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Lopinavir, an HIV-1 peptidase inhibitor, induces alteration on the lipid metabolism of Leishmania amazonensis promastigotes

Published online by Cambridge University Press:  28 May 2018

Karina M. Rebello
Affiliation:
Laboratório de Estudos Integrados em Protozoologia, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz (FIOCRUZ), Rio de Janeiro, Brazil
Valter V. Andrade-Neto
Affiliation:
Laboratório de Bioquímica de Tripanosomatídeos, Instituto Oswaldo Cruz, FIOCRUZ, Rio de Janeiro, Brazil
Aline A. Zuma
Affiliation:
Laboratório de Ultraestrutura Celular Hertha Meyer, Instituto de Biofísica Carlos Chagas Filho, Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, Brazil
Maria Cristina M. Motta
Affiliation:
Laboratório de Ultraestrutura Celular Hertha Meyer, Instituto de Biofísica Carlos Chagas Filho, Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, Brazil
Claudia Regina B. Gomes
Affiliation:
Laboratório de Síntese de Fármacos, Farmanguinhos, FIOCRUZ, Rio de Janeiro, Brazil
Marcus Vinícius N. de Souza
Affiliation:
Laboratório de Síntese de Fármacos, Farmanguinhos, FIOCRUZ, Rio de Janeiro, Brazil
Geórgia C. Atella
Affiliation:
Instituto de Bioquímica Médica, UFRJ, Rio de Janeiro, Brazil
Marta H. Branquinha
Affiliation:
Laboratório de Investigação de Peptidases, Instituto de Microbiologia Paulo de Góes, UFRJ, Rio de Janeiro, Brazil
André L. S. Santos
Affiliation:
Laboratório de Investigação de Peptidases, Instituto de Microbiologia Paulo de Góes, UFRJ, Rio de Janeiro, Brazil
Eduardo Caio Torres-Santos
Affiliation:
Laboratório de Bioquímica de Tripanosomatídeos, Instituto Oswaldo Cruz, FIOCRUZ, Rio de Janeiro, Brazil
Claudia M. d'Avila-Levy*
Affiliation:
Laboratório de Estudos Integrados em Protozoologia, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz (FIOCRUZ), Rio de Janeiro, Brazil
*
Author for correspondence: Claudia M. d'Avila-Levy, E-mail: [email protected]

Abstract

The anti-leishmania effects of HIV peptidase inhibitors (PIs) have been widely reported; however, the biochemical target and mode of action are still a matter of controversy in Leishmania parasites. Considering the possibility that HIV-PIs induce lipid accumulation in Leishmania amazonensis, we analysed the effects of lopinavir on the lipid metabolism of L. amazonensis promastigotes. To this end, parasites were treated with lopinavir at different concentrations and analysed by fluorescence microscopy and spectrofluorimetry, using a fluorescent lipophilic marker. Then, the cellular ultrastructure of treated and control parasites was analysed by transmission electron microscopy (TEM), and the lipid composition was investigated by thin-layer chromatography (TLC). Finally, the sterol content was assayed by gas chromatography–mass spectrometry (GC/MS). TEM analysis revealed an increased number of lipid inclusions in lopinavir-treated cells, which was accompanied by an increase in the lipophilic content, in a dose-dependent manner. TLC and GC–MS analysis revealed a marked increase of cholesterol-esters and cholesterol. In conclusion, lopinavir-induced lipid accumulation and affected lipid composition in L. amazonensis in a concentration–response manner. These data contribute to a better understanding of the possible mechanisms of action of this HIV-PI in L. amazonensis promastigotes. The concerted action of lopinavir on this and other cellular processes, such as the direct inhibition of an aspartyl peptidase, may be responsible for the arrested development of the parasite.

Type
Special Issue Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2018

Introduction

Leishmaniasis is a tropical disease caused by an intracellular parasite of the genus Leishmania, which is transmitted by phlebotomine sand flies. Leishmaniasis is characterized by wide clinical presentations, ranging from cutaneous ulcers to deadly visceral lesions. An estimated 900 000–1.3 million new cases and 20 000–30 000 deaths occur annually (Alvar et al., Reference Alvar2012). Concurrently, human immunodeficiency virus (HIV) infection is a major global public health problem and the prevalence is increasing worldwide. This scenario is worsened by an overlap between HIV and several infectious diseases, including leishmaniasis (Alvar et al., Reference Alvar2008). As a result, the number of reported coinfection cases has been increasing globally (Lindoso et al., Reference Lindoso2016), and these patients have a higher risk of treatment failure, a higher risk of relapse and higher rates of mortality (Alvar et al., Reference Alvar2008).

The current therapeutic approach to leishmaniasis is still based on a handful of drugs developed in the beginning and middle of the last century and that present several drawbacks, such as high costs, mode of administration and resistance emergence. The available compounds are pentavalent antimonials, amphotericin B, pentamidine, miltefosine and paromomycin. Although it is clear that the aetiological agent plays a crucial role in the clinical disease patterns, the choice of treatment is mainly based on drug availability in each country or region and patient care availability, since several drugs require hospitalization due to intravenous administration route and the severe side-effects. Also, there are no easily accessible methods for species-specific diagnosis in endemic areas, which reduces the physician possibility to choose the most suitable chemotherapeutic approach. Although miltefosine, which has been recently approved by US Food and Drug Administration (FDA), has the tremendous advantage of being orally administered, its teratogenic potential and the long half-life that can lead to the selection of drug-resistant lines still raises doubts on its suitability. The overlap between HIV and leishmaniasis poses additional problems to patient treatment, mainly due to the lack of information on chemotherapeutic combination (reviewed by Uliana et al., Reference Uliana, Trinconi and Coelho2017). It is clear that the main problems related to leishmaniasis treatment are mainly economical (Ennes-Vidal et al., Reference Ennes-Vidal2017; Uliana et al., Reference Uliana, Trinconi and Coelho2017; Alvar and Arana, Reference Alvar, Arana, Rivas and Gil2018).

