deviations from 3 independent experiments. Ratios of IC (WT)/IC (c14dm ) were indicated.

Amp B is another widely-used antifungal/antiprotozoal compound. It binds membrane sterol leading to the formation of channels and subsequent cell lysis. As shown in Fig. 5B and Table 1, c14dm mutants were extremely resistant to Amp B as their IC values were 10–100 times higher than those of WT and c14dm /+C14DM parasites. These findings support the notion that Amp B targets ergostane-based sterols more efficiently than cholesterol-like sterols, which confers selectivity [50], [51]. Similar to ITZ, Amp B exhibited a biphasic inhibition on L. major growth: a C14DM-dependent phase at low concentrations (<0.1 µM) and a C14DM-independent phase at high concentrations (Fig. 5B). Together, these data indicate that: 1) loss of ergostane-based sterols (through genetic or chemical inactivation of C14DM) is not detrimental to promastigotes in culture; and 2) ITZ and Amp B have additional targets in Leishmania beyond the sterol synthesis pathway.

C14dm mutants exhibit significantly altered cell membrane organization

Sterols are key stabilizers of biological membranes. Along with sphingolipids, they promote the formation of ordered membrane microdomains or lipid rafts [9], [52]. The unusual sterol profile in c14dm prompted us to investigate whether sterol synthesis affects the expression and organization of membrane-bound, GPI-anchored virulence factors such as lipophosphoglycan (LPG) and GP63 (an abundant metalloprotease). In both log phase and stationary phase, c14dm mutants had much less LPG than WT and c14dm /+C14DM cells based on western-blot (10–25%, Fig. 6A–C). This was not due to increased shedding/secretion, as the LPG in c14dm culture supernatant was also low (Fig. 6A–B). Similar results were observed by immunofluorescence microscopy and flow cytometry using an anti-LPG antibody (Fig. S10). Meanwhile, these mutants contained more GP63 than WT (∼two-fold increase) in log phase but not in stationary phase or metacyclic promastigotes (similar to WT in these stages; Fig. 6A, B, D and Fig. S11). Therefore, changes in sterol composition do affect the steady state level of GPI-anchored virulence factors.

Figure 6. Altered expression of LPG and GP63 in c14dm mutants.

Figure 6

(AB) Whole cell lysates or culture supernatants (LPG in supe.) from log phase (A) or day 3 stationary phase (B) promastigotes (lane 1: WT, lane 2: c14dm , lane 3: c14dm /+C14DM) were analyzed by Western blot, using antibodies against LPG, GP63, or α-tubulin. (CD) The relative abundance of LPG (C) and GP63 (D) was normalized in log phase, stationary phase, and metacyclic parasites (black bars: WT; white bars: c14dm ; grey bars: c14dm /+C14DM). Error bars represent standard deviations from 3 experiments (*: p<0.05, **: p<0.01).

We also assessed the abundance of LPG and GP63 in liquid-ordered membrane microdomains by examining the DRMs. In mammalian cells and trypanosomatids, GPI-anchored macromolecules tend to be segregated in DRMs at 4°C (but not 37°C), which may reflect their association with cholesterol/sphingolipid- rich domains (lipid rafts) [9], [53]. In WT parasites, LPG was enriched in DRM in late stationary phase (35–38% of total LPG) but not in log phase (only 9–14% of total LPG) (Fig. 7A and G), indicative of a plasma membrane remodeling process during promastigote development as previously proposed [54]. Differing from LPG, GP63 had a clear association with DRM (50–60% of total GP63) in both log phase and stationary phase (Fig. 7C and H), suggesting that it is a constitutive component of lipid rafts. As a control, the cytosolic protein HSP83 was not found in DRM (Fig. 7E) [55]. Importantly, loss of C14DM reduced the DRM-association of GP63 in log phase and stationary phase (from 50–60% in WT to 20–32% in c14dm , Fig. 7C, D, and H); c14dm mutants also had less LPG in DRM than WT during stationary phase (12–15% in c14dm versus 35–38% in WT; Fig. 7A, B, and G); and restoration of C14DM expression reversed these defects (Fig. 7G and H). Collectively, these data indicate that ergostane-based sterols are critical not only for the synthesis and/or trafficking of GPI-anchored virulence factors, but also for their association with liquid-ordered microdomains.

Figure 7. C14dm mutants show reduced LPG and GP63 levels in the detergent resistant membrane (DRM) fractions.

Figure 7

(AF) Log phase and day 3 stationary phase cell lysates from WT (A, C, E) or c14dm (B, D, F) promastigotes were extracted with 1% triton X100 at 4°C or 37°C. Both insoluble (I) and soluble (S) materials were analyzed by Western blot, using antibodies against LPG (AB), GP63 (CD) or HSP83 (EF). Fractions of LPG and GP63 in DRM were quantified and summarized in G and H, respectively. Black bars: WT, white bars: c14dm , grey bars: c14dm /+C14DM. Error bars represent standard deviations from 3 experiments (*: p<0.05, **: p<0.01).

C14dm mutants are highly attenuated in virulence

To determine whether ergosterol synthesis is required for Leishmania survival in mammals, metacyclics were isolated from stationary phase promastigotes and injected into the footpads of BALB/c mice. As indicated in Fig. 8A, WT and c14dm /+C14DM parasites caused rapid progression of lesions and all the mice had to be euthanized within 100 days post infection due to severe pathology. In contrast, mice infected by c14dm did not show any disease for the first 120 days and it took them 180–200 days to develop large lesions (∼2.0 mm). The parasite loads in c14dm -infected mice were also significantly lower than those infected by WT or c14dm /+C14DM parasites at the same time (Fig. 8B). Similar results were obtained when BALB/c mice were infected with lesion-derived amastigotes of WT, c14dm , c14dm /+C14DM parasites (Fig. 8C–D). While LPG is an important virulence factor for L. major promastigotes, it is not required for the infectivity of amastigotes [56]. Thus, the reduced virulence of c14dm cannot be solely attributed to LPG deficiency. Besides mouse infection, we also examined the ability of c14dm mutants to parasitize primary murine macrophages in vitro. Comparing to WT and c14dm /+C14DM parasites, c14dm mutants survived poorly in BALB/c macrophages (Fig. S12). Together, these findings demonstrate that C14DM is extremely important for Leishmania to effectively survive, proliferate, and cause disease in the mammalian host.

Figure 8. C14dm mutants show severely attenuated virulence in BALB/c mice.

Figure 8

BALB/c mice were infected with metacyclics (2×105 parasites/mouse) (A–B) or lesion-derived amastigotes (2×104 parasites/mouse) (C–D). Footpad lesions were recorded weekly and shown in A and C (black circle: WT; white circle: c14dm ; black triangle: c14dm /+C14DM). Parasite numbers in the infected footpads were determined at the indicated times by limiting dilution assay and summarized in B and D (black bars: WT, white bars: c14dm , grey bars: c14dm /+C14DM). Error bars represent standard deviations from 5 mice in each group (**: p<0.01).

The fact that c14dm mutants could still cause disease (at a reduced capacity nonetheless) suggests sterol synthesis is not absolutely essential for Leishmania during the mammalian stage. To investigate the effect of C14DM-deletion on the sterol composition of amastigotes, we isolated WT and c14dm amastigotes from footpad lesions (Fig. S13) and examined their lipid contents by GC-MS (Fig. S1415). For comparison, we also extracted lipids from uninfected mouse footpad tissue (Fig. S16) and promastigotes (Fig. S1718; the RT values here were different from the ones in Figs. 4 and S5S8 because a different GC column was used). Cholesta-3,5-diene was added as an internal standard to both amastigote and promastigote samples (1.0×109 molecules/amastigote and 2.0×107 molecules/promastigote; RT = 11.00 in Fig. S1418). In WT amastigotes, a very high level of cholesterol was evident (RT = 12.87 in Fig. S14A–B), whereas the ergostane-based sterols (ergosterol, 5-dehydroepisterol, and episterol) were almost undetectable (Fig. S14C–D; similar to uninfected mouse tissue in Fig. S16). Clearly, some of the cholesterol was not directly associated with amastigotes (instead from mouse cells; Fig. S13 and Fig. S16). Nonetheless, the lack of endogenous sterols suggests that de novo sterol synthesis is significantly downregulated in amastigotes. This was in sharp contrast to WT promastigotes which had much more ergostane-based sterols than cholesterol (Fig. S17 and Fig. S5). C14dm amastigotes also contained an overwhelming amount of cholesterol (Fig. S15A–B), much more abundant than the 14-methyl sterols (Fig. S15D–E) which were dominant in promastigotes (RT = 13.69 in Fig. S18). Since Leishmania parasites do not synthesize cholesterol [14], [57], these results suggest that amastigotes acquire the majority of their sterols from the host rather than de novo synthesis.

C14dm mutants show reduced cell membrane rigidity and are extremely sensitive to heat stress

Next we investigated whether sterol synthesis was involved in resistance to heat, acidic pH, and reactive oxygen intermediates/reactive nitrogen intermediates (ROIs/RNIs). In order to establish infection in mammals, Leishmania parasites must overcome these stress conditions. To examine if C14DM is required for heat tolerance, stationary phase parasites were incubated at either 27°C (the regular promastigote culture temperature) or 37°C (mimicking the mammalian body temperature). Most parasites were alive at 27°C as expected (Fig. 9A). At 37°C, however, 73–90% of c14dm promastigotes were dead in 12 hours whereas the vast majority of WT and c14dm /+C14DM cells remained viable (Fig. 9B). Similar to c14dm , WT parasites grown in the presence of ITZ from log phase to stationary phase were hypersensitive to 37°C condition (Fig. 9C). In contrast, if WT parasites were cultured without ITZ to stationary phase and then treated with ITZ (which would not significantly affect sterol synthesis since most stationary phase cells were non-replicative), they did not show such defects (Fig. 9D). Therefore, it is the alteration of sterol composition (rather than other effects from ITZ) that is responsible for this hypersensitivity to high temperature.

Figure 9. Inactivation of C14DM leads to extreme sensitivity to heat and increased membrane fluidity.

