Research Article

Natural Killer T Cells Activated by a Lipopeptidophosphoglycan from Entamoeba histolytica Are Critically Important To Control Amebic Liver Abscess

  • Hannelore Lotter equal contributor mail,

    equal contributor Contributed equally to this work with: Hannelore Lotter, Nestor González-Roldán (HL); (OH)

    Affiliation: Bernhard-Nocht-Institute for Tropical Medicine, Hamburg, Germany

  • Nestor González-Roldán equal contributor,

    equal contributor Contributed equally to this work with: Hannelore Lotter, Nestor González-Roldán

    Affiliations: Bernhard-Nocht-Institute for Tropical Medicine, Hamburg, Germany, Division of Structural Biochemistry, Research Center Borstel, Leibniz-Center for Medicine and Biosciences, Borstel, Germany, Unidad de Investigación Médica en Inmunoquímica, Hospital de Especialidades del Centro Médico Nacional Siglo XXI del Instituto Mexicano del Seguro Social (IMSS), Mexico City, Mexico, Departamento de Inmunología, Escuela Nacional de Ciencias Biológicas, Instituto Politécnico Nacional, Mexico City, Mexico

  • Buko Lindner,

    Affiliation: Division of Immunochemistry, Research Center Borstel, Leibniz-Center for Medicine and Biosciences, Borstel, Germany

  • Florian Winau,

    Affiliation: Immune Disease Institute and Department of Pathology, Harvard Medical School, Boston, Massachusetts, United States of America

  • Armando Isibasi,

    Affiliation: Unidad de Investigación Médica en Inmunoquímica, Hospital de Especialidades del Centro Médico Nacional Siglo XXI del Instituto Mexicano del Seguro Social (IMSS), Mexico City, Mexico

  • Martha Moreno-Lafont,

    Affiliation: Departamento de Inmunología, Escuela Nacional de Ciencias Biológicas, Instituto Politécnico Nacional, Mexico City, Mexico

  • Artur J. Ulmer,

    Affiliation: Division of Immunology and Cell Biology, Research Center Borstel, Leibniz-Center for Medicine and Biosciences, Borstel, Germany

  • Otto Holst mail, (HL); (OH)

    Affiliation: Division of Structural Biochemistry, Research Center Borstel, Leibniz-Center for Medicine and Biosciences, Borstel, Germany

  • Egbert Tannich,

    Affiliation: Bernhard-Nocht-Institute for Tropical Medicine, Hamburg, Germany

  • Thomas Jacobs

    Affiliation: Bernhard-Nocht-Institute for Tropical Medicine, Hamburg, Germany

  • Published: May 15, 2009
  • DOI: 10.1371/journal.ppat.1000434


The innate immune response is supposed to play an essential role in the control of amebic liver abscess (ALA), a severe form of invasive amoebiasis due to infection with the protozoan parasite Entamoeba histolytica. In a mouse model for the disease, we previously demonstrated that Jα18-/- mice, lacking invariant natural killer T (iNKT) cells, suffer from more severe abscess development. Here we show that the specific activation of iNKT cells using α-galactosylceramide (α-GalCer) induces a significant reduction in the sizes of ALA lesions, whereas CD1d−/− mice develop more severe abscesses. We identified a lipopeptidophosphoglycan from E. histolytica membranes (EhLPPG) as a possible natural NKT cell ligand and show that the purified phosphoinositol (PI) moiety of this molecule induces protective IFN-γ but not IL-4 production in NKT cells. The main component of EhLPPG responsible for NKT cell activation is a diacylated PI, (1-O-[(28:0)-lyso-glycero-3-phosphatidyl-]2-O-(C16:0)-Ins). IFN-γ production by NKT cells requires the presence of CD1d and simultaneously TLR receptor signalling through MyD88 and secretion of IL-12. Similar to α-GalCer application, EhLPPG treatment significantly reduces the severity of ALA in ameba-infected mice. Our results suggest that EhLPPG is an amebic molecule that is important for the limitation of ALA development and may explain why the majority of E. histolytica-infected individuals do not develop amebic liver abscess.

Author Summary

Amoebiasis is a widespread human parasitic disease caused by the intestinal protozoan Entamoeba histolytica. There are two major clinical manifestations of the disease, amebic colitis and amebic liver abscess. Interestingly, only a small proportion of E. histolytica-infected individuals develop invasive disease, whereas the majority harbors the parasite within the gut without clinical symptoms. So far, cells of the innate immune system have been described to constitute the main host defense mechanism for the control of amoebiasis, relying largely on the early production of interferon-γ (IFN-γ), a protein, which activates macrophages to kill microorganisms including parasites. However, the IFN-γ-producing cells as well as the amebic antigen involved in the activation have not been identified. Here we demonstrate that mice challenged with live E. histolytica, and which are deficient of a specific lymphocyte population known as natural killer T cells (NKT cells), have a reduced capacity to control ameba infection and develop much larger amebic liver abscesses compared to normal mice. In addition, we isolated a molecule from the surface membrane of E. histolytica, which constitutes a lipopeptidophosphoglycan, and which activates NKT cells for the production of protective IFN-γ. Thus, our study provides a mechanism for the innate control of ameba invasion that might explain why the majority of E. histolytica-infected individuals do not develop amebic disease.