The antiretroviral treatment has a tremendous impact in the development of acquired immunodeficiency syndrome; it delays relapses and increases the survival and life quality of HIV patients, and greatly reduces the occurrence and severity of opportunistic infections (Santos, Reference Santos2010; Sunpath et al., Reference Sunpath2014; Lindoso et al., Reference Lindoso2016). The latter effect has been associated to either a recovery of the immune response or to a direct action of HIV aspartyl peptidase inhibitors (HIV-PIs) on opportunistic pathogens (Santos, Reference Santos2010; Sunpath et al., Reference Sunpath2014; Lindoso et al., Reference Lindoso2016). In this sense, HIV-PIs were designed against an aspartyl peptidase from HIV and an orthologous of this enzyme is present at the genome of Leishmania. Some data support that this orthologous is the intracellular target for HIV-PIs (White et al., Reference White, Powell and Berry2011; Perteguer et al., Reference Perteguer2013). However, there is no direct evidence on the functional role of the aspartyl peptidases in these parasites, such as knockout or RNA interference approaches. Nevertheless, we and others have demonstrated that HIV-PIs exert potent antiparasitic effects in vitro on Leishmania promastigotes and intracellular amastigotes, but the exact biochemical target and mechanism of action is still poorly understood (Savoia et al., Reference Savoia, Allice and Tovo2005; Trudel et al., Reference Trudel2008; Santos et al., Reference Santos2009, Reference Santos2013a; Valdivieso et al., Reference Valdivieso2010; van Griensven et al., Reference van Griensven2013; White et al., Reference White, Powell and Berry2011; Demarchi et al., Reference Demarchi2012 for a comprehensive review see Santos et al., Reference Santos2013b, Reference Santos2017). Transmission electron microscopy (TEM) revealed that HIV-PIs provoke an increase in lipid inclusions in Leishmania amazonensis (Santos et al., Reference Santos2009). Interestingly, one of the adverse events caused in humans by HIV-PIs treatment is lipodystrophy, which is a condition induced by long-term exposure to PIs that causes excessive fat deposition and accumulation (Hui, Reference Hui2003). HIV-PIs have been also described modulating proteasome activity (Andre et al., Reference Andre1998; Schmidtke et al., Reference Schmidtke1999), apoptosis (Vlahakis et al., Reference Vlahakis2007; Rizza and Badley, Reference Rizza and Badley2008) and lipid metabolism (Hui, Reference Hui2003; Nolan, Reference Nolan2003; Zha et al., Reference Zha2013).

Here, considering the possible induction of lipid accumulation by HIV-PIs in L. amazonensis (Santos et al., Reference Santos2009) and the well-established side-effect of these inhibitors on lipid accumulation in treated HIV patients, we decided to investigate whether lopinavir, the most common drug used in clinics, would exert any effect on the lipid metabolism in L. amazonensis. Our data indicate the occurrence of a significant accumulation of esterified cholesterol (CHO) in treated parasites in a concentration-dependent manner, culminating in parasite death. These data highlight one of the possible mechanisms of action of this compound.

Material and methods

Chemicals and reagents

Lopinavir was synthesized in the Laboratory of Chemical Synthesis, Farmanguinhos, FIOCRUZ, and dissolved in dimethyl sulfoxide (DMSO). Miconazole, heat-inactivated fetal bovine serum (FBS), 7-hydroxy-3H-phenoxazin-3-one-10-oxide sodium salt (Resazurin sodium salt), RPMI-1640 medium, adenine, d-biotin, folic acid, streptomycin, penicillin, hemin, poly-l-lysine, DMSO and lipid standards were purchased from Sigma Aldrich Chemical (St. Louis, MO, USA). ProLong Gold antifade reagent with DAPI (4′,6-diamidino-2-phenylindole) and BODYPI were purchased from Thermo Fisher Scientific (Waltham, MA, USA). Silica plates 60 F254 for thin-layer chromatography (TLC) were purchased from Merck (Frankfurt, DS, Germany). All solvents used were of the purest grade available. All other reagents were analytical grade or superior.

Parasite culture

Promastigotes of L. amazonensis (strain MHOM/BR/77/LTB0016) were cultivated at 26 °C in RPMI medium without phenol red supplemented with 10% FBS, 100 µg mL−1 streptomycin, 100 U mL−1 penicillin and 5 mg mL−1 of hemin, 0.2 mg mL−1 of d-biotin, 4 mg mL−1 of adenine and 0.5 mg mL−1 folic acid.