Figure 9

(A–B) Promastigotes were cultured to stationary phase and half of the cells were maintained at 27°C (A) while the other half was incubated at 37°C/5% CO2 for 12 hours (B). Percentages of dead cells were determined every 4 hours (black bars: WT, white bars: c14dm , grey bars: c14dm /+C14DM). (C) WT (inoculated in the presence or absence of ITZ since early log phase at 2×105 cells/ml) or c14dm parasites were cultured to stationary phase and subjected to 37°C/5%CO2 treatment. Cell viability was measured after 8 hours. (D) ITZ (0.5 µM) was added to either early log phase (2×105 cells/ml) or day 1 stationary phase (S1, ∼2.5×107 cells/ml) WT cultures. After 2 days of incubation, cells were subjected to 37°C/5%CO2 treatment for 8 hours before the percentages of dead cells were measured. (E–F) Log phase (E) and stationary phase (F) promastigotes (black bars: WT, white bars: c14dm , grey bars: c14dm /+C14DM) were analyzed by anisotropy measurement. The rigidity of plasma membrane was determined by measuring the fluorescent depolarization of incorporated TMA-DPH at various temperatures. Experiments in A–F were repeated 3 times and error bars represent standard deviations (*: p<0.05, **: p<0.01).

To determine if the function of C14DM on heat resistance is conserved in other Leishmania species, we grew L. mexicana, L. amazonensis and L. donovani parasites in sub-lethal concentrations of ITZ (3.3 nM for L. mexicana, 25 nM for L. amazonensis, and 81 nM for L. donovani) which were sufficient to shut down ergostane-based sterol synthesis but only inhibit growth by ∼25% (Fig. S19A, Table S1 and S2). Similar to c14dm , these ITZ-treated parasites were extremely vulnerable to heat (Fig. S19B). Therefore, C14DM likely plays similar roles in multiple Leishmania species.

We also tested the ability of c14dm mutants to withstand oxidative, nitrosative and acidic pH stress as previously described [58]. As shown in Fig. S20A–B, these mutants were slightly more sensitive to SNAP (a nitric oxide releaser) than WT and c14dm /+C14DM parasites (although the difference was not statistically significant), which might be due to their low LPG abundance (Fig. 6) [56]. Meanwhile, their resistance to H2O2 and acidic pH were normal (Fig. S20C–F).

Since sterols could function as stabilizers in lipid bilayer [59], we examined whether alteration in sterol composition affects the cell membrane fluidity of c14dm mutants, which may be linked to their heat sensitivity and defects in forming DRM/rafts. To do so, promastigotes were labeled with TMA-DPH (a cationic lipophilic probe that diffuses into the outer leaflet of lipid bilayer) for 20 min at 4°C, 25°C, 37°C, or 45°C (>95% of cells were alive by propidium iodide staining). Plasma membrane fluidity was then determined by measuring the fluorescence depolarization of TMA-DPH as previously described [60]. As indicated in Fig. 9E–F, WT and c14dm /+C14DM parasites maintained their membrane fluidity at a reasonably stable level when the temperature rose from 4°C to 45°C (a high anisotropy value means the membrane is more rigid or less fluid). In contrast, the plasma membrane of c14dm mutants became much more fluid at elevated temperatures (Fig. 9E–F). Therefore, defects in sterol synthesis may compromise cell membrane stability and rigidity at high temperatures, resulting in hypersensitivity to heat.

Discussion

In this study, we investigated the role of C14DM in L. major, a vector-borne protozoan parasite responsible for cutaneous leishmaniasis. C14DM catalyzes the heme-dependent oxidative removal of 14α-methyl group from sterol intermediates, a key step in sterol biosynthesis. Deletion of C14DM in L. major results in a complete loss of ergostane-based sterols and significant accumulation of 14-methylated sterol intermediates. This drastic change of sterol composition leads to increased plasma membrane fluidity, failure to form normal DRM/lipid rafts, and extreme vulnerability to heat. Nonetheless, c14dm mutants are fully viable and replicative as promastigotes in culture with only minor imperfections in growth rate, morphology and cytokinesis. They do exhibit marked defects in the synthesis and/or trafficking of GPI-anchored virulence factors and are more resistant to antifungals such as ITZ and Amp B. The infectivity of c14dm mutants is greatly reduced but not completely abolished, suggesting that inhibition of C14DM by itself is not sufficient to eliminate L. major infection.

It is rather surprising that Leishmania promastigotes remain viable and proliferative without C14DM. In the absence of endogenous sterols, c14dm mutants mainly accumulate 14-methylated intermediates. Similar results were observed when parasites were exposed to sub-lethal concentrations of azoles (Table S1) [57], [61]. Since the overall level of sterols is similar between WT and c14dm parasites (Table S1; only the composition is altered), it appears that 14-methylfecosterol and 14-methylzymosterol could partially compensate the loss of ergostane-based sterol. Other membrane lipids such as sphingolipids, glycerophospholipids, and cholesterol (salvaged from the environment) may also help stabilize the plasma membrane in Leishmania. However, the aberrant sterol composition in c14dm does have serious consequences as these mutants fail to maintain proper membrane rigidity at elevated temperatures, which probably contributes to their hypersensitivity to mild heat (although other mechanisms may also be involved). Inactivation of C14DM also seems to interfere with the formation of liquid-ordered microdomains, as the DRMs from c14dm is depleted of GP63 and LPG which should be enriched in lipid rafts. One possibility is that protrusion of axial 14α-methyl group from the planar 4-ring core structure decreases the interaction between sterols and phospholipid side chains [62], [63]. Consequently, compared to regular sterols (which possess a smooth α-side), 14α-methylated sterols may be less efficient at promoting the condensation of lipid bilayer, leading to increased membrane fluidity (especially at elevated temperatures) in c14dm [61], [64] [65], [66]. Additionally, the loss of ergostane-based sterols (besides the accumulation of 14α-methylated sterols) may also contribute to these membrane defects. It has been reported that ergosterol is more effective at promoting the liquid-ordered phase than lanosterol (which also contains the 14α-methyl group) [67], [68].

The altered shape of c14dm mutants is likely caused by increased membrane permeability due to high fluidity, allowing more water penetration as previously shown in S. cerevisiae treated with fluconazole [69]. C14dm mutants also have more 2K2N cells which have completed DNA replication but are slow to finish division, consistent with their prolonged doubling time. In mammalian cells, cholesterol starvation induced growth arrest at G2 phase and polyploidy formation [70], [71]. In S. cerevisiae, sterol depletion led to growth arrest at G1 stage [12]. Addition of cholesterol and ergosterol at hormonal amounts reversed these effects in mammalian cells and yeasts, respectively [12]. This indicates that in addition to its membrane function, sterols also possess a signaling role in fungi and mammals.

As promastigotes, c14dm mutants cannot be rescued by exogenous ergosterol when provided at nM-µM range, suggesting that: 1) the accumulation of 14-methylated sterol intermediates (rather than the lack of ergostane-based sterols) is primarily responsible for the defects in membrane stability, heat resistance and replication; or 2) the uptake of ergosterol by Leishmania is insufficient although cholesterol can be incorporated into the membrane. Loss of C14DM also affects the synthesis and/or trafficking of major GPI-anchored virulence factors, as c14dm mutants contain less LPG but more GP63 (only in the log phase) than WT parasites. Previous studies suggest that the synthesis of LPG and GP63 starts with a common pool of alkyl-acyl-PIs with long alkyl chains (C24:0/C26:0), followed by differential glycosylation and fatty acid remodeling in separate compartments [72], [73]. Alteration in sterol composition may compromise the vesicular trafficking or the proper compartmentalization of these pathways, causing abnormality in GPI-molecule synthesis.

The hypersensitivity of c14dm mutants to heat is probably a key contributing factor to their severely reduced virulence in mice. The LPG deficiency could partially explain the virulence defect of c14dm promastigotes but is unlikely to be a major factor for amastigotes since LPG is not required during the mammalian stage of L. major [74]. Besides heat tolerance, the synthesis of ergostane-based sterols is likely needed for other purposes. In L. amazonensis, ketoconazole (another azole drug targeting C14DM) treatment induced the appearance of large multivesicular bodies, increased amounts of lipid droplets and acidocalcisomes (calcium- and phosphate-rich organelles) [75], and alterations in the distribution and appearance of mitochondrial cristae [76], [77]. L. amazonensis parasites exposed to 22,26-azasterol, a sterol methyltransferase inhibitor, also exhibited profound morphological changes including mitochondrial swelling, increased number of acidocalcisomes, and the appearance of large, membranous bodies reminiscent of autophagic vesicles [22]. Comparing to Leishmania promastigotes, intracellular amastigotes show a global decrease in the uptake and utilization of glucose and amino acids, but are more dependent on mitochondrial metabolism (for TCA cycle and glutamine synthesis) [78]. Thus, perturbation of mitochondrial structure/function may be an underlying mechanism for the anti-proliferative effect of sterol synthesis inhibitors.

Importantly, after a delay of 70–120 days, c14dm -infected mice started to show symptom (footpad swelling) and eventually produced lesions similar to WT-infected mice. Mutant parasites were also capable of proliferation after the initial delay. Promastigotes and amastigotes isolated from c14dm -infected mice were still attenuated (Fig. 8), suggesting that this is not due to reversion or compensatory mutations. Hence, despite their profound defects, c14dm mutants are still somewhat virulent. One possibility is that Leishmania amastigotes salvage huge amounts of host lipids including cholesterol and sphingolipids [79][81], which may alleviate the loss of de novo synthesis and/or accumulation of toxic sterols. This is supported by our amastigote lipid analysis which showed significant accumulation of cholesterol (host-derived) and only trace amount of endogenous sterols (Fig. S1318).