Entamoeba histolytica the causative agent of human amebiasis is an intestinal protozoan parasite that causes significant morbidity and mortality worldwide [1]. The main symptoms associated with ameba infection arise when the parasite breach the colonic mucosa, leading to severe hemorrhagic colitis or the development of extraintestinal abscesses, most commonly in the liver. Interestingly, only a small proportion of individuals infected with E. histolytica develop invasive amebiasis while the majority harbors the parasite in the gut without clinical signs of disease [2],[3]. From in vitro studies as well as from animal models for experimental amebic liver abscess (ALA) it is well documented that IFN-γ plays an important role in the early control of E. histolytica invasion. The development of amebicidal activity by neutrophils and monocytes in vitro is dependent on IFN-γ [4][7]. Accordingly, the depletion of IFN-γ by monoclonal antibodies or the targeted disruption of the IFN-γ receptor in mice led to more severe tissue destructions of the liver parenchyma in the mouse model for ALA [8],[9]. Effector lymphocytes with innate like functions such as γδ–T cells, natural killer cells or natural killer T (NKT) cells infiltrate into the center of experimental ALA and thus can serve as a source for the protective IFN-γ in the early phase of abscess development. Hence, mice deficient for γδ-T cells, but more importantly, Jα18−/− mice, lacking NKT-cells, have been shown to develop considerably larger abscesses compared to respective controls [8]. NKT cells are involved in immune responses in a broad range of diseases, including autoimmunity, allergy, cancer and infectious diseases [10]. Murine NKT cell populations are heterogeneous [11], but the majority expresses an invariant Vα14−Jα18 ΤCR and therefore they are referred to as invariant NKT (iNKT) cells, that unlike activation of conventional αβ−T cells by antigenic peptides, recognize glycolipids presented by the nonclassical antigen presenting molecule CD1d. Upon ligation of their TCR, iNKT cells can produce large amounts of a variety of cytokines with sometimes opposite function, including the pro-inflammatory IFN-γ as well as the anti-inflammatory IL-4, IL-10 and IL-13, which is believed to instruct the development of subsequent immune responses. The prototypical and by far most studied iNKT cell antigen is the glycolipid α-galactosylceramide (α-GalCer), a marine sponge glycolipid, which is a potent CD1d-restricted agonist widely used for in vitro and in vivo experiments to decipher iNKT cell function [12]. In recent years, it has been shown that iNKT cells can be activated directly by recognition of microbial glycolipids presented by CD1d or, indirectly by soluble mediators such as IL-12 and/or by recognition of endogenous ligands, both provided by dendritic cells (DC) s−stimulated via Toll-like receptors (TLRs) [10],[13]. In addition to α-GalCer, diverse natural CD1d ligands that stimulate iNKT cells have been identified in various microorgansims [14][18]. Accordingly, mice lacking NKT cells and in particular iNKT cells, have an increased susceptibility to various bacterial, fungal, and parasitic infections [8],[15],[17],[19].

Similar to other protozoa, E. histolytica exposes on its surface a complex GPI-anchored glycoconjugate, designated E. histolytica lipopeptidophosphoglycan (EhLPPG) [20]. As virulent and non-virulent amebae differ in the amount and the antigenicity of their LPPG these molecules have been associated with pathogenicity [21][24]. The structural analysis of EhLPPG revealed the presence of the Gal1Man2GlcN-myo-inositol motif linked to a phosphoserine backbone substituted by the linear carbohydrate chains [Glcα1-6]nGlcβ1-6Gal. Although a lipid anchor was proposed for this molecule, evidence concerning the structure of the lipid has not been provided so far. Thus, information is lacking whether this structure may facilitate a CD1d restricted activation of NKT cells in a CD1d restricted manner. However, toll-like receptor pathways were involved in the induction of IL-12, IL-8, IL-10 and TNFα by EhLPPG [25].

The study presented here was aimed to further investigate the role of NKT cells in the development of ALA, to isolate and characterize the structure of a potential natural ligand from E. histolytica trophozoites and to analyse the mechanism of NKT cell activation by dendritic cells presenting EhLPPG.


Control of amebic liver abscess requires presentation of glycolipids by CD1d

In a previous study we have shown that mice lacking Vα14-Jα18 iNKT cells have a reduced capacity to control experimentally induced amebic liver abscess (ALA). The lack of control in these knock out mice was evidenced by substantially larger abscess sizes and increased re-isolation rates of E. histolytica trophozoites from the liver lesions when compared to wild type controls [8]. To further investigate the role of iNKT cells in the control of ALA, we specifically activated iNKT cells by using the non-physiological ligand α-GalCer. Wild-type C57BL/6 mice were treated with a single dose of α-GalCer, 24 h prior to ameba challenge. This treatment resulted in a significant reduction of ALA lesions (p<0.003). In contrast, ALA in CD1d−/− mice, lacking iNKT and dNKT cells, were significantly increased, irrespectively whether or not treated with α-GalCer (p<0.006) (Fig. 1). The results indicate the importance of NKT cells in the control of abcess formation.


Figure 1. Role of NKT cells in the control of ALA in mice.

Mice treated with α-GalCer or mice lacking CD1d (CD1d−/−) were intrahepatically infected with virulent E. histolytica trophozoites. Seven days p.i. animals were sacrificed and sizes of liver abscesses determined. Bars represent sizes of abscess scores relative to those of wildtype control mice (WT). Results were obtained from 3 independent experiments comprising 5 to 7 animals each (statistics: Mann-Whitney U test).


Isolation of LPPG from E. histolytica trophozoites

The finding that CD1d is required to limit ALA development suggested that an ameba glycolipid that is presented by CD1d and which is able to activate iNKT cells is involved. A likely candidate is the E. histolytica LPPG (EhLPPG), which is present in considerable quantities on the surface of E. histolytica trophozoites. Accordingly, EhLPPG was isolated using an adaptation of the original reported method [26]. The EhLPPG recovered from the aqueous phase after hot phenol-water extraction was initially characterized by 12% SDS-PAGE gels and was visualized by different staining procedures (Fig. 2A). The purified EhLPPG yielded a negative staining with colloidal Coomassie-blue (lane 2), which detects as low as 30 ng of protein content. Positive reaction with the periodic acid Schiff (PAS) reagent (lane 3) or silver nitrate (lane 4) evidenced a high degree of glycosylation of the molecule resulting in a broad band with two major molecular mass regions between 97–200 kDa and 30–65 kDa, which was in agreement with previous reports [23],[27]. The presence of EhLPPG was further confirmed by a Western-blot developed with EH5 (lane 5), a monoclonal antibody specific for EhLPPG [28].


Figure 2. EhLLPG purified from membranes of E. histolytia trophozoites stimulates production of IFN-γ but not of IL-4 by splenocytes and liver lymphocytes.