Parasites treatment with lopinavir

To evaluate the effect of lopinavir on the lipid metabolism, L. amazonensis promastigotes were maintained in flasks at 26 °C for 72 h with the HIV-PI at concentrations ranging from half the IC50 (½IC50), the IC50 and two times the IC50 (2 × IC50), which correspond to 7.5, 15 and 30 µ m, respectively (Santos et al., Reference Santos2009). Control cells consisted of parasites grown in culture medium with no lopinavir. Parasites treated with the highest DMSO dose used to dissolve the HIV-PI were assessed in parallel for additional control. The tests were performed in culture bottles with an initial inoculum of 1 × 106 parasites mL−1. Parasitic growth was evaluated by counting the viable motile parasites in a Neubauer chamber. Parasite viability was assessed by cell motility and trypan blue cell dye exclusion (Strober, Reference Strober2001).

BODYPI staining and fluorimetric analysis

Leishmania amazonensis promastigotes were treated with lopinavir, as described above. Then, parasites (1 × 107 cells) were washed three times in phosphate-buffered saline (PBS; 150 mm NaCl, 20 mm phosphate buffer, pH 7.2) at 3000 × g for 10 min at 4 °C and fixed in 4% freshly prepared paraformaldehyde in PBS for 5 min at room temperature (RT). After washing twice in PBS, promastigotes were incubated in 10 µ m BODIPY for 30 min at 28 °C, protected from light. Afterwards, parasites were washed three times in PBS (3000 × g for 10 min at RT) and immediately used in the following experiments. Cellular suspensions were transferred to a black 96-well microplate and BODYPI fluorescence was determined in a Microplate Reader Spectra Max M2 (Molecular Devices): green fluorescence of neutral lipid inclusions was acquired (excitation: 493 nm; emission 503 nm). Alternatively, an aliquot of each cell suspension was collected and adhered to 0.1% poly-l-lysine coated glass coverslips. Samples were mounted in ProLong Gold antifade reagent with DAPI (excitation: 358 nm; emission: 461 nm) and images of neutral lipid inclusions were acquired using appropriated filters in a Zeiss Axio Observer Z.1 epifluorescence microscope coupled to a QImagingRolera EM-C2 camera.

Transmission electron microscopy

Control and lopinavir-treated cells were cultured as described above and promastigotes (2 × 108 cells) were fixed overnight at 4 °C in 2.5% glutaraldehyde in 0.1 m cacodylate buffer, pH 7.2. Thereafter, cells were washed in cacodylate buffer and postfixed for 1 h in 0.1 m cacodylate buffer containing 1% osmium tetroxide, 0.8% potassium ferrocyanide and 5 mm CaCl2. Then, cells were washed in the same buffer, dehydrated in acetone and embedded in Epon. Ultrathin sections were mounted on 300-mesh grids, stained with uranyl acetate and lead citrate and observed under a Zeiss 900 TEM (Zeiss, Oberkochen, Germany) (Santos et al., Reference Santos2009; Sangenito et al., Reference Sangenito2014).

Lipid extraction and TLC

Leishmania amazonensis promastigotes were treated with lopinavir (½IC50, IC50 and 2 × IC50) or miconazole (2 and 4 µ m, ½IC50 and IC50, respectively) (Andrade-Neto et al., Reference Andrade-Neto2016), miconazole plus lopinavir (2 + 15 µ m or 4 + 15 µ m) or in culture medium alone for 72 h. After incubation, 1 × 108 parasites from each culture were washed three times with PBS (3000 × g for 10 min) and their neutral lipids were extracted by the method of Bling and Dyler (Bligh and Dyer, Reference Bligh and Dyer1959). Briefly, parasites were resuspended in 0.5:2:0.4 parts of chloroform:methanol:water (v/v/v) and homogenized. The suspension was kept under stirring for 1 h at RT and centrifuged (3000 × g for 20 min) and the supernatant, enriched in lipids, was transferred to a new tube. The pellet was subjected to a second extraction of lipids. The supernatants were added to water:chloroform (1:1), and after 40 s of agitation, the material was centrifuged (3000 × g for 30 min). The lipid phase was then separated, and the solvent was evaporated using a centrifugal evaporator and resuspended in 50 µL of chloroform. The lipid extracts were spotted onto silica gel TLC plate previously impregnated with silver nitrate (1%) in methanol, to obtain a better separation of the lipids with double bounds, especially ergostane-related sterols from CHO. The plate was run in two steps. The first run, at the half of the plate, was made with hexane:ethylether:acetic acid (60:40:1, v/v/v), and the second was made with hexane:chloroform:acetic acid (80:20:1, v/v/v) (Mangold, Reference Mangold and Stahl1969). The plates were developed using a charring reagent (CuSO4) followed by heating at 200 °C for 20 min (Bitman and Wood, Reference Bitman and Wood1982). After that, the chromatography plates were digitized, and the bands were quantified by densitometry (Andrade-Neto et al., Reference Andrade-Neto2011). Cholesterol-ester (CHOE), ergosterol (ERG), CHO, lanosterol, squalene, monoacylglycerol, diacylglycerol (DG) and triacylglycerol (TG) were used as standards.

Sterol extraction

Total lipids were extracted as described above and dried under a stream of nitrogen. The sterol content was extracted after saponification (Arthington-Skaggs et al., Reference Arthington-Skaggs1999). Briefly, 3 mL of 25% alcoholic potassium hydroxide solution (25 g KOH and 35 mL of sterile distilled water, brought to 100 ml with 100% ethanol) were added to each pellet and vortex-mixed for 1 min. Cell suspensions were transferred to 16 by 100 mm sterile borosilicate glass screw-cap tubes and were incubated in an 85 °C water bath for 1 h. Following incubation, tubes were allowed to cool to RT for 30 min. Sterols were then extracted by addition of a mixture of 1 mL of sterile distilled water and 2 mL of n-heptane followed by vigorous vortex mixing for 3 min. The heptane layer was transferred to a clean borosilicate glass screw-cap tube. The sterols were dried with N2 and resuspended in 50 µL silylant STFA, TMCS (99:1) + 50 µL pyridine followed by incubation for 1 h at 65 °C.