The fact that c14dm mutants are viable as promastigotes and infective in mice (at a reduced capacity) suggests that inhibition of C14DM by itself may not be sufficient to cure Leishmania infection. In vitro, azole drugs such as ketoconazole, fluconazole, itraconazole, and posaconazole have shown activity against the growth of Leishmania and Trypanosoma cruzi (responsible for Chagas disease), yet their in vivo efficacies remain somewhat unsatisfactory [39], [82][85]. These drugs are often limited by poor pharmacokinetics (difficulties in formulation, delivery and bioavailability) [86] and emergence of resistance (e.g. increased drug efflux and mutations in the target gene) [86]. Findings from our study suggest that the efficacy of azoles may improve if they are used in combination with localized heat treatment. Thus, although C14DM inhibition only exerts modest anti-Leishmania effect, it does make parasites vulnerable to other physical or chemical perturbations.

For Leishmania promastigotes, ITZ (and possibly other azoles) treatment seems to be mimic the effect of C14DM deletion at low concentrations but it clearly inhibits other unknown targets at high concentrations (Fig. 5A and Fig. S19A). Based on our findings, it may be worthwhile to explore whether inhibitors of sphingolipid/phospholipid synthesis can exacerbate the membrane instability of c14dm mutants. If so, combined inhibition of multiple lipid synthesis pathways may have synergistic effect on parasite survival. Our findings also indicate that mutations in C14DM can confer significant resistance to Amp B, although the fitness costs associated with such mutations could be therapeutically exploited.

In summary, genetic or chemical inactivation of C14DM in Leishmania results in dramatic change in sterol composition, leading to DRM/raft disruption, increased membrane fluidity, and impairment in the synthesis and/or trafficking of GPI-anchored molecules. Ablating C14DM is not detrimental in L. major, perhaps due to the compensatory effect of other lipids, but does render parasites extremely vulnerable to heat. These findings may guide the development of new therapies which would improve the efficacies of current treatments and exploit the fitness cost of drug resistant strains. In addition, future studies will determine the mechanistic basis of c14dm -associated defects, e.g. whether they are mainly caused by membrane perturbations or dysregulation of intracellular pathways. The viability of c14dm mutants also provides a valuable platform to study the roles of DRM/rafts in crucial events such as vesicular trafficking and signaling. Finally, the interaction between Leishmania amastigotes and host cells at sterol metabolism, e.g. de novo synthesis vs salvage is another important topic worthy of further studies.

Materials and Methods

Materials

BALB/c (female, 7–8 weeks old) mice were purchased from Charles River Laboratories International (Wilmington, MA). All procedures involving mice were approved by the Animal Care and Use Committee at Texas Tech University (PHS Approved Animal Welfare Assurance No. A3629-01). Mice were housed and cared for in the facility operated by the Animal Care and Resources Center at Texas Tech University adhering to the Guide for the Care and Use of Laboratory Animals (the 8th Edition, NRC 2011) for animal husbandry. Reasonable efforts were made to minimize animal suffering. Anesthesia was applied through intra-peritoneal injection of ketamine hydrochloride (100 mg/kg)/xylazine (10 mg/kg). Euthanasia was achieved by asphyxiation through controlled flow of pure CO2.

Zymosterol, lanosterol, cholesterol, ergosterol and 5-dehydroergosterol were purchased from Avanti Polar Lipids (Birmingham, AL) as standards (to determine retention times) in gas chromatography-mass spectrometry (GC-MS) studies. Cholesta-3,5-diene was purchased from Sigma-Aldrich (St. Louis, MO) as an internal standard for quantitation in total ion current chromatograms. Itraconazole (ITZ) was purchased from LKT Laboratories, Inc. (St. Paul, MN). Amphotericin B (Amp B) and 30% H2O2 were purchased from EMD Chemicals, Inc. (San Diego, CA). 1-(4-Trimethylammoniumphenyl)-6-Phenyl-1,3,5-Hexatriene p-Toluenesulfonate (TMA-DPH) was purchased from Life Technologies Corporation (Grand Island, NY). All other chemicals were purchased from VWR International or Fisher Scientifics unless specified otherwise.

Molecular constructs

The predicted open reading frame (ORF) of L. major C14DM (LmjF.11.1100) was amplified by PCR from L. major genomic DNA using primers #170/#171. The resulting 1.44 Kb DNA fragment was digested with BglII and cloned in the pXG vector [87] as pXG-C14DM (B294). A modified C14DM-ORF was amplified with primers #170/#333 to remove the stop codon and cloned into the pXG-'GFP+ vector [87] to generate pXG-C14DM-GFP (B321), which was used to generate a C-terminal GFP fusion protein for the localization study.

The upstream and downstream flanking sequences (∼1 Kb each) of C14DM ORF were amplified with primers #172/#173 and primer #174/#175, respectively. These two PCR products were cloned together into pUC18. Genes conferring resistance to the puromycin (PAC) and blasticidin (BSD) were inserted between the upstream and downstream flanking sequences to generate pUC-KO-C14DM::PAC (B292) and pUC-KO-C14DM::BSD (B293). Primers used in this study were summarized in Table S3. All DNA constructs were confirmed by restriction enzyme digestion and sequencing.

Leishmania culture, genetic manipulations, and Southern blot

L. major LV39 clone 5 (Rho/SU/59/P), L.(L) amazonensis (MHOM/BR/77/LTB0016), L. (L) mexicana M379 (MNYC/BZ/62/M379) and L. donovani 1S2D (MHOM/SD/62/1S) promastigotes were cultured at 27°C in M199 medium (pH 7.4) with 10% fetal bovine serum and additional supplements [88]. In general, log phase promastigotes refer to replicative parasites at densities lower than 1.0×107 cells/ml, and stationary phase promastigotes refer to non-replicative parasites at densities higher than 2.0×107 cells/ml. The infective metacyclic parasites (metacyclics) were isolated from stationary phase promastigotes using the density centrifugation method [89].

To generate C14DM-null mutants (c14dm or ▵C14DM::PAC/▵C14DM::BSD), the C14DM alleles from wild type L. major parasites (WT) were sequentially replaced by PAC and BSD resistance genes using the homologous recombination-based approach as previously described [90]. To confirm the loss of C14DM, genomic DNAs were digested with SacI, resolved on a 0.7% agarose gel, transferred to a nitrocellulose membrane, and hybridized with a [32P]-labeled DNA probe recognizing either the C14DM ORF or a ∼500-bp upstream region of C14DM. Blots were then visualized by radiography. The c14dm mutants were maintained in media containing 10 µg/ml of puromycin and 10 µg/ml of blasticidin. To restore C14DM expression, pXG-C14DM or pXG-C14DM-GFP was introduced into c14dm by electroporation and stable transfectants were referred to as c14dm /+C14DM or c14dm /+C14DM-GFP, respectively. Three independent c14dm mutant clones were generated and their phenotypes were nearly identical. Therefore, c14dm #1 and its add-back control were described in this study.

Cell growth, stress response and drug sensitivity

To measure promastigote growth, parasites were inoculated in complete M199 medium at 1.0×105 cells/ml. Culture density was determined at designated times using a hemacytometer. Percentages of round cells (defined as those with the long axis shorter than twice the length of the short axis) and dead cells were determined by microscopy and flow cytometry, respectively, as previously described [91].

To assess thermal tolerance, stationary phase promastigotes were incubated at either 27°C (the regular temperature) or 37°C/5%CO2 and cell viability were determined after 0–12 hours [58]. To measure sensitivity to oxidative and nitrosative stress, stationary phase promastigotes were incubated in various concentrations of H2O2 or S-nitroso-N-acetylpenicillamine (SNAP) [92]; cell density and viability were determined after 48 hours. To determine sensitivity to acidic pH, stationary phase promastigotes were inoculated in a pH 5.0 medium at 2.5×107 cells/ml and culture densities were determined after 48 hours [58].

To test drug sensitivity, promastigotes were inoculated in M199 medium at 2.0×105 cells/ml in the presence of ITZ (0–10 µM) or Amp B (0–10 µM). Culture densities were determined after 48 hours.

Western blot, immunofluorescence microscopy and flow cytometry

To collect whole cell lysates, promastigotes were washed once in PBS and resuspended at 5.0×107 cells/ml in 1× SDS sample buffer. Supernatants were collected from log and stationary phase cultures after centrifugation. To generate detergent resistant membrane fractions (DRMs), promastigotes were washed once in PBS and extracted with 1% of TritonX-100 (at 1.0×108 cells/ml) for 10 minutes at 4°C or 37°C. Detergent-soluble and -insoluble fractions were separated by centrifugation at 14,000 g for 2 minutes. An equal volume of 2 × SDS sample buffer was added to the detergent soluble fraction and two volumes of 1 × SDS sample buffer were added to the detergent insoluble fraction [53]. Samples were boiled for 5 minutes before SDS-PAGE. After transfer to PVDF membranes, blots were probed with either mouse-anti-LPG monoclonal antibody WIC 79.3 (1∶1000) [93], or mouse-anti-GP63 monoclonal antibody #235 (1∶1000) [94], followed by a goat anti-mouse IgG conjugated with HRP (1∶2000). For C14DM-GFP, blots were probed with a rabbit anti-GFP HRP-conjugated antibody (1∶5000). For loading controls, blots were probed with a mouse-anti-α-tubulin antibody or a rabbit anti-Leishmania HSP83 antibody. A FluorChem E system (Protein Simple) was used to detect and quantify signals.

For LPG/GP63 localization, formaldehyde-fixed parasites were attached to poly-lysine coated cover slips and permeabilized with ice-cold ethanol. Cells were labeled with either mouse-anti-LPG antibody WIC79.3 or mouse-anti-GP63 antibody (both at 1∶2000 dilution in 2% bovine serum albumin prepared in PBS) for 20 minutes, and then incubated with a goat anti-mouse IgG-FITC (1∶1000 dilution) for 20 minutes. For C14DM-GFP localization, c14dm /+C14DM-GFP parasites were labeled with a rabbit anti-T. brucei BiP antiserum (1∶10,000) [46] for 30 minutes and then incubated with a goat anti-rabbit IgG-Texas Red antibody (1∶1000 dilution) for 30 minutes. For mitochondrial staining, 1×106 parasites were centrifuged at 1000 g for 10 minutes, resuspended in 350 nM of Mitotracker Red 580 (Life technologies) in darkness; after 30 minutes, cells were washed in PBS once, and fixed with 3.7% formaldehyde; cells were then transferred to poly-L-lysine coated coverslips by centrifugation (462 g for 5 minutes), washed by 50% methanol, and stained with 1.0 µg/ml of Hoechst 33342 for 10 minutes. Images were acquired using an Olympus BX51 Upright Fluorescence Microscope equipped with a digital camera.