(A) EhLPPG was separated by a 12% SDS-PAGE and developed by the following staining procedures: colloidal Coomassie (lane 2), periodic acid-Schiff staining (lane 3), a modified silver nitrate staining (lane 4) [61] and a Western-blot of EhLPPG developed with mAb EH5 (lane 5) [28]. A low molecular weight protein standard (BioRad), stained with colloidal Coomassie, is shown in lane 1. The negative stain in lane 2 revealed the abscence of major protein content, a positive staining in lane 3 and 4 evidenced the high glycosylation of the molecule and the detection by EH5 in lane 5 proved the identity of E. histolytica LPPG. (B,C) APC (1x105) were pulsed for 3 h with 2 µg α-GalCer or EhLPPG prior to co-cultivation with spleen or gradient separated liver lymphocytes (4x105). Supernatants were taken after 48 h and tested for the presence of IFN-γ (B) and IL-4 by ELISA (C). IFN-γ produced compared to DMSO control *( p<0.05); **( p<0.005), ***( p<0.001); Mann Whitney U-test. The results were obtained from experiments repeated at least 5 times.


Induction of IFN-γ by EhLPPG

In order to examine whether the purified EhLPPG was able to stimulate lymphocytes from wild-type C57BL/6 mice in vitro, antigen-presenting cells (APC) were generated and pulsed with α-GalCer or purified EhLPPG prior to co-cultivation with isolated liver or spleen lymphocytes. Supernatants were analysed for the presence of IFN-γ and IL-4, respectively. Stimulation of spleen or liver lymphocytes with α-GalCer or EhLPPG resulted in significant IFN-γ production (Fig. 2B). However, similar to recently described microbial glycolipids [17], the stimulation with EhLPPG reached only 30–50% of the IFN-γ levels induced by α-GalCer, possibly due to the exceptional strong affinity of the non-physiological ligand α-GalCer [29]. In contrast to α-GalCer, EhLPPG-induced lymphocytes did not produce significant amounts of IL-4 (Fig. 2C). The LPS content in the amebic EhLPPG preparations was below 0.25 EU/ml at an EhLPPG concentration of 2 µg/ml that induced significant levels of IFN-γ. This LPS concentration did not induce cytokine production in control experiments (data not shown).

Isolation and structural characterization of the phosphatidylinositol moiety from EhLPPG

To further characterize the portion of EhLPPG that might be responsible for lymphocyte activation, and in particular to determine whether the phosphatidylinositol moiety of the GPI anchor from EhLPPG (EhPI) is involved, EhPI was separated from EhLPPG after cleavage by nitrous acid deamination. HPTLC analyses demonstrated the presence of two products, designated EhPIa and EhPIb, respectively (Fig. 3A). These bands were isolated and analyzed by GC-MS after methanolysis and peracetylation in order to determine the chemical composition. Both EhPIa and EhPIb contained glycerol (Gro), Inositol (Ins), as well as the fatty acids 30:1, 28:0 and 16:0, respectively, the latter being present only in minor amount in EhPIa. ESIFT-ICRMS mass spectrometry revealed the presence of two prominent pseudomolecular ions at m/z 765.49 and m/z 739.47 in EhPIa, and at m/z 1003.72 and m/z 977.70 in EhPIb, evidencing a difference of [M]+26 m/z in both cases. The most abundant ions in EhPIa and EhPIb at m/z 739.47 and m/z 977.70, respectively, corresponded to the molecules containing 28:0, whereas the ions at m/z 765.49 (EhPIa) and m/z 1003.72 (EhPIb) corresponded to the molecules containing 30:1 (Fig. 3B). The fine structural characteristics of both molecules were deduced after ESI-IRMPD experiments (Fig. 3C). For EhPIa, the presence of the daughter ion at m/z 241.0 (inositol-1,2-cyclic phosphate) identified the parent ion as a PI and further indicated that the inositol ring was not acylated at the position 2 [30]. The additional presence of only one fatty acid carboxylate ion at m/z 449.4 (30:1) and the abundant presence of the ion at m/z 153.0 (cyclic glycerophosphate) identified this PI as a lyso-acyl anchor [31]. The ions at m/z 585.4 and m/z 315.0 corresponded to P+Gro+30:1 and Ins+P+Gro, respectively. In the case of EhPIb, the virtual absence of the ion at m/z 241.0 and the presence of the pseudomolecular ions at m/z 585.4 (showing the loss of the Ins+16:0 fragment) as well as at m/z 479.2 (P+Ins+16:0), demonstrated a substitution with 16:0 at position 2 of the Ins. Acylation of inositol was the only structural feature that differentiated EhPIb from EhPIa. Similar to EhPIa, the abundant presence of the ion at m/z 153.0 in EhPIb and the strong fatty acid carboxylate ion at m/z 449.4 (30:1), indicated a lyso-acyl anchor in this PI isoform as well [31]. Based on these results, the E. histolytica LPPG lipid anchors were assigned as 1-O-(28:0)-lyso-glycero-3-phosphatidylinositol for EhPIa and 1-O-[(28:0)-lyso-glycero-3-phosphatidyl-]2-O-(16:0)-inositol for EhPIb (Fig. 4A). Interestingly, stimulation of lymphocytes in the presence of EhLPPG or separated EhPIa and EhPIb, respectively, indicated that EhPIb, but not EhPIa, is the active portion of EhLPPG that contains the capacity to induce the production of IFN-γ (Fig. 4Β).


Figure 3. Structural characterization of the PI moieties of EhLPPG.

(A) Thin-layer chromatography. Lane 1, PI from Sigma, lane 2 shows the two isoforms EhPIa and EhPIb obtained after nitrous acid deamination ofEhPI. (B) EhPIs were analyzed by ESIFT-ICRMS. Negative ion mass spectrum of EhPIa (upper) and EhPIb (lower). The [M]-26 corresponded to the exchange in the use of a 30:1 or a 28:1 fatty acid. EhPIs were further analyzed by ESI-IRMPD. (C) Negative ion mass spectrum of the major parent ions found in EhPIa and EhPIb shown in (B).


Figure 4. Structure and NKT cell stimulatory capacity of EhPIs.