Gas chromatography–mass spectrometry analysis of the L. amazonensis sterols

Leishmania amazonensis sterols were analysed by the use of gas chromatography–mass spectrometry (GC–MS), wherein the lipids were extracted from promastigotes grown in the presence of lopinavir, miconazole or both drugs. The analysis of the sterol fraction by GC–MS was carried out on a Shimadzu GCMS-QP2010 Plus system, using an HP Ultra 2 (5% phenyl – methylpolysiloxane) of Agilent (25 m × 0.20 mm × 0.33 µm). Injector was set at 250 °C. Column temperature was elevated to 50–270 °C with a heating rate of 15 °C min−1 and 270–300 °C, with high rate heating of 0.9 °C min−1, and held at 300 °C for 6 min. Helium was used as carrier gas with linear velocity of 37.9 cm s−1. A volume of 1 µL of sample was injected into the chromatograph. Electroionization (EI-70 eV) and a quadrupole mass analyser were operated in scans from 40 to 600 amu. Interface was set at 280 °C and the ion source at 280 °C. The components were identified by comparing their mass spectra with those of the library NIST05 contained in the computer's mass spectrometer.

Statistical analysis

All experiments were repeated at least three times in triplicate and the graphics were generated with Graphpad Prism 6 software. Fluorimetric data were analysed statistically using one-way analysis of variance test followed by Tukey post-test. Student's t-test was used to evaluate densitometry data. P values of 0.05 or less were considered statistically significant. Representative images of these experiments are shown.

Results

Promastigote lipid accumulation depends on lopinavir concentration

In order to analyse the effect of lopinavir on leishmanial lipid content, L. amazonensis promastigotes cells were grown for 72 h in the presence of ½IC50, IC50 and 2 × IC50 concentrations of the compound. Lipid bodies (LB) were distributed throughout the parasite body, as visualized by cell labelling with BODIPY (Fig. 1A). Treated parasites presented a clear increase in green fluorescence intensity in relation to control cells, in a concentration-dependent manner, as revealed by fluorescence fluorimetric measurements. In parasites treated with 2 × IC50, there was an enhancement of more than two times of the fluorescence emission, when compared with untreated parasites (Fig. 1B).

Fig. 1. Neutral lipid distribution in L eishmania amazonensis promastigotes cultivated in different lopinavir concentrations and incubated with BODIPY. (A) Promastigotes were grown in 7.5, 15 and 30 µ m of lopinavir (½IC50, IC50 and 2 × IC50, respectively) for 72 h and incubated with BODIPY and DAPI. Cells were analysed under differential interferential contrast (DIC) and fluorescence in a Zeiss epifluorescence microscope. In the images, the kinetoplast (k) and nucleus (n) are indicated. (B) Fluorimetric analysis using BODIPY revealed that promastigotes incubated with 2 × IC50 stored more neutral lipids than those grown in lower concentrations of this inhibitor. Fluorescence intensity was expressed in arbitrary units (AU). The experiments were performed three times in triplicate and data are shown as bar graphs ± standard error of the mean. *P <  0.01, **P < 0.05.

To further analyse the lipid inclusions distribution, control and treated parasites were submitted to TEM analysis. After lopinavir treatment, the parasites presented larger lipid inclusions in relation to control cells (Fig. 2A–F). Usually LB were observed very close to each other and often appear to be fusing (Fig. 2B). These structures are seen in association with the mitochondrion (Fig. 2C), as well as with the endoplasmic reticulum (Fig. 2D) and are positioned at the cell periphery (Fig. 2E), sometimes promoting protrusions on the plasma membrane (Fig. 2F).

Fig. 2. Transmission electron microscopy ultrastructural analysis of L eishmania amazonensis promastigotes treated with lopinavir. Untreated parasites (A) or those treated with ½IC50 (B), IC50 (C and D) and 2 × IC50 (E and F) of lopinavir for 72 h are shown. Lipid inclusions (asterisks) are numerous in parasites treated with lopinavir (B–H). Sometimes it is possible to detect fusion between lipid bodies (B – arrow). Such structures were observed in close association with the mitochondrion (C and D) and the endoplasmic reticulum (D). Lipid bodies are commonly observed at the cell periphery (E), close to the plasma membrane and even promoting its protrusion (F). M – mitochondrion, N – nucleus, ER – endoplasmic reticulum. Bars equal to 2 µm (A–C), 1 µm (D and E) and 0.5 µm (F).