Flow cytometry analyses for cell viability, DNA content, and surface LPG expression were performed as previously described [53] [95], [96], using a BD Accuri C6 flow cytometer.

Sterol analysis by gas chromatography/mass spectrophotometry (GC-MS)

Total lipids were extracted according to a modified Folch's protocol [97]. Briefly, promastigotes were resuspended in chloroform: methanol (2∶1) at 1.0×108 cells/ml and vortexed for 30 seconds. An internal standard, cholesta-3,5-diene (FW = 368.84), was added to cell extract at 2.0×107 molecules/cell (or 1.2 µg/108 promastigotes). Cell debris was removed by centrifugation (1000 g for 10 minutes) and the supernatant was washed with 0.2 volume of 0.9% NaCl. After centrifugation, the aqueous layer was removed and the organic phase was dried under a stream of air. Lipid samples were then dissolved in methanol at the equivalence of 1.0×109 cells/ml. Lesion amastigotes were purified from infected mice as previously described [98]. Amastigote lipids were then extracted following the same procedure as promastigote samples except that the internal standard (cholesta-3,5-diene) was provided at 1.0×109 molecules/amastigote (due to the high cholesterol level) or 30 µg/5×107 amastigotes/footpad. Lipid from uninfected mouse footpads also contained the internal standard (30 µg/footpad).

Electron impact GC/MS analyses of sterol lipids were performed on a Thermo Scientific ISQ (San Jose, CA) single-stage quadrupole mass spectrometer with Trace GC controlled by Thermo Xcalibur 2.1 software. The extract (1 µL) was injected in a splitless mode and analyzed by GC on a Phenomenex (Torrance, CA) ZB-50 column (15 m, 0.32 mm id, 0.5 µm film thickness). The initial temperature of GC was set at 100°C for 2 min, increased to 200°C at a rate of 50°C/min, and then raised to a final temperature of 300°C at a rate of 10°C/min (and then maintained at 300°C for 10 min). Temperatures of the injector, transfer line of the GC column, and of the ion-source were set at 280°C, 280°C, and 220°C, respectively. The full scan mass spectra (50 to 500 Dalton) or total ion current chromatograms were acquired at a rate of 1 scan/0.2 sec. Electron ionization mass spectra of major Leishmania sterols were performed at 70 eV. Pure sterol standards (zymosterol, lanosterol, cholesterol, ergosterol and 5-dehydroergosterol) were also analyzed to obtain their electron impact mass spectra and GC retention times.

Macrophage infection and mouse footpad infection

Bone marrow derived macrophages were isolated from BALB/c mice as previously described [58]. Macrophage infection was performed using metacyclic promastigotes (opsonized with C57BL6 mouse serum) at a ratio of five parasites per macrophage [99].

Footpad infections of BALB/c mice were performed as previously described [58] using metacyclic promastigotes (2.0×105 cells/mouse) or lesion-derived amastigotes (2.0×104 cells/mouse) [100]. Lesion size (the thickness of infected footpad minus the thickness of uninfected footpad) was measured weekly using a Vernier caliper. Parasite numbers in the infected footpad were determined by the limiting dilution assay [101].

Anisotropy assay

The plasma membrane fluidity of live Leishmania promastigotes was determined by measuring the fluorescence depolarization of TMA-DPH, as previously described for T. brucei [60]. Parasites were washed once with and resuspended in PBS at a density of 5.0×106 cells/mL. TMA-DPH was added to a final concentration of 0.5 µM and allowed to stain the cell membrane for 20 min at 4°C, 25°C, 37°C, or 45°C in the dark. Anisotropic values were acquired using a T-mode Photon Technology International (Lawrenceville, NJ) C61/2000 spectrofluorimeter. Samples were excited at 358 nm, and emission was read at 430 nm, with 10-nm excitation and emission slit widths. Temperature was maintained by means of the PerkinElmer LS55 Biokinetics accessory. Data were corrected for light scattering with an unlabeled sample of cells, and anisotropy was calculated according to the equation r  =  (IVV − GIVH)/(IVV + 2GIVH), where r is the anisotropy value, IVV is the emission intensity acquired with the excitation- and emission-polarizing filters set vertically, G is the instrument correction factor, and IVH is the emission intensity acquired with the excitation-polarizing filter set vertically and the emission-polarizing filter set horizontally. Data points shown are the average of triplicate measurements with standard deviations.

Statistical analysis

Most experiments (except for the Southern blot in Fig. 1) were repeated at least three times. The difference between two groups was determined by the Student's t test using Sigmaplot 11.0 (Systat Software Inc, San Jose, CA). P values indicating statistical significance were grouped into values of <0.05 and <0.01.

List of accession numbers/ID numbers

  • Leishmania major C14DM: LmjF11.1100 (TritrpDB)

  • Homo sapiens C14DM: Q16850 (Genbank)

  • Aspergillus fumigatus C14DM: XP_752137 (Genbank)

  • Candida albicans C14DM: XP_716822 (Genbank)

  • Mycobacterium tuberculosis C14DM: NP_215278 (Genbank)

  • Leishmania major squalene epoxidase: LmjF.13.1620 (TritrpDB)

  • Leishmania major squalene synthase: LmjF.31.2940 (TritrpDB)

  • Leishmania major delta(24)-sterol C-methyltransferase: LmjF.36.2380 and LmjF.36.2390 (TritrpDB)

Supporting Information

Figure S1

Predicted sterol synthesis pathway in Leishmania from lanosterol to ergosterol. I–XIII represent sterol intermediates or final products (formula weights in parentheses). I: lanosterol (426.7); II: 4,14-dimethyl-8,24-cholestadienol (412.7); III: 4-methyl-8,24-cholestadienol (398.6); IV: zymosterol (384.6); V: fecosterol (398.6); VI: cholesta-7,24-dienol (384.6); VII: episterol (398.6); VIII: cholesta-5,7,24-trienol (382.6); IX: 5-dehydroepisterol (396.6); X: ergosterol (396.6); XI: 14-methyl-zymosterol (398.6); XII: 14-methyl-fecosterol (412.6); XIII: cholesterol (386.6). C14DM: Sterol C14α-demethylase (the blue circle marks the C14-methyl group to be removed by C14DM). SMT: Sterol C24-methyl transferase. VIII, IX and X represent final sterol products synthesized by Leishmania; XIII (cholesterol, shaded) is salvaged from the host or environment; XI and XII (in red) represent the accumulated sterol intermediates when C14DM is blocked.

(PDF)

Figure S2

Alignment of C14DMs from L. major (LmjF11.1100), H. sapiens (Q16850), A. fumigatus (XP_752137), C. albicans (XP_716822), and M. tuberculosis (NP_215278). Highly conserved residues are highlighted in black. The asterisks mark the predicted sterol substrate binding site and the box indicates the predicted heme binding motif.

(PDF)

Figure S3

The C14DM-GFP fusion protein is intact and functional. (A) Log and day 3 stationary phase cell lysates from c14dm and c14dm /+C14DM-GFP parasites were analyzed by Western blot, using antibodies against GFP (upper panel) or α-tubulin (lower panel). (B) Partial GC-MS chromatogram of lipids from c14dm /+C14DM-GFP promastigotes. VIII-X represent sterol species (shown in Fig. S1 and Fig. 4 ) and their corresponding peaks are indicated by arrows.

(PDF)

Figure S4

Accumulation of tetraploid cells in c14dm mutants. Log phase (AC) or stationary phase (DF) promastigotes of WT (A, D), c14dm (B, E), and c14dm /+C14DM (C, F) were fixed, permeablized and treated with RNase before staining with propidium iodide. Following flow cytometry, percentages of 1K1N and 2K2N cells are indicated. More 2K2N cells were observed in log phase when cells were more replicative.

(PDF)

Figure S5

Sterol analysis in WT promastigotes. Total lipids were extracted from WT promastigotes and analyzed by GC-MS. (A) Total ion current (TIC) chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity (an arbitrary unit reflecting the abundance of the major ion) is indicated on the right.

(PDF)

Figure S6

Sterol analysis in c14dm promastigotes. Total lipids from c14dm promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S7

Sterol analysis in WT promastigotes treated with ITZ. WT promastigotes were inoculated at 2.0×105 cells/ml in the presence of ITZ (0.2 µM). Total lipids were extracted after three days and analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S8

Sterol analysis in c14dm /+C14DM promastigotes. Total lipids were extracted from c14dm /+C14DM promastigotes and analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S9

Electron ionization mass spectra of Leishmania sterols. Lipids from WT or c14dm promastigotes were analyzed by GC-MS. Electron ionization spectra (70 eV) of sterol species based on retention time (RT) in Fig. S5S8 were included. The predicted sterol types were indicated above each panel.

(PDF)

Figure S10

Reduced LPG expression in c14dm mutants. Log phase promastigotes of WT (AC), c14dm (D–F) and c14dm /+C14DM (G–I) were examined by immunofluorescence microscopy. A, D, and G: immune-staining with anti-LPG monoclonal antibody WIC 79.3, followed by a goat-anti-mouse IgG-FITC; B, E, and H: DNA staining using Hoechst 33242; C, F, and I: DIC images. (JL) Log phase promastigotes of WT (L) or c14dm (K) were labeled with anti-LPG antibody, followed by goat-anti-mouse IgG-FITC and then analyzed by flow cytometry. L: merge of J and K.

(PDF)

Figure S11

Enhanced GP63 expression in log phase c14dm mutants. Log phase promastigotes of WT (AC), c14dm (D–F) and c14dm /+C14DM (G–I) were examined by immunofluorescence microscopy. A, D, and G: immuno-staining with a monoclonal anti-GP63 antibody, followed by a goat-anti-mouse IgG-FITC; besides plasma membrane, GP63 was also found intracellularly; B, E, and H: DNA staining using Hoechst 33242; C, F, and I: DIC images.