(A) The proposed structures of EhPIa (left) and EhPIb (right). The only difference between the EhPIs is the acylation of inositol at position 2 in EhPIb. The fatty acids and the molar ratios are indicated. (B) IFNγ production of NKT cells stimulated by APCs pulsed with α-GalCer, EhLPPG, EhPI, EhPIa and EhPIb. IFN-γ production compared to DMSO control *( p<0.05);**( p<0.005); ANOVA, Dunnett. The results were obtained from three independent experiments.


EhLPPG activates NKT cells in a CD1d-restricted manner

To determine whether indeed NKT cells are responsible for IFN-γ secretion after stimulation with EhLPPG or EhPI, lymphocytes were prepared from Jα18−/− or CD1d−/− mice lacking iNKT or all NKT subpopulations, respectively, and co-cultivated with EhLPPG- or EhPI-pulsed APC from wild-type C57BL/6 mice. Cells from both Jα18−/− and CD1d−/− mice revealed a strong reduction in IFN-γ secretion, indicating that iNKT cells represent the major source for IFN-γ. To further investigate CD1d-restriction of EhLPPG-mediated NKT-cell activation, APC from wild type or CD1d−/− mice were pulsed with α−GalCer, EhLPPG and EhPI, respectively, and co-cultivated with purified T cells from liver or spleen of Vα14 tg mice (Fig. 5B). As expected, in contrast to APC from wild type mice, APC from CD1d−/− mice were impaired in their ability to activate NKT cells. Purified T cells incubated with α-GalCer, EhLPPG and EhPI does not induce IFN-γ in the abscence of APC (data not shown). Taken together, these results suggest that EhLPPG and in particular EhPI activates iNKT cells to produce IFN-γ in a CD1d restricted manner.


Figure 5. CD1d-restricted NKT cell activation by EhLPPG and EhPI.

(A) APC (5x104) from WT mice were pulsed with either 2 µg of α-GalCer, EhLPPG or EhPI and incubated with 1x105 lymphocytes of spleen cell preparations from Jα 18−/− lacking iNKT cells and CD1d−/− mice lacking iNKT and dNKT cells. IFN-γ secretion was measured by ELISA. Difference of IFN-γ production in EhLPPG/EhPI activated WT splenocytes *( p<0.05);**( p<0.005),***( p<0.001); ANOVA, Dunnett. (B) APC were generated from either WT or CD1d−/− mice, pulsed as described above and incubated with gradient purified liver lymphocytes from Vα14-transgenic mice. Liver iNKT cells were further purified by magnetic cells sorting. IFN-γ was assessed by ELISA. Difference of IFN-γ production in EhLPPG/EhPI activated WT splenocytes *( p<0.05); student t test. The results were obtained from three independent experiments.


EhLPPG-induced NKT cell activation requires toll-like–receptor 2/6 and functional IL-12

To determine whether CD1d-restricted iNKT cell activation by EhLPPG requires the involvement of Toll-like-receptor (TLR) pathways, APC from knock out mice lacking the TLR-related adapter molecules MyD88 and TRIF, respectively, were pulsed with EhLPPG or EhPI and co-cultivated with T cells from Vα14 tg mice (Vα14iNKT). In addition, parallel experiments were performed with APC from mice lacking TLR1, TLR2 or TLR6, or with APC that are impaired to produce functional IL-12 (IL-12p40−/−) (Fig. 6). The results indicated that a TLR pathway other than TLR3 is required for iNKT cell activation, as APC generated from MyD88−/− but not from TRIF−/− mice were unable to induce IFN-γ by Vα14iNKT cells. Moreover, the finding that IFN-γ is induced by APC from TLR1−/−, but not by those generated from TLR2−/− and TLR6−/− mice suggested that EhLPPG or EhPI were capable to activate APC by binding to TLR2, TLR6 or to TLR2-TLR6 heterodimers. In addition to TLR2 and/or TLR6 signaling, iNKT cell activation by EhLPPG or EhPI required the presence of functional IL-12, as APC from IL-12p40−/− mice were incapable to induce IFN-γ production by Vα14iNKT cells.


Figure 6. Activation of NKT cells by EhLPPG involves molecules of the TLR signalling pathway.

APC from IL12-p40−/−, MyD88−/−, TRIF−/− (A), CD1d−/−, TLR2−/−, 4−/−, 9−/− (B), and TLR1−/−, 2−/− and 6−/− (C) were generated, pulsed with EhLPPG and used to stimulate purified T cells from Vα14tg mice. The production of IFN-γ by purifed T cells was determined by ELISA. EhLPPG-dependent NKT cell activation was abrogated in CD1d−/−, IL-12p40−/−, MyD88 and TLR 2−/− and TLR 6−/− mice. The results were obtained from two independent experiments.


We did not detect IL-4 in the supernatants of the co-culture experiments using APC from the various knock-out mutants pulsed with EhLPPG and iNKT cells (data not shown).

EhLPPG is internalized by APC

To gain more insight into the CD1d-restricted activation process we performed several experiments to evaluate if EhLPPG directly binds to CD1d without further processing. To this end EhLPPG was incubated with plate bound CD1d and purified NKT cells. However, no activation of NKT cells was observed. Also CD1d-tetramer incubated with EhLPPG was unable to stain NKT cells (data not shown). These data suggest that EhLPPG cannot bind directly to CD1d molecules. In order to analyse whether EhLPPG enter the endocytic pathway which would allow further processing as a prerequisite for presentation on CD1d, we performed immunofluorescence analysis using the monoclonal anti-EhLPPG antibody EH5. Here we found that the ameba lipopeptidophosphoglycan is internalized as anti-EH5 staining was found to co-localize with Lamp-1 positive vesicles (Fig. 7A). Thus, EhLPPG was targeted to lysosomes and/or late endosomes which would allow processing and loading of the molecule to CD1d. To corroborate this finding we inhibited the internalization and processing of antigens by pre-incubation of APC with bafilomycin A1, which interferes with the uptake of macromolecules in endosomes [32]. The inhibition of endocytosis abrogated the IFN-γ production of NKT cells by EhLPPG and α-GalCer, but not the IFN-γ production induced by the TLR-specific activators PamCys or LPS used as positive controls [33],[34]. In addition the incubation of antigen-pulsed APC with the mAb EH5, but not with an isotype control (data not shown), inhibited the IFN-γ production of NKT cells in response to EhLPPG (Fig. 7B). This may indicate that the mAb EH5 recognizes EhLPPG presented on CD1d and thus prevented binding to the T cell receptor. Collectively these data indicate that a processing of the EhLPPG molecule is necessary to allow its presentation via CD1d.