Effect of lopinavir on sterol biosynthesis of L. amazonensis promastigotes

Lopinavir has already been described as effective in inhibiting the growth of Leishmania spp. (Santos et al., Reference Santos2009). Miconazole, an inhibitor of the enzyme sterol C14 demethylase, stops the ERG biosynthesis in Leishmania, which causes the accumulation of precursors and an increase in the uptake of exogenous CHO (Andrade-Neto et al., Reference Andrade-Neto2011). Thus, miconazole was included in the assay for comparison purposes. The activity of lopinavir on the sterol biosynthesis in promastigotes of L. amazonensis was evaluated by TLC after parasite treatment with increasing concentrations of lopinavir, miconazole or the combination of both compounds for 72 h (Fig. 3A and B). Densitometric analysis of the TLC revealed several alterations in the lipid profile after lopinavir treatment, like a marked increase of CHOE (Fig. 3C). However, no significant decrease in ERG content was observed in these parasites and no accumulation of methylated sterols (MS1 and MS2) after lopinavir treatment, as observed in the treatment with miconazole (Fig. 3B and D). The results of GC–MS showed an increase in the CHO content in a dose-dependent manner (Table 1). Since the saponification during the extraction disrupts the ester bonds, the total amount of CHO observed in GC–MS analysis is the sum of free CHO and CHOE. The treatment with miconazole induced an inhibition of the biosynthesis of 5-dehydroepisterol, with accumulation of the methylated sterol, 4,14-dimethylzymosterol (Table 1). Despite the decrease in 5-dehydroepisterol in cells treated with 2 × IC50, there was no accumulation of methylated sterols, which corroborates the TLC data.

Fig. 3. Effect of lopinavir on the lipid composition of L eishmania amazonensis promastigotes. (A) L eishmania amazonensis promastigotes were incubated in the absence (C – control) or presence of varying concentrations of lopinavir (L7.5, L15 and L30 µ m) and (B) miconazole (M2 and M4 µ m) alone or in combination (M2 + L15 µ m or M4 + L15 µ m) for 72 h. Neutral lipids were extracted as described and subjected to thin-layer chromatography (TLC). The TLC image is representative of three independent experiments. Lipid standards used were: ergosterol (ERG), diacylglycerol (DG), cholesterol (CHO), lanosterol (LAN), triacylglycerol (TG) and cholesteryl palmitate (CHOE). The sterol content of parasites treated with lopinavir (C), miconazole alone or miconazole plus lopinavir (D) was estimated by densitometry of the TLC using Image Master Total Lab v1.11 software (AU – arbitrary units). The plotted data are mean standard error of three independent experiments. *P < 0.05, **P < 0.01.

Table 1. GC–MS analysis of sterol composition in L eishmania amazonensis treated with lopinavir, miconazole or miconazole plus lopinavir

a Molecular weight (Da).

b Retention time.

c Non-detectable.

To find out whether the accumulated band (CHOE) was actually CHOE (from an exogenous source) or other endogenous esterified ergostane sterol, parasites were simultaneously treated with lopinavir and miconazole. Interestingly, there was an increase in the CHOE band intensity, even higher than lopinavir alone at the IC50 concentration (Fig. 3B). This result confirmed that the sterol accumulated in lopinavir-treated parasites is not an ergosterol-ester, since it persists even when ERG biosynthesis is inhibited by the combined treatment with miconazole and lopinavir. GC–MS and densitometric analysis of TLCs confirmed that this combined treatment induced an increase in CHOE band intensities (Table 1 and Fig. 3D).

Discussion

Although HIV-PIs are targeted to the retroviral aspartyl peptidase, long-term treatment leads to important side-effects, such as insulin resistance (Hruz, Reference Hruz2008) and lipodystrophy (Hui, Reference Hui2003; Nolan, Reference Nolan2003). Lipodystrophy is characterized by the abnormal distribution of fat in the human body, increased levels of triglycerides, very low-density lipoprotein and low-density lipoprotein (LDL) CHO (Periard et al., Reference Periard1999). Considering this important side-effect of HIV-PIs and previous observations from our research group that these inhibitors seem to induce an increase in lipid inclusions in L. amazonensis (Santos et al., Reference Santos2009), we decided to analyse the effect of lopinavir on L. amazonensis lipid metabolism.

This study shows for the first time that parasites treated with increasing concentrations of lopinavir exhibited accumulation of lipid inclusions and increased amounts of CHOE in a dose-dependent manner. Interestingly, lopinavir alters the sterol profile in L. amazonensis without inhibiting ERG biosynthesis, since this lipid content was not affected by the HIV-PI treatment. Sterol biosynthesis inhibitors have been widely studied in Leishmania spp., particularly because this pathway is a promising target for antiprotozoal chemotherapy (Rodrigues et al., Reference Rodrigues2002; Magaraci et al., Reference Magaraci2003; Chawla and Madhubala, Reference Chawla and Madhubala2010; de Macedo-Silva et al., Reference de Macedo-Silva, de Souza and Rodrigues2015; Andrade-Neto et al., Reference Andrade-Neto2016). In this regard, the mode of action of miltefosine on Leishmania lipid metabolism has been recently deeply investigated (Armitage et al., Reference Armitage2018). Miltefosine also induces apoptosis-like death and the disruption of metabolite transport. It is possible that these two mechanisms are linked to an interference in the lipid metabolism (Armitage et al., Reference Armitage2018). Leishmania treated with miltefosine presented a dramatic decrease in many membrane phospholipids, in addition to amino acid pools, while sphingolipids and sterols increased. This change in the lipid content can alter lipid micro-domain complexes of sterols in the Leishmania parasites membranes. In tumour cells, the apoptosis induced by miltefosine is associated to changes in lipid micro-domains. It is also interesting that the analysis of a mutant of Leishmania major that lacks the first and rate-limiting enzyme of the biosynthetic pathway of sphingolipids revealed a three times lower susceptibility to miltefosine, while the drug intracellular concentration presented no significant difference in relative concentration in relation to wild-type cells. The increase in the sphingolipid content reported may be related to either a stimulatory effect of miltefosine on the biosynthesis itself or to the inhibition of a catabolic pathway, the latter more probable, since the mutant cells also presented an increase in sphingolipids (Armitage et al., Reference Armitage2018).