(PDF)

Figure S12

C14dm parasites survive poorly in murine macrophages (MΦs). Purified metacyclics (black circle: WT; white circle: c14dm ; black triangle: c14dm /+C14DM) were used to infect bone marrow MΦs from BALB/c mice. To show that MΦs possess microbicidal activity, WT parasites were also used to infect MΦs that were activated with 50 ng/ml of LPS and 50 ng/ml of IFN-γ (white triangle). Fraction of infected MΦs (A) and number of parasites per 100 MΦs (B) were recorded. Error bars represent standard deviations from triplicates.

(PDF)

Figure S13

Isolated lesion amastigotes. L. major WT amastigotes were isolated from infected BALB/c mice (footpads) and subjected to fluorescence microscopy. (A) DIC image; (B) DNA staining; (C) merge of A and B. Arrows indicate amastigotes and arrowheads indicate mouse cells/debris.

(PDF)

Figure S14

Analysis of sterols in WT amastigotes. Total lipids from WT lesion amastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S15

Analysis of sterols in c14dm amastigotes. Total lipids from c14dm amastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S16

Analysis of sterols in uninfected mouse tissue. Total lipids from uninfected mouse footpads were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S17

Analysis of sterols in WT promastigotes. Total lipids from WT promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B)–(F) Selected ion monitoring of sterol species with m/z of 386–387 (B), 396–397 (C), 398–399 (D), 412–413 (E), and 382–383 (F). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S18

Analysis of sterols in c14dm promastigotes. Total lipids from c14dm promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B)–(F) Selected ion monitoring of sterol species with m/z of 386–387 (B), 396–397 (C), 398–399 (D), 412–413 (E), and 382–383 (F). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S19

ITZ treatment leads to extreme sensitivity to heat in several Leishmania species. (A) Log phase promastigotes of L. major LV39 (black circle), L. amazonensis (white circle), L. mexicana (black triangle) and L. donovani (white triangle) were cultured in various concentrations of ITZ. Culture densities were determined after 48 hours. (B) Promastigotes were grown in the absence or presence of ITZ (at IC25 concentrations) to stationary phase. Cells were then incubated at 37°C/5% CO2 and cell viability was measured after 8 hours (black bars: L. major LV39, white bars: L. amazonensis, dark grey bars: L. mexicana, light grey bar: L. donovani). Experiments were repeated three times and error bars represent standard deviations.

(PDF)

Figure S20

Ability of c14dm mutants to survive nitrosative, oxidative and acidic pH stress. Stationary phase promastigotes of WT (black circle, black bars), c14dm (white circle, white bars), and c14dm /+c14dm (black triangle, grey bars) were treated with various concentrations of SNAP (A–B), H2O2 (C–D), or incubated in pH 5.0 media (E–F). Cell density and percentage of dead cells were measured after 48 hours. Experiments were repeated three times and error bars represent standard deviations.

(PDF)

Table S1

Sterol composition in Leishmania promastigotes. Promastigotes were cultured in the absence or presence of ITZ (provided at IC25 concentrations: 120 nM for L. major, 81 nM for L. donovani, 3.3 nM for L. mexicana, and 25 nM for L. amazonensis) from early log phase to day 1 stationary phase and total lipids were analyzed by GC-MS. Abundances of ergosterol, 5-dehydroepisterol, cholesterol, cholesta-5,7,24-trienol, 14-methyl sterols (14-methylfecosterol + 14-methylzymosterol), and total sterols were estimated in relation to the internal standard cholesta-3,5-diene (provided at 2.0×107 molecules/cell). Analyses were repeated 3 times and averaged values ± standard deviations (SDs) were shown. ND: not detectable.

(PDF)

Table S2

Susceptibility of Leishmania parasites to ITZ (IC values in µM). Promastigotes were inoculated at 2.0×105 cells/ml in various concentrations of ITZ and culture densities were determined after 48 hours. IC25, IC50, and IC90 are ITZ concentrations that inhibit growth by 25%, 50%, and 90%, respectively, in comparison to control cultures (no ITZ). Experiments were performed three times (average ± SD).

(PDF)

Table S3

List of oligonucleotides used in this study. Sequences in lowercase represent restriction enzyme recognition sites.

(PDF)

Acknowledgments

We thank Patrick Pallus and Mattie Pawlowic for technical assistance. Rabbit antibodies again Leishmania GP63, Leishmania HSP83, and T. brucei BiP were kindly provided by Dr. KP Chang (Rosalind Franklin University), Dr. Dan Zilberstein (Technion Israel Institute of Science), and Dr. Jay Bangs (University at Buffalo, State University of New York), respectively.

Data Availability

The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.

Funding Statement

This work was funded by National Institutes of Health (http://www.nih.gov/) grants AI099380 (KZ), DK056341 (FFH), GM103422 (FFH), and RR000954 (FFH). The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