Figure 7. EhLPPG is internalized and requires processing or endosomal trafficking for activation of NKT cells.

(A) WT APC were pulsed with 20 µg/ml EhLPPG for 3 h, fixed with 4% PFA and permeabilized with 0.5% saponin; EhLPPG was labeled with mAb EH5 [28] and anti Lamp-1 mAb was used for detection of late endosomes by confocal microscopy. The experiment was performed four times. (B) Treatment of APC with an inhibitor of endocytosis, bafilomycin A1 (10 nM, 30 min), led to a decrease in the IFN-γ production in NKT cells after stimulation with α-GalCer (4 µg/ml) and EhLPPG (10 µg), but not with PamCys (4 µg/ml) and LPS (1 ng/ml). The addition of mAb EH5 (100 µg/ml) to APC pulsed with α-GalCer and EhLPPG specifically inhibited the IFN-γ secretion of cocultured NKT cells.


EhLPPG treatment reduces the severity of ALA

To investigate whether EhLPPG similar to α-GalCer is able to inhibit ALA development wildtype mice were treated with purified EhLPPG 24 h prior to intrahepatic challenge with virulent E. histolytica trophozoites. The results clearly indicate significant protection in EhLPPG treated mice compared to respective controls (Fig. 8).


Figure 8. Development of ALA in EhLPPG treated mice.

24 h prior to intrahepatic challenge with virulent E. histolytica trophozoites, WT mice were treated with 4 µg EhLPPG by i.p. application. Seven days post infection, mice were sacrificed and sizes of abscesses were determined. Shown are sizes of ALA in EhLPPG treated mice relative to untreated controls. Results were obtained from 2 independent experiments comprising 5 to 6 animals each (statistics: Mann-Whitney U test).



The majority of individuals infected with E. histolytica harbor the parasite within the gut without any clinical signs of disease. Only a small proportion may develop invasive amebaisis, e.g. amebic colitis or amebic liver abscess (ALA). In this study we report on the isolation and characterization of an E. histolytica lipopeptidophosphoglycan (EhLPPG) that activates iNKT cells which were previously shown to be crucial in the control of ALA in a mouse model for disease [8]. EhLPPG was found to be a potent stimulator of NKT cells to produce IFN-γ, but not IL-4. Structural characterization revealed that a particular phosphatidylinositol (EhPI) isoform present within the GPI anchor of EhLPPG constitutes the active component for IFN-γ induction. Dissection of the pathway involved in NKT cell activation indicated that direct recognition of EhLPPG or EhPI presented on CD1d was not sufficient for NKT cell activation, as it also required TLR signaling and IL-12 production.

The importance of NKT cells for the control of ALA in vivo was previously shown by the use of Jα 18−/− mice lacking iNKT cells [8] and further confirmed in this study by the finding that CD1d−/− mice lacking both iNKT and dNKT cells are more susceptible to ALA development. In addition, application of the most potent and specific NKT cell activator, α-GalCer reduced sizes of ALA significantly. Likewise, mouse models for malaria, trypanosomiasis or cryptococcus infection have shown that a single treatment with α-GalCer rapidly stimulated IFN-γ production by iNKT cells and reduced parasite and bacterial burden, respectively [19],[35],[36].

EhLPPG, which is expressed on the surface of E. histolytica trophozoites [20],[23],[27],[37] was identified as the ameba molecule that activates iNKT cells in vitro and which is able to reduce ALA development when applied to mice prior to amebic challenge. To this end we isolated the EhLPPG by an improvement of the original method [26]. This method reduced the possibility of contamination with phospholipids and small glycolipids that could be co-extracted with LPPG and thus may interfere with/or compete for the binding to CD1d, or may potentially provide an indirect stimulus by ligation of TLR. A basic biochemical characterization demonstrated the highly glycosylated nature of the purified compound, which was further identified as EhLPPG by its reactivity with the EhLPPG-specific monoclonal antibody EH5 [28]. EhLPPG is structurally related to glycoconjugates dominating the cell surfaces of other protozoa like Trypanosoma brucei, T. cruzi, Leishmania and Plasmodium. Previous studies on EhLPPG in which the structure was partially characterized indicated the presence of the consensus sequence Gal1Man2GlcN-myo-inositol that corresponds to the core region of GPI anchored molecules, although the nature and arrangement of the lipid portion linked to the inositol moiety remained unclear [27]. In the study presented, it is demonstrated that the EhLPPG is in fact a GPI anchored molecule, applying biochemical degradation, gas chromatography and mass spectrometry of its PI moieties. From these results it is concluded that E. histolytica trophozoites posses two isoforms of PI, EhPIa and EhPIb, respectively (Fig. 3A). In EhPIa, the glycerol is only substituted at the sn-1 position by a single, long fatty acid chain (28:0 or 30:1), similarly to LPG from Leishmania major [38]. EhPIb bears the same substitution with 28:0 or 30:1 at the sn-1 of glycerol but interestingly had an additional 16:0 in the inositol ring, which is not a common feature among protozoa [39], although it was found in Plasmodium falciparum GPI [40] and in T. brucei PARP GPI, where the glycerol is monoacylated as well as the inositol is substituted by 16:0 [41]. This non-common fatty acid distribution might confer particular biological properties to EhLPPG in the interaction with components of the innate immune system like CD1d molecules. These molecules belong to a family of major histocompatibility antigen-like molecules that bind gycophosphinositol with a high affinity and regulate the function and differentiation of NKT cells [42].