It has been shown that ERG biosynthesis inhibitors induce alterations in the ultrastructure of some organelles. An important alteration observed after treatment with sterol biosynthesis inhibitors is the presence of several LB displaying variable morphology (de Souza and Rodrigues, Reference de Souza and Rodrigues2009). Interestingly, even though the ERG biosynthesis was not targeted by lopinavir, there was a pronounced accumulation of CHOE, which in mammalian cells is the CHO storage form (Maxfield and van Meer, Reference Maxfield and van Meer2010). De Cicco et al. (Reference De Cicco2012) reported the capacity of L. amazonensis to synthesize CHOE using LDL particles as the sole source of CHO. Trypanosomatids are able to incorporate CHO from the host or from the culture medium through LDL receptors endocytic pathway (Bastin et al., Reference Bastin1996).

LB are cytoplasmic intracellular inclusions of compartmentalization and storage of lipids. In microorganisms such as fungi, microalgae and bacteria, the accumulation of these LB seems to be induced specifically in response to some stress. The structure and morphology of LB have been described in mammalian cells, especially in adipocytes, and consist of a monolayer of phospholipids, amphipathic glycolipids and/or steroids that surround a hydrophobic core of neutral lipids, mainly TG and esters of sterols (Murphy, Reference Murphy2001; Farese and Walther, Reference Farese and Walther2009; d'Avila et al., Reference d'Avila, Toledo and Melo2012; Rabhi et al., Reference Rabhi2016; Roingeard and Melo, Reference Roingeard and Melo2017). Lipid metabolism has been demonstrated as an important pathway modulated by protozoan parasites in host cells. Several studies with Toxoplamasma gondii, Plasmodium spp. and L. amazonensis have documented that these pathogens are able to induce accumulation of lipids, such as TG, DG, CHOE, CHO and/or phospholipids (Coppens et al., Reference Coppens, Sinai and Joiner2000; Das et al., Reference Das2016; Rabhi et al., Reference Rabhi2016; Toledo et al., Reference Toledo, D'Avila and Melo2016). Our results suggest that the content of LB observed in the treatment with lopinavir in L. amazonensis promastigotes can be composed of CHOE, because the sterol analysis demonstrated an increase of both LB and CHOE in a concentration-dependent manner. In this sense, we suggest that CHO storage (CHOE form) can interfere with the membrane formation.

In conclusion, our findings reinforce that lopinavir can be useful in leishmaniasis treatment and adds some light on one possible mechanism of action, through interference in the sterol metabolism, with an accumulation of LB and an increase in esterified CHO concentration.

Acknowledgements

We are grateful to Keyla Cristiny da Silva Gonçalves, for her helpful assistance to provide lopinavir with Farmanguinhos researchers and Mileane S. Buch for her expert technical assistance.

Financial support

This work was supported by CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico), CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior), FAPERJ (Fundação de Amparo a Pesquisa do Rio de Janeiro) and Fundação Oswaldo Cruz (Fiocruz).

Conflict of interest

None.

Ethical standards

Not applicable.

Footnotes

Both authors share senior authorship.