  • 1. Bern C, Maguire JH, Alvar J (2008) Complexities of assessing the disease burden attributable to leishmaniasis. PLoS Negl Trop Dis 2: e313. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 2. Murray HW, Berman JD, Davies CR, Saravia NG (2005) Advances in leishmaniasis. Lancet 366: 1561–1577. [DOI] [PubMed] [Google Scholar]
  • 3. Desjeux P (2004) Leishmaniasis: current situation and new perspectives. Comp Immunol Microbiol Infect Dis 27: 305–318. [DOI] [PubMed] [Google Scholar]
  • 4. Croft SL, Olliaro P (2011) Leishmaniasis chemotherapy–challenges and opportunities. Clin Microbiol Infect 17: 1478–1483. [DOI] [PubMed] [Google Scholar]
  • 5. Ginger ML, Prescott MC, Reynolds DG, Chance ML, Goad LJ (2000) Utilization of leucine and acetate as carbon sources for sterol and fatty acid biosynthesis by Old and New World Leishmania species, Endotrypanum monterogeii and Trypanosoma cruzi. Eur J Biochem 267: 2555–2566. [DOI] [PubMed] [Google Scholar]
  • 6. Goldstein JL, Brown MS (1990) Regulation of the mevalonate pathway. Nature 343: 425–430. [DOI] [PubMed] [Google Scholar]
  • 7. Gaylor JL (2002) Membrane-bound enzymes of cholesterol synthesis from lanosterol. Biochem Biophys Res Commun 292: 1139–1146. [DOI] [PubMed] [Google Scholar]
  • 8. Brown DA, London E (1998) Functions of lipid rafts in biological membranes. Annu Rev Cell Dev Biol 14: 111–136. [DOI] [PubMed] [Google Scholar]
  • 9. Schroeder RJ, Ahmed SN, Zhu Y, London E, Brown DA (1998) Cholesterol and sphingolipid enhance the Triton X-100 insolubility of glycosylphosphatidylinositol-anchored proteins by promoting the formation of detergent-insoluble ordered membrane domains. J Biol Chem 273: 1150–1157. [DOI] [PubMed] [Google Scholar]
  • 10. Daum G, Lees ND, Bard M, Dickson R (1998) Biochemistry, cell biology and molecular biology of lipids of Saccharomyces cerevisiae. Yeast 14: 1471–1510. [DOI] [PubMed] [Google Scholar]
  • 11. Swan TM, Watson K (1998) Stress tolerance in a yeast sterol auxotroph: role of ergosterol, heat shock proteins and trehalose. FEMS Microbiol Lett 169: 191–197. [DOI] [PubMed] [Google Scholar]
  • 12. Dahl C, Biemann HP, Dahl J (1987) A protein kinase antigenically related to pp60v-src possibly involved in yeast cell cycle control: positive in vivo regulation by sterol. Proc Natl Acad Sci U S A 84: 4012–4016. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13. Payne AH, Hales DB (2004) Overview of steroidogenic enzymes in the pathway from cholesterol to active steroid hormones. Endocr Rev 25: 947–970. [DOI] [PubMed] [Google Scholar]
  • 14. Goad LJ, Holz GG Jr, Beach DH (1984) Sterols of Leishmania species. Implications for biosynthesis. Mol Biochem Parasitol 10: 161–170. [DOI] [PubMed] [Google Scholar]
  • 15. Urbina JA, Concepcion JL, Rangel S, Visbal G, Lira R (2002) Squalene synthase as a chemotherapeutic target in Trypanosoma cruzi and Leishmania mexicana. Mol Biochem Parasitol 125: 35–45. [DOI] [PubMed] [Google Scholar]
  • 16. Zakai HA, Zimmo S, Fouad MA (2003) Effect of itraconazole and terbinafine on Leishmania promastigotes. J Egypt Soc Parasitol 33: 97–107. [PubMed] [Google Scholar]
  • 17. Zakai HA, Zimmo SK (2000) Effects of itraconazole and terbinafine on Leishmania major lesions in BALB/c mice. Ann Trop Med Parasitol 94: 787–791. [DOI] [PubMed] [Google Scholar]
  • 18. Buckner F, Yokoyama K, Lockman J, Aikenhead K, Ohkanda J, et al. (2003) A class of sterol 14-demethylase inhibitors as anti-Trypanosoma cruzi agents. Proc Natl Acad Sci U S A 100: 15149–15153. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 19. Consigli J, Danielo C, Gallerano V, Papa M, Guidi A (2006) Cutaneous leishmaniasis: successful treatment with itraconazole. Int J Dermatol 45: 46–49. [DOI] [PubMed] [Google Scholar]
  • 20. Beach DH, Goad LJ, Holz GG Jr (1988) Effects of antimycotic azoles on growth and sterol biosynthesis of Leishmania promastigotes. Mol Biochem Parasitol 31: 149–162. [DOI] [PubMed] [Google Scholar]
  • 21. Haughan PA, Chance ML, Goad LJ (1995) Effects of an azasterol inhibitor of sterol 24-transmethylation on sterol biosynthesis and growth of Leishmania donovani promastigotes. Biochem J 308 (Pt 1): 31–38. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22. Rodrigues JC, Attias M, Rodriguez C, Urbina JA, Souza W (2002) Ultrastructural and biochemical alterations induced by 22,26-azasterol, a delta(24(25))-sterol methyltransferase inhibitor, on promastigote and amastigote forms of Leishmania amazonensis. Antimicrob Agents Chemother 46: 487–499. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 23. Baginski M, Resat H, Borowski E (2002) Comparative molecular dynamics simulations of amphotericin B-cholesterol/ergosterol membrane channels. Biochim Biophys Acta 1567: 63–78. [DOI] [PubMed] [Google Scholar]
  • 24. Lemke A, Kiderlen AF, Kayser O (2005) Amphotericin B. Appl Microbiol Biotechnol. 68: 151–162. [DOI] [PubMed] [Google Scholar]
  • 25. Jha TK, Giri YN, Singh TK, Jha S (1995) Use of amphotericin B in drug-resistant cases of visceral leishmaniasis in north Bihar, India. Am J Trop Med Hyg 52: 536–538. [DOI] [PubMed] [Google Scholar]
  • 26. de Souza W, Rodrigues JC (2009) Sterol Biosynthesis Pathway as Target for Anti-trypanosomatid Drugs. Interdiscip Perspect Infect Dis 2009: 642502. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 27. Urbina JA (1997) Lipid biosynthesis pathways as chemotherapeutic targets in kinetoplastid parasites. Parasitology 114 Suppl: S91–99 [PubMed] [Google Scholar]
  • 28. Gebre-Hiwot A, Frommel D (1993) The in-vitro anti-leishmanial activity of inhibitors of ergosterol biosynthesis. J Antimicrob Chemother 32: 837–842. [DOI] [PubMed] [Google Scholar]
  • 29. Debeljak N, Fink M, Rozman D (2003) Many facets of mammalian lanosterol 14alpha-demethylase from the evolutionarily conserved cytochrome P450 family CYP51. Arch Biochem Biophys 409: 159–171. [DOI] [PubMed] [Google Scholar]
  • 30. Guengerich FP, Sohl CD, Chowdhury G (2011) Multi-step oxidations catalyzed by cytochrome P450 enzymes: Processive vs. distributive kinetics and the issue of carbonyl oxidation in chemical mechanisms. Arch Biochem Biophys 507: 126–134. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 31. Keber R, Motaln H, Wagner KD, Debeljak N, Rassoulzadegan M, et al. (2011) Mouse knockout of the cholesterogenic cytochrome P450 lanosterol 14alpha-demethylase (Cyp51) resembles Antley-Bixler syndrome. J Biol Chem 286: 29086–29097. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 32. Bard M, Lees ND, Turi T, Craft D, Cofrin L, et al. (1993) Sterol synthesis and viability of erg11 (cytochrome P450 lanosterol demethylase) mutations in Saccharomyces cerevisiae and Candida albicans. Lipids 28: 963–967. [DOI] [PubMed] [Google Scholar]
  • 33. Kalb VF, Woods CW, Turi TG, Dey CR, Sutter TR, et al. (1987) Primary structure of the P450 lanosterol demethylase gene from Saccharomyces cerevisiae. DNA 6: 529–537. [DOI] [PubMed] [Google Scholar]
  • 34. Watson PF, Rose ME, Ellis SW, England H, Kelly SL (1989) Defective sterol C5–6 desaturation and azole resistance: a new hypothesis for the mode of action of azole antifungals. Biochem Biophys Res Commun 164: 1170–1175. [DOI] [PubMed] [Google Scholar]
  • 35. Lamb DC, Kelly DE, Waterman MR, Stromstedt M, Rozman D, et al. (1999) Characteristics of the heterologously expressed human lanosterol 14alpha-demethylase (other names: P45014DM, CYP51, P45051) and inhibition of the purified human and Candida albicans CYP51 with azole antifungal agents. Yeast 15: 755–763. [DOI] [PubMed] [Google Scholar]
  • 36. Buckner FS, Joubert BM, Boyle SM, Eastman RT, Verlinde CL, et al. (2003) Cloning and analysis of Trypanosoma cruzi lanosterol 14alpha-demethylase. Mol Biochem Parasitol 132: 75–81. [DOI] [PubMed] [Google Scholar]
  • 37. Lepesheva GI, Nes WD, Zhou W, Hill GC, Waterman MR (2004) CYP51 from Trypanosoma brucei is obtusifoliol-specific. Biochemistry 43: 10789–10799. [DOI] [PubMed] [Google Scholar]
  • 38. Hargrove TY, Wawrzak Z, Liu J, Nes WD, Waterman MR, et al. (2011) Substrate preferences and catalytic parameters determined by structural characteristics of sterol 14alpha-demethylase (CYP51) from Leishmania infantum. J Biol Chem 286: 26838–26848. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 39. Buckner FS (2008) Sterol 14-demethylase inhibitors for Trypanosoma cruzi infections. Adv Exp Med Biol 625: 61–80. [DOI] [PubMed] [Google Scholar]
  • 40. Suryadevara PK, Racherla KK, Olepu S, Norcross NR, Tatipaka HB, et al. (2013) Dialkylimidazole inhibitors of Trypanosoma cruzi sterol 14alpha-demethylase as anti-Chagas disease agents. Bioorg Med Chem Lett 23: 6492–6499. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 41. Soeiro Mde N, de Souza EM, da Silva CF, Batista Dda G, Batista MM, et al. (2013) In vitro and in vivo studies of the antiparasitic activity of sterol 14alpha-demethylase (CYP51) inhibitor VNI against drug-resistant strains of Trypanosoma cruzi. Antimicrob Agents Chemother 57: 4151–4163. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 42. Bak S, Kahn RA, Olsen CE, Halkier BA (1997) Cloning and expression in Escherichia coli of the obtusifoliol 14 alpha-demethylase of Sorghum bicolor (L.) Moench, a cytochrome P450 orthologous to the sterol 14 alpha-demethylases (CYP51) from fungi and mammals. Plant J 11: 191–201. [DOI] [PubMed] [Google Scholar]
  • 43. Lepesheva GI, Zaitseva NG, Nes WD, Zhou W, Arase M, et al. (2006) CYP51 from Trypanosoma cruzi: a phyla-specific residue in the B' helix defines substrate preferences of sterol 14alpha-demethylase. J Biol Chem 281: 3577–3585. [DOI] [PubMed] [Google Scholar]
  • 44. Lepesheva GI, Waterman MR (2011) Structural basis for conservation in the CYP51 family. Biochim Biophys Acta 1814: 88–93. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 45. Cruz A, Beverley SM (1990) Gene replacement in parasitic protozoa. Nature 348: 171–173. [DOI] [PubMed] [Google Scholar]
  • 46. Bangs JD, Uyetake L, Brickman MJ, Balber AE, Boothroyd JC (1993) Molecular cloning and cellular localization of a BiP homologue in Trypanosoma brucei. Divergent ER retention signals in a lower eukaryote. J Cell Sci 105 (Pt 4): 1101–1113. [DOI] [PubMed] [Google Scholar]
  • 47. Reinhart MP, Billheimer JT, Faust JR, Gaylor JL (1987) Subcellular localization of the enzymes of cholesterol biosynthesis and metabolism in rat liver. J Biol Chem 262: 9649–9655. [PubMed] [Google Scholar]
  • 48. Homma K, Yoshida Y, Nakano A (2000) Evidence for recycling of cytochrome P450 sterol 14-demethylase from the cis-Golgi compartment to the endoplasmic reticulum (ER) upon saturation of the ER-retention mechanism. J Biochem 127: 747–754. [DOI] [PubMed] [Google Scholar]
  • 49. Sacks DL, Perkins PV (1984) Identification of an infective stage of Leishmania promastigotes. Science 223: 1417–1419. [DOI] [PubMed] [Google Scholar]
  • 50. Zotchev SB (2003) Polyene macrolide antibiotics and their applications in human therapy. Curr Med Chem 10: 211–223. [DOI] [PubMed] [Google Scholar]
  • 51. Baginski M, Czub J, Sternal K (2006) Interaction of amphotericin B and its selected derivatives with membranes: molecular modeling studies. Chem Rec 6: 320–332. [DOI] [PubMed] [Google Scholar]