In vitro stimulation of APC by EhLPPG induced secretion of IFN-γ by NKT cells. However, compared to α-GalCer, stimulation with EhLPPG was significantly weaker, similar to levels obtained with glycolipid preparations from other microorganisms such as bacteria or protozoa [16][18]. The strong induction of IFN-γ by α-GalCer might be due to the composition and length of the alkyl (C26:0) and sphingosine (C18:0) chains, which appear to be optimal for CD1d binding [43]. On the other hand and in contrast to α-GalCer, EhLPPG did not induce secretion of IL-4. Although the mechanism for the induction of IL-4 is not well understood, a recent investigation suggested that the length of the lipid chain plays an essential role since the truncation of the sphingosine chain promoted the induction of IL-4 and triggered a Th2 immune response [44].

Activation of iNKT cells due to microbial infections can be achieved through direct or indirect pathways (for rev. see [10]). The direct, cognate or antigen mediated activation requires the uptake of the glycolipid, processing and subsequent loading to CD1d molecules in the endosomes of the APC. In this scenario, iNKT cells are engaged via their invariant TCR recognizing antigen presented on CD1d without any contribution of additional cytokines released from the APC. Beside α-GalCer as the classical direct activator of iNKT cells, glycolipids from various bacteria or protozoa have the capacity to activate NKT cells by CD1d restriction independent from cytokines provided by the APC [15][18]. For indirect or adjuvant-like activation of iNKT cells, different possible pathways have been proposed. One of the indirect pathways involves the recognition of PAMPS by TLR resulting in the induction of IL-12 and/or IL-18 activating NKT cells in a CD1d-independent manner [45]. During Salmonella typhimurium infection, the NKT cell response depends on IL-12 and additionally on CD1d recognition [46]. Another activation mechanism has been described for LPS which induces IFN-γ production in NKT cells via IL-12 and IL- [34]. A third alternative is an indirect activation pathway induced by parasite eggs. Here endogenous glycolipid is upregulated by a yet unknown mechanism and presented via CD1d to NKT cells. So far, this mechanism has been described only for DCs sensitized with eggs from Schistosoma mansoni [47]. From the results presented here using a series of knock-out mice we conclude that activation of iNKT cells by EhLPPG or EhPI requires both presentation of EhPI by CD1d as well as TLR signalling and IL-12 production.

In addition, we provide evidence that endocytosis and processing of EhLPPG is a prerequisite for CD1d-dependent NKT cell activation since i) we could not find a direct binding of EhLPPG to recombinant CD1d, ii) EhLPPG was found to co-localize with Lamp-1 as a marker for late endosomes which would allow processing and loading of the molecule to CD1d and iii) we showed that NKT cell activation is abrogated when APC endocytosis was inhibited by bafilomycin [48]. In addition, the incubation of APC with the mAb EH5 inhibited the IFN-γ production of NKT cells in response to EhLPPG. The finding that induction of IFN-γ by APC from TLR2−/− and TLR6−/− mice is abrogated suggests that EhLPPG and EhPI is capable to activate the APC by binding through these TLR. This is in agreement with recent results that diacylated motifs, as also present in the active EhPIb isoform, bind to TLR2-TLR6 heterodimers, while triacylated molecules engage TLR2-TLR1 heterodimers [49],[50]. However, we can not exclude that the inability of EhLPPG and recombinant CD1d to stimulate NKT cells is due to a lack of costimulatory molecules and/or cytokines. Moreover, the lack of direct binding of EhLPPG to CD1d might indicate that the observed activation of NKT cells by EhLPPG also involves an increased presentation of self-antigens by CD1d.

Interestingly, we did not find activity with the monoacylated EhPIa isoform, although such a structure is in principle capable to activate NKT cells via TLR2 and CD1d dependent pathways as shown for a structurally related LPG from Leishmania [15],[51]. In consideration of an adjuvant effect of TLR-ligands during activation of CD1d-restricted NKT cell, traces of contaminating lipopeptides could also be responsible for the TLR2-dependent response [52]. However, the double extraction method (chloroform methanol water and phenol water) used for the purification of EhLPPG should minimize the risk of contamination [53].

Our data demonstrate that early IFN-γ production by NKT cells is responsible for a sufficient control of parasites in the liver. In addition, NKT cells provide a link between innate and adaptive immunity due to their capacity to early produce large amounts of IFN-γ and IL-4 that can bias the immune response into either a TH1-or TH2 direction. The exclusive IFN-γ production of EhLPPG activated NKT cells can be expected to trigger the subsequent adaptive immune response into a TH1 type that would provide additional IFN-γ. This might augment efficient abcess control by T cell dependent mechanisms at later time points.

Taken together the results presented here indicate that EhLPPG is able to limit ALA development most likely due to its ability to specifically activate iNKT cells to produce IFN-γ. The importance of IFN-γ for the control of E. histolytica has been documented in various investigations [4],[5],[7],[8],[9],[54]. In particular, the mouse model used in this study recently revealed that the application of IFN-γ - neutralizing antibodies abrogates ALA development. Thus EhLPPG constitutes an ameba molecule that is critically important to control ALA and which might be responsible for the lack of amebic disease in the majority of E. histolytica infected individuals.

Materials and Methods

Cultivation of E. histolytica

Trophozoites of the E. histolytica isolate HM-1:IMSS were grown axenically in TYI-S-3 medium [55]. To maintain virulence, trophozoites were regularly passaged through the liver of C57BL/6 mice as described previously [8].

Origin of mice

Wild-type C57BL/6 (WT), Vα14-Jα18 transgenic (tg), TLR1−/−, TLR6−/−, CD1d−/− and Jα18−/− were bred and housed under specific pathogen-free conditions at the Bernhard Nocht Institute for Tropical Medicine (Hamburg). IL12p40−/−; TLR2−/− and MyD88−/− were kindly provided by Christoph Hölscher, Research Center Borstel, Germany. TRIF−/− were kindly provided by Bruce Beutler, La Jolla, California. All mice were backcrossed on a B6 genetic background for >10 generations.