References

Alvar, J and Arana, B (2018) I. Appraisal of leishmaniasis chemotherapy, current status and pipeline strategies. In Rivas, L, Gil, C (eds), Drug Discovery for Leishmaniasis. Cambridge, UK: Royal Society of Chemistry, pp. 123.Google Scholar
Alvar, J et al. (2008) The relationship between leishmaniasis and AIDS: the second 10 years. Clinical Microbiology Reviews 21, 334359.Google Scholar
Alvar, J et al. (2012) Leishmaniasis worldwide and global estimates of its incidence. PLoS ONE 7, e35671.Google Scholar
Andrade-Neto, VV et al. (2011) The pharmacological inhibition of sterol biosynthesis in Leishmania is counteracted by enhancement of LDL endocytosis. Acta Tropica 119, 194198.Google Scholar
Andrade-Neto, VV et al. (2016) Imipramine alters the sterol profile in Leishmania amazonensis and increases its sensitivity to miconazole. Parasite & Vectors 9, 183.Google Scholar
Andre, P et al. (1998) An inhibitor of HIV-1 protease modulates proteasome activity, antigen presentation, and T cell responses. Proceedings of the National Academy of Sciences of the USA 95, 1312013124.Google Scholar
Armitage, EG et al. (2018) A complex interplay between sphingolipid and sterol metabolism revealed by perturbations to the Leishmania metabolome caused by miltefosine. Antimicrobial Agents and Chemotherapy. 62, e02095–17.Google Scholar
Arthington-Skaggs, BA et al. (1999) Quantitation of ergosterol content: novel method for determination of fluconazole susceptibility of Candida albicans. Journal of Clinical Microbiology 37, 33323337.Google Scholar
Bastin, P et al. (1996) An M(r) 145,000 low-density lipoprotein (LDL)-binding protein is conserved throughout the Kinetoplastida order. Molecular and Biochemical Parasitology 76, 4356.Google Scholar
Bitman, J and Wood, DL (1982) An improved copper reagent for quantitative densitometric thin-layer chromatography of lipids. Journal of Liquid Chromatography 5, 11551162.Google Scholar
Bligh, EG and Dyer, WJ (1959) A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology 37, 911917.Google Scholar
Chawla, B and Madhubala, R (2010) Drug targets in Leishmania. Journal of Parasitic Diseases 34, 113.Google Scholar
Coppens, I, Sinai, AP and Joiner, KA (2000) Toxoplasma gondii exploits host low-density lipoprotein receptor-mediated endocytosis for cholesterol acquisition. Journal of Cell Biology 149, 167180.Google Scholar
d'Avila, H, Toledo, DA and Melo, RC (2012) Lipid bodies: inflammatory organelles implicated in host-Trypanosoma cruzi interplay during innate immune responses. Mediators of Inflammation 2012, 478601.Google Scholar
Das, S et al. (2016) Na+ influx induced by new antimalarials causes rapid alterations in the cholesterol content and morphology of Plasmodium falciparum. PLoS Pathogens 12, e1005647.Google Scholar
Demarchi, IG et al. (2012) Effect of HIV protease inhibitors on New World Leishmania. Parasitology International 61, 538544.Google Scholar
De Cicco, NN et al. (2012) LDL uptake by Leishmania amazonensis: involvement of membrane lipid microdomains. Experimental Parasitology 130, 330340.Google Scholar
de Macedo-Silva, ST, de Souza, W and Rodrigues, JC (2015) Sterol biosynthesis pathway as an alternative for the anti-protozoan parasite chemotherapy. Current Medicinal Chemistry 22, 21862198.Google Scholar
de Souza, W and Rodrigues, JC (2009) Sterol biosynthesis pathway as target for anti-trypanosomatid drugs. Interdisciplinary Perspectives on Infectious Diseases 2009, 642502.Google Scholar
Ennes-Vidal, V et al. (2017) Why calpain inhibitors are interesting leading compounds to search for new therapeutic options to treat leishmaniasis? Parasitology 144, 117123.Google Scholar
Farese, RV and Walther, TC (2009) Lipid droplets finally get a little R-E-S-P-E-C-T. Cell 139, 855860.Google Scholar
Hruz, PW (2008) HIV protease inhibitors and insulin resistance: lessons from in-vitro, rodent and healthy human volunteer models. Current Opinion HIV and AIDS 3, 660665.Google Scholar
Hui, DY (2003) Effects of HIV protease inhibitor therapy on lipid metabolism. Progress in Lipid Research 42, 8192.Google Scholar
Lindoso, JA et al. (2016) Leishmaniasis-HIV coinfection: current challenges. HIV AIDS (Auckland, NZ) 8, 147156.Google Scholar
Magaraci, F et al. (2003) Azasterols as inhibitors of sterol 24-methyltransferase in Leishmania species and Trypanosoma cruzi. Journal of Medicine Chemistry 46, 47144727.Google Scholar
Mangold, HK (1969) Aliphatic lipids. In Stahl, E (ed.), Thin-Layer Chromatography. Berlin, Heidelberg: Springer, pp. 363421.Google Scholar
Maxfield, FR and van Meer, G (2010) Cholesterol, the central lipid of mammalian cells. Current Opinion in Cell Biology 22, 422429.Google Scholar
Murphy, DJ (2001) The biogenesis and functions of lipid bodies in animals, plants and microorganisms. Progress in Lipid Research 40, 325438.Google Scholar
Nolan, D (2003) Metabolic complications associated with HIV protease inhibitor therapy. Drugs 63, 25552574.Google Scholar
Periard, D et al. (1999) Atherogenic dyslipidemia in HIV-infected individuals treated with protease inhibitors. The Swiss HIV Cohort Study. Circulation 100, 700705.Google Scholar
Perteguer, MJ et al. (2013) Ddi1-like protein from Leishmania major is an active aspartyl proteinase. Cell Stress and Chaperones 18, 171181.Google Scholar
Rabhi, S et al. (2016) Lipid droplet formation, their localization and dynamics during Leishmania major macrophage infection. PLoS ONE 11, e0148640.Google Scholar
Rizza, SA and Badley, AD (2008) HIV protease inhibitors impact on apoptosis. Medicinal Chemistry 4, 7579.Google Scholar
Rodrigues, JC et al. (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. Antimicrobial Agents and Chemotherapy 46, 487499.Google Scholar
Roingeard, P and Melo, RC (2017) Lipid droplet hijacking by intracellular pathogens. Cellular Microbiology 19, e12688.Google Scholar
Sangenito, LS et al. (2014) Decoding the anti-Trypanosoma cruzi action of HIV peptidase inhibitors using epimastigotes as a model. PLoS ONE 9, e113957.Google Scholar
Santos, ALS (2010) HIV aspartyl protease inhibitors as promising compounds against Candida albicans. World Journal of Biological Chemistry 1, 2130.Google Scholar
Santos, ALS et al. (2017) EDITORIAL: old drugs x new perspectives/new compounds x old necessities: focusing on combating microbial resistance – part I. Current Topics in Medicinal Chemistry 17, 11171118.Google Scholar
Santos, LO et al. (2009) HIV aspartyl peptidase inhibitors interfere with cellular proliferation, ultrastructure and macrophage infection of Leishmania amazonensis. PLoS ONE 4, e4918.Google Scholar
Santos, LO et al. (2013 a) Nelfinavir is effective in inhibiting the multiplication and aspartic peptidase activity of Leishmania species, including strains obtained from HIV-positive patients. Journal of Antimicrobial Chemotherapy 68, 348353.Google Scholar
Santos, LO et al. (2013 b) Aspartic peptidases of human pathogenic trypanosomatids: perspectives and trends for chemotherapy. Current Medicinal Chemistry 20, 31163133.Google Scholar
Savoia, D, Allice, T and Tovo, PA (2005) Antileishmanial activity of HIV protease inhibitors. International Journal of Antimicrobial Agents 26, 9294.Google Scholar
Schmidtke, G et al. (1999) How an inhibitor of the HIV-I protease modulates proteasome activity. Journal of Biological Chemistry 274, 3573435740.Google Scholar
Strober, W (2001) Trypan blue exclusion test of cell viability. Current Protocols in Immunology Appendix 3, Appendix 3B.Google Scholar
Sunpath, H et al. (2014) Double-dose lopinavir-ritonavir in combination with rifampicin-based anti-tuberculosis treatment in South Africa. International Journal of Tuberculosis and Lung Diseases 18, 689693.Google Scholar
Toledo, DA, D'Avila, H and Melo, RC (2016) Host lipid bodies as platforms for intracellular survival of protozoan parasites. Frontiers in Immunology 7, 174.Google Scholar
Trudel, N et al. (2008) Intracellular survival of Leishmania species that cause visceral leishmaniasis is significantly reduced by HIV-1 protease inhibitors. Journal of Infectious Diseases 198, 12921299.Google Scholar
Uliana, SR, Trinconi, CT and Coelho, AC (2017) Chemotherapy of leishmaniasis: present challenges. Parasitology 20, 117.Google Scholar
Valdivieso, E et al. (2010) Effects of HIV aspartyl-proteinase inhibitors on Leishmania sp. Experimental Parasitology 126, 557563.Google Scholar
van Griensven, J et al. (2013) HIV-1 protease inhibitors for treatment of visceral leishmaniasis in HIV-co-infected individuals. The Lancet Infectious Diseases 13, 251259.Google Scholar
Vlahakis, SR et al. (2007) HIV protease inhibitors modulate apoptosis signaling in vitro and in vivo. Apoptosis 12, 969977.Google Scholar
White, RE, Powell, DJ and Berry, C (2011) HIV proteinase inhibitors target the Ddi1-like protein of Leishmania parasites. FASEB Journal 25, 17291736.Google Scholar
Zha, BS et al. (2013) HIV protease inhibitors disrupt lipid metabolism by activating endoplasmic reticulum stress and inhibiting autophagy activity in adipocytes. PLoS ONE 8, e59514.Google Scholar
Figure 0