  • 52. Brown DA, London E (1998) Structure and origin of ordered lipid domains in biological membranes. J Membr Biol 164: 103–114. [DOI] [PubMed] [Google Scholar]
  • 53.Zhang K, Showalter M, Revollo J, Hsu FF, Turk J, et al. (2003) Sphingolipids are essential for differentiation but not growth in Leishmania. EMBO J 22: 6016–6026. PMCID: 275442. [DOI] [PMC free article] [PubMed]
  • 54. Denny PW, Field MC, Smith DF (2001) GPI-anchored proteins and glycoconjugates segregate into lipid rafts in Kinetoplastida. FEBS Lett 491: 148–153. [DOI] [PubMed] [Google Scholar]
  • 55. Shapira M, Pinelli E (1989) Heat-shock protein 83 of Leishmania mexicana amazonensis is an abundant cytoplasmic protein with a tandemly repeated genomic arrangement. Eur J Biochem 185: 231–236. [DOI] [PubMed] [Google Scholar]
  • 56. Spath GF, Garraway LA, Turco SJ, Beverley SM (2003) The role(s) of lipophosphoglycan (LPG) in the establishment of Leishmania major infections in mammalian hosts. Proc Natl Acad Sci USA 100: 9536–9541. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 57. Goad LJ, Holz GG Jr, Beach DH (1985) Sterols of ketoconazole-inhibited Leishmania mexicana mexicana promastigotes. Mol Biochem Parasitol 15: 257–279. [DOI] [PubMed] [Google Scholar]
  • 58. Xu W, Xin L, Soong L, Zhang K (2011) Sphingolipid degradation by Leishmania major is required for its resistance to acidic pH in the mammalian host. Infect Immun 79: 3377–3387. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 59. Dufourc EJ (2008) Sterols and membrane dynamics. J Chem Biol 1: 63–77. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 60. Harrington JM, Scelsi C, Hartel A, Jones NG, Engstler M, et al. (2012) Novel African trypanocidal agents: membrane rigidifying peptides. PLoS One 7: e44384. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 61. Berman JD, Holz GG Jr, Beach DH (1984) Effects of ketoconazole on growth and sterol biosynthesis of Leishmania mexicana promastigotes in culture. Mol Biochem Parasitol 12: 1–13. [DOI] [PubMed] [Google Scholar]
  • 62. Rog T, Pasenkiewicz-Gierula M (2001) Cholesterol effects on the phosphatidylcholine bilayer nonpolar region: a molecular simulation study. Biophys J 81: 2190–2202. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 63. Rog T, Pasenkiewicz-Gierula M (2004) Non-polar interactions between cholesterol and phospholipids: a molecular dynamics simulation study. Biophys Chem 107: 151–164. [DOI] [PubMed] [Google Scholar]
  • 64. Bloch KE (1983) Sterol structure and membrane function. CRC Crit Rev Biochem 14: 47–92. [DOI] [PubMed] [Google Scholar]
  • 65. Poyry S, Rog T, Karttunen M, Vattulainen I (2008) Significance of cholesterol methyl groups. J Phys Chem B 112: 2922–2929. [DOI] [PubMed] [Google Scholar]
  • 66. Rog T, Pasenkiewicz-Gierula M, Vattulainen I, Karttunen M (2007) What happens if cholesterol is made smoother: importance of methyl substituents in cholesterol ring structure on phosphatidylcholine-sterol interaction. Biophys J 92: 3346–3357. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 67. Cournia Z, Ullmann GM, Smith JC (2007) Differential effects of cholesterol, ergosterol and lanosterol on a dipalmitoyl phosphatidylcholine membrane: a molecular dynamics simulation study. J Phys Chem B 111: 1786–1801. [DOI] [PubMed] [Google Scholar]
  • 68. Sabatini K, Mattila JP, Kinnunen PK (2008) Interfacial behavior of cholesterol, ergosterol, and lanosterol in mixtures with DPPC and DMPC. Biophys J 95: 2340–2355. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 69. Abe F, Usui K, Hiraki T (2009) Fluconazole modulates membrane rigidity, heterogeneity, and water penetration into the plasma membrane in Saccharomyces cerevisiae. Biochemistry 48: 8494–8504. [DOI] [PubMed] [Google Scholar]
  • 70. Fernandez C, Lobo Md Mdel V, Gomez-Coronado D, Lasuncion MA (2004) Cholesterol is essential for mitosis progression and its deficiency induces polyploid cell formation. Exp Cell Res 300: 109–120. [DOI] [PubMed] [Google Scholar]
  • 71. Martinez-Botas J, Suarez Y, Ferruelo AJ, Gomez-Coronado D, Lasuncion MA (1999) Cholesterol starvation decreases p34(cdc2) kinase activity and arrests the cell cycle at G2. FASEB J 13: 1359–1370. [DOI] [PubMed] [Google Scholar]
  • 72. Ralton JE, McConville MJ (1998) Delineation of three pathways of glycosylphosphatidylinositol biosynthesis in Leishmania mexicana. Precursors from different pathways are assembled on distinct pools of phosphatidylinositol and undergo fatty acid remodeling. J Biol Chem 273: 4245–4257. [DOI] [PubMed] [Google Scholar]
  • 73. Naderer T, McConville MJ (2002) Characterization of a Leishmania mexicana mutant defective in synthesis of free and protein-linked GPI glycolipids. Mol Biochem Parasitol 125: 147–161. [DOI] [PubMed] [Google Scholar]
  • 74. Spath GF, Lye LF, Segawa H, Sacks DL, Turco SJ, et al. (2003) Persistence without pathology in phosphoglycan-deficient Leishmania major . Science 301: 1241–1243. [DOI] [PubMed] [Google Scholar]
  • 75. Moreno SN, Docampo R (2003) Calcium regulation in protozoan parasites. Curr Opin Microbiol 6: 359–364. [DOI] [PubMed] [Google Scholar]
  • 76. Vannier-Santos MA, Urbina JA, Martiny A, Neves A, de Souza W (1995) Alterations induced by the antifungal compounds ketoconazole and terbinafine in Leishmania. J Eukaryot Microbiol 42: 337–346. [DOI] [PubMed] [Google Scholar]
  • 77. Vannier-Santos MA, Martiny A, Lins U, Urbina JA, Borges VM, et al. (1999) Impairment of sterol biosynthesis leads to phosphorus and calcium accumulation in Leishmania acidocalcisomes. Microbiology 145 (Pt 11): 3213–3220. [DOI] [PubMed] [Google Scholar]
  • 78. Saunders EC, Ng WW, Kloehn J, Chambers JM, Ng M, et al. (2014) Induction of a stringent metabolic response in intracellular stages of Leishmania mexicana leads to increased dependence on mitochondrial metabolism. PLoS Pathog 10: e1003888. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 79. Pucadyil TJ, Tewary P, Madhubala R, Chattopadhyay A (2004) Cholesterol is required for Leishmania donovani infection: implications in leishmaniasis. Mol Biochem Parasitol 133: 145–152. [DOI] [PubMed] [Google Scholar]
  • 80. Rub A, Dey R, Jadhav M, Kamat R, Chakkaramakkil S, et al. (2009) Cholesterol depletion associated with Leishmania major infection alters macrophage CD40 signalosome composition and effector function. Nat Immunol 10: 273–280. [DOI] [PubMed] [Google Scholar]
  • 81.Zhang K, Hsu FF, Scott DA, Docampo R, Turk J, et al. (2005) Leishmania salvage and remodelling of host sphingolipids in amastigote survival and acidocalcisome biogenesis. Mol Microbiol 55: 1566–1578. PMC Journal – In Process. PMID: 15720561. [DOI] [PMC free article] [PubMed]
  • 82. Alrajhi AA, Ibrahim EA, De Vol EB, Khairat M, Faris RM, et al. (2002) Fluconazole for the treatment of cutaneous leishmaniasis caused by Leishmania major. N Engl J Med 346: 891–895. [DOI] [PubMed] [Google Scholar]
  • 83. Momeni AZ, Jalayer T, Emamjomeh M, Bashardost N, Ghassemi RL, et al. (1996) Treatment of cutaneous leishmaniasis with itraconazole. Randomized double-blind study. Arch Dermatol 132: 784–786. [PubMed] [Google Scholar]
  • 84. Weinrauch L, Livshin R, el-On J (1987) Ketoconazole in cutaneous leishmaniasis. Br J Dermatol 117: 666–668. [DOI] [PubMed] [Google Scholar]
  • 85. Olivieri BP, Molina JT, de Castro SL, Pereira MC, Calvet CM, et al. (2010) A comparative study of posaconazole and benznidazole in the prevention of heart damage and promotion of trypanocidal immune response in a murine model of Chagas disease. Int J Antimicrob Agents 36: 79–83. [DOI] [PubMed] [Google Scholar]
  • 86. Prentice AG, Glasmacher A (2005) Making sense of itraconazole pharmacokinetics. J Antimicrob Chemother 56 Suppl 1i17–i22. [DOI] [PubMed] [Google Scholar]
  • 87. Ha DS, Schwarz JK, Turco SJ, Beverley SM (1996) Use of the green fluorescent protein as a marker in transfected Leishmania. Mol Biochem Parasitol 77: 57–64. [DOI] [PubMed] [Google Scholar]
  • 88. Kapler GM, Coburn CM, Beverley SM (1990) Stable transfection of the human parasite Leishmania major delineates a 30-kilobase region sufficient for extrachromosomal replication and expression. Mol Cell Biol 10: 1084–1094. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 89. Spath GF, Beverley SM (2001) A lipophosphoglycan-independent method for isolation of infective Leishmania metacyclic promastigotes by density gradient centrifugation. Exp Parasitol 99: 97–103. [DOI] [PubMed] [Google Scholar]
  • 90. Beverley SM (2003) Protozomics: trypanosomatid parasite genetics comes of age. Nat Rev Genet 4: 11–19. [DOI] [PubMed] [Google Scholar]
  • 91.Zhang O, Wilson MC, Xu W, Hsu FF, Turk J, et al. (2009) Degradation of host sphingomyelin is essential for Leishmania virulence. PLoS Pathog 5(12): e1000692. PMCID: 2784226. [DOI] [PMC free article] [PubMed]
  • 92. Moreira W, Leblanc E, Ouellette M (2009) The role of reduced pterins in resistance to reactive oxygen and nitrogen intermediates in the protozoan parasite Leishmania . Free Radic Biol Med 46: 367–375. [DOI] [PubMed] [Google Scholar]
  • 93. de Ibarra AA, Howard JG, Snary D (1982) Monoclonal antibodies to Leishmania tropica major: specificities and antigen location. Parasitology 85 (Pt 3): 523–531. [DOI] [PubMed] [Google Scholar]
  • 94. Connell ND, Medina-Acosta E, McMaster WR, Bloom BR, Russell DG (1993) Effective immunization against cutaneous leishmaniasis with recombinant bacille Calmette-Guerin expressing the Leishmania surface proteinase gp63. Proc Natl Acad Sci U S A 90: 11473–11477. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 95. Morales MA, Pescher P, Spath GF (2010) Leishmania major MPK7 protein kinase activity inhibits intracellular growth of the pathogenic amastigote stage. Eukaryot Cell 9: 22–30. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 96. Spath GF, Epstein L, Leader B, Singer SM, Avila HA, et al. (2000) Lipophosphoglycan is a virulence factor distinct from related glycoconjugates in the protozoan parasite Leishmania major . Proc Natl Acad Sci USA 97: 9258–9263. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 97. Folch J, Lees M, Sloane Stanley GH (1957) A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226: 497–509. [PubMed] [Google Scholar]
  • 98.Zhang O, Xu W, Pillai A, Zhang K (2012) Developmentally Regulated Sphingolipid Degradation in Leishmania major. PLoS One 7(1):e31059: PMCID: 3267774. [DOI] [PMC free article] [PubMed]
  • 99. Racoosin EL, Beverley SM (1997) Leishmania major: promastigotes induce expression of a subset of chemokine genes in murine macrophages. Exp Parasitol 85: 283–295. [DOI] [PubMed] [Google Scholar]
  • 100. Pillai AB, Xu W, Zhang O, Zhang K (2012) Sphingolipid degradation in Leishmania (Leishmania) amazonensis. PLoS Negl Trop Dis 6: e1944. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 101. Titus RG, Marchand M, Boon T, Louis JA (1985) A limiting dilution assay for quantifying Leishmania major in tissues of infected mice. Parasite Immunol 7: 545–555. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Figure S1