Experimental amebic liver abscess and treatment with α-GalCer

Amebic liver abscesses were induced by direct intrahepatic inoculation of virulent E. histolytica trophozoites as previously described [56] with minor modifications for the use of C57BL/6 mice [8]. The influence of α-GalCer and EhLPPG on the abscess formation was investigated by intraperitoneal application of 2 µg α-GalCer (Alexis, Axxora) or 4 µg EhLPPG diluted in PBS/0.05% Tween 20 per animal 24 h prior to amebic challenge. In our previous work we found that abscesses are self-limited and were resolved until day 21 post infection. Performing a kinetic analysis of abcess formation we found that day seven post infection is the most appropriate time point for studying the influence of immune mechanisms on abcess size [8]. Therefore, on day seven post intrahepatic inoculation of E. histolytica trophozoites, the animals were sacrificed and the size of the abscess lesions were measured in mm, a score was introduced and related to the score of ALA found in WT mice (score: 0 = no abscess; 1 = <1 mm; 2 = 1–5 mm; 3 = >5 mm).

Isolation of EhLPPG and its phosphatidylinositol (EhPI) moiety

Trophozoites of the late logarithmic phase of growth were washed, resuspended in pyrogen free water and lysed by freeze and thawing. The homogenate was centrifuged at 430 g at 4°C for 10 min and subsequently the supernatant was recovered and ultracentrifuged at 150,000 g for 40 min [57]. The obtained pellet was extracted with a mixture of chloroform/methanol/water 10:10:3 (by volume) and the insoluble material was recovered by centrifugation, dried, resuspended in distilled pyrogen free water and extracted three times with an equal volume of 90% phenol at 68°C for 30 min with constant stirring [58]. The water phase containing EhLPPG was recovered after centrifugation at 12,000 g for 30 min and dialysis against distilled water. In order to obtain the EhPI moiety, nitrous acid deamination was performed as described [59]. In brief, dried EhLPPG was resuspended in a mixture of 0.3 M sodium acetate buffer at pH 4.0 and 1 M sodium nitrite, incubated at 37°C for 2 h. The released EhPI moiety was recovered from the organic phase after partition between water and water-saturated 1-butanol. The organic phase was then dried under a stream of nitrogen and resuspended in a mixture of chloroform/methanol/water 10:10:3 (by volume) for analysis on Silica Gel 60 high-performance thin-layer chromatography (HPTLC) plates. EhPIa and EhPIb were separated on a preparative HPTLC and re-extracted with a mixture of Chloroform/methanol/water 10:10:3 (by volume). For the use in cell stimulation, PI, PIa and PIb were dried under a stream of nitrogen and resuspened in PBS/Tween (0.05%). EhLPPG and EhPI samples contained <0.25 endotoxin units (EU) per ml at the concentrations used for cell activation, as determined by the Limulus amoebocyte lysate assays (Cambrex).

Immunochemical and spectroscopic analysis

EhLPPG (10 µg/lane) was analyzed by 12% SDS-PAGE and either stained to evidence the presence of protein (Coomassie brilliant blue) and carbohydrates (silver nitrate and periodic acid Schiff), or transferred to a PVDF membrane for Western blot analysis and subsequently developed with the LPPG-specific monoclonal antibody EH5 [28]. For compositional analyses, EhLPPG and EhPI were subjected to methanolysis. 150 µl of 0.5 M hydrochloric acid in dry methanol was added and the solution incubated at 85°C for 1 h, followed by addition of 50 µl of both pyridine and acetic anhydride and analyzed by GC-MS on a Hewlett Packard GL 5890 Gas chromatograph equipped with an Ultra-1 column (Agilent) and coupled to an electron impact mass detector.

Electrospray Ionization Fourier Transform Ion Cyclotron Mass Spectrometry (ESI FT-ICR MS) was performed in the negative ion mode using an APEX Qe – Instrument (Bruker Daltonics, Billerica, USA) equipped with a 7 Tesla actively shielded magnet. Mass spectra were acquired using standard experimental sequences as provided by the manufacturer. Samples were dissolved at a concentration of ~10 ng/µl in a 50:50:0.001 (v/v/v) mixture of 2-propanol, water, and triethylamine and sprayed at a flow rate of 2 µl/min. Capillary entrance voltage was set to 3.8 kV, and dry gas temperature to 150°C.

Infrared-multiphoton dissociation (IRMPD) of isolated parent ions was performed with a 35 W, 106 µm CO2 laser (Synrad, Mukilteo, WA). The unfocused laser beam was directed through the center of the ICR cell and fragment ions were detected after a delay of 0.5 ms. The duration of laser irradiation was adapted for each sample to generate optimal fragmentation and varied between 10–80 ms.

Generation of APC

Bone marrow was harvested from femurs of 6- to 10-week-old mice and cultured as described by Lutz et al. [60]. Cultures were supplemented with supernatants from Ag8653 myeloma cells transfected with the gene coding for murine GM-CSF (kindly provided by B. Stockinger, NMRI, Mill Hill, London, UK). The percentage of mature cells was determined by FACS analysis using anti- CD11c - APC, anti - CD40-FITC, anti - CD86-PE or anti - CD80 (BD-Bioscience) and ranged from 20–23%.

Isolation of cells from spleen and liver

Spleens were perfused with hypotonic ammonium chlorid solution for erythrolysis. Subsequently, cells were washed twice with medium and adjusted to the appropriate number. Livers were perfused with ice cold PBS/20% FCS solution and subsequently filtered through a 40 µm mesh. Following centrifugation at 400 g, cell pellets were resuspended in RPMI-20 medium, underlayed with a 30% Nycodenz solution (NycoprepTM, Universal) and centrifuged at 900 g for 20 min. The liver lymphocytes were collected from the interface, treated with hypotonic ammonium chloride solution, washed and subjected to magnetic bead sorting using the Pan T-cell isolation kit (Macs, Myltenyi). NKT-cell populations were analyzed for purity by flow cytometry using α-GalCer (Alexis; Axora) loaded CD1d-tetramer-PE (Proimmune) and anti-CD4-FITC (BD Bioscience). Purified NKT cells did not produce IFN-γ after cultivation with α-GalCer in the abscence of aditional APC.