Fig. 1. Neutral lipid distribution in Leishmania amazonensis promastigotes cultivated in different lopinavir concentrations and incubated with BODIPY. (A) Promastigotes were grown in 7.5, 15 and 30 µm of lopinavir (½IC50, IC50 and 2 × IC50, respectively) for 72 h and incubated with BODIPY and DAPI. Cells were analysed under differential interferential contrast (DIC) and fluorescence in a Zeiss epifluorescence microscope. In the images, the kinetoplast (k) and nucleus (n) are indicated. (B) Fluorimetric analysis using BODIPY revealed that promastigotes incubated with 2 × IC50 stored more neutral lipids than those grown in lower concentrations of this inhibitor. Fluorescence intensity was expressed in arbitrary units (AU). The experiments were performed three times in triplicate and data are shown as bar graphs ± standard error of the mean. *P <  0.01, **P < 0.05.

Figure 1

Fig. 2. Transmission electron microscopy ultrastructural analysis of Leishmania amazonensis promastigotes treated with lopinavir. Untreated parasites (A) or those treated with ½IC50 (B), IC50 (C and D) and 2 × IC50 (E and F) of lopinavir for 72 h are shown. Lipid inclusions (asterisks) are numerous in parasites treated with lopinavir (B–H). Sometimes it is possible to detect fusion between lipid bodies (B – arrow). Such structures were observed in close association with the mitochondrion (C and D) and the endoplasmic reticulum (D). Lipid bodies are commonly observed at the cell periphery (E), close to the plasma membrane and even promoting its protrusion (F). M – mitochondrion, N – nucleus, ER – endoplasmic reticulum. Bars equal to 2 µm (A–C), 1 µm (D and E) and 0.5 µm (F).

Figure 2

Fig. 3. Effect of lopinavir on the lipid composition of Leishmania amazonensis promastigotes. (A) Leishmania amazonensis promastigotes were incubated in the absence (C – control) or presence of varying concentrations of lopinavir (L7.5, L15 and L30 µm) and (B) miconazole (M2 and M4 µm) alone or in combination (M2 + L15 µm or M4 + L15 µm) for 72 h. Neutral lipids were extracted as described and subjected to thin-layer chromatography (TLC). The TLC image is representative of three independent experiments. Lipid standards used were: ergosterol (ERG), diacylglycerol (DG), cholesterol (CHO), lanosterol (LAN), triacylglycerol (TG) and cholesteryl palmitate (CHOE). The sterol content of parasites treated with lopinavir (C), miconazole alone or miconazole plus lopinavir (D) was estimated by densitometry of the TLC using Image Master Total Lab v1.11 software (AU – arbitrary units). The plotted data are mean standard error of three independent experiments. *P < 0.05, **P < 0.01.

Figure 3

Table 1. GC–MS analysis of sterol composition in Leishmania amazonensis treated with lopinavir, miconazole or miconazole plus lopinavir