Predicted sterol synthesis pathway in Leishmania from lanosterol to ergosterol. I–XIII represent sterol intermediates or final products (formula weights in parentheses). I: lanosterol (426.7); II: 4,14-dimethyl-8,24-cholestadienol (412.7); III: 4-methyl-8,24-cholestadienol (398.6); IV: zymosterol (384.6); V: fecosterol (398.6); VI: cholesta-7,24-dienol (384.6); VII: episterol (398.6); VIII: cholesta-5,7,24-trienol (382.6); IX: 5-dehydroepisterol (396.6); X: ergosterol (396.6); XI: 14-methyl-zymosterol (398.6); XII: 14-methyl-fecosterol (412.6); XIII: cholesterol (386.6). C14DM: Sterol C14α-demethylase (the blue circle marks the C14-methyl group to be removed by C14DM). SMT: Sterol C24-methyl transferase. VIII, IX and X represent final sterol products synthesized by Leishmania; XIII (cholesterol, shaded) is salvaged from the host or environment; XI and XII (in red) represent the accumulated sterol intermediates when C14DM is blocked.

(PDF)

Figure S2

Alignment of C14DMs from L. major (LmjF11.1100), H. sapiens (Q16850), A. fumigatus (XP_752137), C. albicans (XP_716822), and M. tuberculosis (NP_215278). Highly conserved residues are highlighted in black. The asterisks mark the predicted sterol substrate binding site and the box indicates the predicted heme binding motif.

(PDF)

Figure S3

The C14DM-GFP fusion protein is intact and functional. (A) Log and day 3 stationary phase cell lysates from c14dm and c14dm /+C14DM-GFP parasites were analyzed by Western blot, using antibodies against GFP (upper panel) or α-tubulin (lower panel). (B) Partial GC-MS chromatogram of lipids from c14dm /+C14DM-GFP promastigotes. VIII-X represent sterol species (shown in Fig. S1 and Fig. 4 ) and their corresponding peaks are indicated by arrows.

(PDF)

Figure S4

Accumulation of tetraploid cells in c14dm mutants. Log phase (AC) or stationary phase (DF) promastigotes of WT (A, D), c14dm (B, E), and c14dm /+C14DM (C, F) were fixed, permeablized and treated with RNase before staining with propidium iodide. Following flow cytometry, percentages of 1K1N and 2K2N cells are indicated. More 2K2N cells were observed in log phase when cells were more replicative.

(PDF)

Figure S5

Sterol analysis in WT promastigotes. Total lipids were extracted from WT promastigotes and analyzed by GC-MS. (A) Total ion current (TIC) chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity (an arbitrary unit reflecting the abundance of the major ion) is indicated on the right.

(PDF)

Figure S6

Sterol analysis in c14dm promastigotes. Total lipids from c14dm promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S7

Sterol analysis in WT promastigotes treated with ITZ. WT promastigotes were inoculated at 2.0×105 cells/ml in the presence of ITZ (0.2 µM). Total lipids were extracted after three days and analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S8

Sterol analysis in c14dm /+C14DM promastigotes. Total lipids were extracted from c14dm /+C14DM promastigotes and analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (C) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (D) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (E) Selected ion monitoring of sterol species with m/z of 382–383 (cholesta-5,7,24-trienol). (F) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Signal intensity is indicated on the right.

(PDF)

Figure S9

Electron ionization mass spectra of Leishmania sterols. Lipids from WT or c14dm promastigotes were analyzed by GC-MS. Electron ionization spectra (70 eV) of sterol species based on retention time (RT) in Fig. S5S8 were included. The predicted sterol types were indicated above each panel.

(PDF)

Figure S10

Reduced LPG expression in c14dm mutants. Log phase promastigotes of WT (AC), c14dm (D–F) and c14dm /+C14DM (G–I) were examined by immunofluorescence microscopy. A, D, and G: immune-staining with anti-LPG monoclonal antibody WIC 79.3, followed by a goat-anti-mouse IgG-FITC; B, E, and H: DNA staining using Hoechst 33242; C, F, and I: DIC images. (JL) Log phase promastigotes of WT (L) or c14dm (K) were labeled with anti-LPG antibody, followed by goat-anti-mouse IgG-FITC and then analyzed by flow cytometry. L: merge of J and K.

(PDF)

Figure S11

Enhanced GP63 expression in log phase c14dm mutants. Log phase promastigotes of WT (AC), c14dm (D–F) and c14dm /+C14DM (G–I) were examined by immunofluorescence microscopy. A, D, and G: immuno-staining with a monoclonal anti-GP63 antibody, followed by a goat-anti-mouse IgG-FITC; besides plasma membrane, GP63 was also found intracellularly; B, E, and H: DNA staining using Hoechst 33242; C, F, and I: DIC images.

(PDF)

Figure S12

C14dm parasites survive poorly in murine macrophages (MΦs). Purified metacyclics (black circle: WT; white circle: c14dm ; black triangle: c14dm /+C14DM) were used to infect bone marrow MΦs from BALB/c mice. To show that MΦs possess microbicidal activity, WT parasites were also used to infect MΦs that were activated with 50 ng/ml of LPS and 50 ng/ml of IFN-γ (white triangle). Fraction of infected MΦs (A) and number of parasites per 100 MΦs (B) were recorded. Error bars represent standard deviations from triplicates.

(PDF)

Figure S13

Isolated lesion amastigotes. L. major WT amastigotes were isolated from infected BALB/c mice (footpads) and subjected to fluorescence microscopy. (A) DIC image; (B) DNA staining; (C) merge of A and B. Arrows indicate amastigotes and arrowheads indicate mouse cells/debris.

(PDF)

Figure S14

Analysis of sterols in WT amastigotes. Total lipids from WT lesion amastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S15

Analysis of sterols in c14dm amastigotes. Total lipids from c14dm amastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (mainly14-methyl-zymosterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S16

Analysis of sterols in uninfected mouse tissue. Total lipids from uninfected mouse footpads were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B) Selected ion monitoring of sterol species with m/z of 386–387 (cholesterol). (C) Selected ion monitoring of sterol species with m/z of 396–397 (ergosterol and 5-dehydroepisterol). (D) Selected ion monitoring of sterol species with m/z of 398–399 (episterol). (E) Selected ion monitoring of sterol species with m/z of 412–413 (14-methyl-fecosterol). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S17

Analysis of sterols in WT promastigotes. Total lipids from WT promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B)–(F) Selected ion monitoring of sterol species with m/z of 386–387 (B), 396–397 (C), 398–399 (D), 412–413 (E), and 382–383 (F). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S18

Analysis of sterols in c14dm promastigotes. Total lipids from c14dm promastigotes were analyzed by GC-MS. (A) TIC chromatogram of lipids with m/z of 50–500. Std: internal standard (cholesta-3,5-diene). (B)–(F) Selected ion monitoring of sterol species with m/z of 386–387 (B), 396–397 (C), 398–399 (D), 412–413 (E), and 382–383 (F). Retention times for major peaks are marked in AE. Signal intensity is indicated in each panel.

(PDF)

Figure S19

ITZ treatment leads to extreme sensitivity to heat in several Leishmania species. (A) Log phase promastigotes of L. major LV39 (black circle), L. amazonensis (white circle), L. mexicana (black triangle) and L. donovani (white triangle) were cultured in various concentrations of ITZ. Culture densities were determined after 48 hours. (B) Promastigotes were grown in the absence or presence of ITZ (at IC25 concentrations) to stationary phase. Cells were then incubated at 37°C/5% CO2 and cell viability was measured after 8 hours (black bars: L. major LV39, white bars: L. amazonensis, dark grey bars: L. mexicana, light grey bar: L. donovani). Experiments were repeated three times and error bars represent standard deviations.

(PDF)

Figure S20

Ability of c14dm mutants to survive nitrosative, oxidative and acidic pH stress. Stationary phase promastigotes of WT (black circle, black bars), c14dm (white circle, white bars), and c14dm /+c14dm (black triangle, grey bars) were treated with various concentrations of SNAP (A–B), H2O2 (C–D), or incubated in pH 5.0 media (E–F). Cell density and percentage of dead cells were measured after 48 hours. Experiments were repeated three times and error bars represent standard deviations.

(PDF)

Table S1

Sterol composition in Leishmania promastigotes. Promastigotes were cultured in the absence or presence of ITZ (provided at IC25 concentrations: 120 nM for L. major, 81 nM for L. donovani, 3.3 nM for L. mexicana, and 25 nM for L. amazonensis) from early log phase to day 1 stationary phase and total lipids were analyzed by GC-MS. Abundances of ergosterol, 5-dehydroepisterol, cholesterol, cholesta-5,7,24-trienol, 14-methyl sterols (14-methylfecosterol + 14-methylzymosterol), and total sterols were estimated in relation to the internal standard cholesta-3,5-diene (provided at 2.0×107 molecules/cell). Analyses were repeated 3 times and averaged values ± standard deviations (SDs) were shown. ND: not detectable.

(PDF)

Table S2

Susceptibility of Leishmania parasites to ITZ (IC values in µM). Promastigotes were inoculated at 2.0×105 cells/ml in various concentrations of ITZ and culture densities were determined after 48 hours. IC25, IC50, and IC90 are ITZ concentrations that inhibit growth by 25%, 50%, and 90%, respectively, in comparison to control cultures (no ITZ). Experiments were performed three times (average ± SD).

(PDF)

Table S3

List of oligonucleotides used in this study. Sequences in lowercase represent restriction enzyme recognition sites.

(PDF)

Data Availability Statement

The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.


Articles from PLoS Pathogens are provided here courtesy of PLOS

RESOURCES