Co-culture of APC with NKT cells isolated from spleen or liver

BMDC were used as antigen presenting cells (APC). In brief, 4×104 cells/well were cultured in triplicates in 96-well round bottom plates with RPMI-20 medium, supplemented with FCS, L-glutamine, antibiotics, sodium pyruvate. The cells were pulsed with α-GalCer or purified amebic EhLPPG or EhPI at indicated concentrations for 3 h. NKT-cell enriched spleen and liver lymphocytes were then added to the pulsed APC with 1×105 cells/well and incubated for 24 h (IL-4) and 48 h (IFN-γ). Cytokines were measured with the respective sandwhich ELISA for IL-4 and IFN-γ (R&D System). To block the processing and presentation pathway, APCs were treated with 10 nM bafilomycin A1 (Sigma) 30 min before incubation with EhLPPG, α-GalCer, PamCys-SKK (EMC, Germany) or LPS (E. coli, serotype 055:B5; SIGMA). In an additional set of experiments APC were pulsed for 3 h with EhLPPG or α-GalCer. Subsequently APC were incubated with 100 µg/ml mAb EH5 [28] before the addition of NKT cells.

Intracellular localization of EhLPPG

APC from WT BL6 mice were pulsed with 20 µg/ml of EhLPPG and seeded in 24-well plates with glass coverslips and incubated with 5%CO2 at 37°C for 3 h. Subsequently, cells were washed, fixed with 4% paraformaldehyde and permeabilized with 0.5% saponin (Sigma). Intracellular EhLPPG was stained with mouse-monoclonal antibody EH5 [28] followed by Alexa 594 labeled anti-mouse IgG (Invitrogen). The internalized EhLPPG colocalized with a rat anti- CD107a/LAMP-1 Mab (Southern Biotec) and Alexa 488 labelled anti-rat IgG (Invitrogen). Nuclei were stained with 4‵,6‵-diamidino-2-phenylindole hydrochloride (DAPI). All stainings were visualized with a Leica DRM confocal microscope and OpenLab software (Improvison. Inc).


Statistics were performed using Prism statistical software (GraphPad) unpaired, one-way, non parametric Mann-Whitney U tests, the ANOVA, Dunnett and the student t test.


The authors thank Claudia Marggraff, Iris Gaworski, and Thomas Bickert for expert technical support and Regina Engel for GC-MS analysis.

Author Contributions

Conceived and designed the experiments: HL NGR FW AI MML AJU OH ET TJ. Performed the experiments: HL NGR BL TJ. Analyzed the data: HL NGR BL FW AJU OH ET TJ. Contributed reagents/materials/analysis tools: HL BL AJU OH ET TJ. Wrote the paper: HL OH. Supervisor and Grant supplier for the PhD student NGR: AI. Supervisor of NGR at the university: MML. Supplied the grant, position for HL: ET.


  1. 1. WHO (1997) Amoebiasis. Wkly Epidemiol Rec 72: 97–99.
  2. 2. Blessmann J, Van Linh P, Nu PA, Thi HD, Muller-Myhsok B, et al. (2002) Epidemiology of amebiasis in a region of high incidence of amebic liver abscess in central Vietnam. Am J Trop Med Hyg 66: 578–583.
  3. 3. Petri WA Jr, Haque R, Lyerly D, Vines RR (2001) Revisiting amebiasis. Trends Parasitol 17: 65.
  4. 4. Salata RA, Murray HW, Rubin BY, Ravdin JI (1987) The role of gamma interferon in the generation of human macrophages cytotoxic for Entamoeba histolytica trophozoites. Am J Trop Med Hyg 37: 72–78.
  5. 5. Denis M, Chadee K (1989) Cytokine activation of murine macrophages for in vitro killing of Entamoeba histolytica trophozoites. Infect Immun 57: 1750–1756.
  6. 6. Denis M, Chadee K (1989) Human neutrophils activated by interferon-gamma and tumour necrosis factor-alpha kill Entamoeba histolytica trophozoites in vitro. J Leukoc Biol 46: 270–274.
  7. 7. Ghadirian E, Salimi A (1993) In vitro effect of recombinant interferon gamma in combination with LPS on amoebicidal activity of murine Kupffer cells. Immunobiology 188: 203–219.
  8. 8. Lotter H, Jacobs T, Gaworski I, Tannich E (2006) Sexual dimorphismin the control of amebic liver abscess in a mouse model of disease. Infect Immun 74: 118–124.
  9. 9. Seydel KB, Smith SJ, Stanley SL Jr (2000) Innate immunity to amebic liver abscess is dependent on gamma interferon and nitric oxide in a murine model of disease. Infect Immun 68: 400–402.
  10. 10. Tupin E, Kinjo Y, Kronenberg M (2007) The unique role of natural killer T cells in the response to microorganisms. Nat Rev Microbiol 5: 405–417.
  11. 11. Godfrey DI, MacDonald HR, Kronenberg M, Smyth MJ, Van Kaer L (2004) NKT cells: what's in a name? Nat Rev Immunol 4: 231–237.
  12. 12. Morita M, Motoki K, Akimoto K, Natori T, Sakai T, et al. (1995) Structure-activity relationship of alpha-galactosylceramides against B16-bearing mice. J Med Chem 38: 2176–2187.
  13. 13. Moody DB (2006) TLR gateways to CD1 function. Nat Immunol 7: 811–817.
  14. 14. Procopio DO, Almeida IC, Torrecilhas AC, Cardoso JE, Teyton L, et al. (2002) Glycosylphosphatidylinositol-anchored mucin-like glycoproteins from Trypanosoma cruzi bind to CD1d but do not elicit dominant innate or adaptive immune responses via the CD1d/NKT cell pathway. J Immunol 169: 3926–3933.
  15. 15. Amprey JL, Im JS, Turco SJ, Murray HW, Illarionov PA, et al. (2004) A subset of liver NK T cells is activated during Leishmania donovani infection by CD1d-bound lipophosphoglycan. J Exp Med 200: 895–904.
  16. 16. Fischer K, Scotet E, Niemeyer M, Koebernick H, Zerrahn J, et al. (2004) Mycobacterial phosphatidylinositol mannoside is a natural antigen for CD1d-restricted T cells. Proc Natl Acad Sci U S A 101: 10685–10690.
  17. 17. Mattner J, Debord KL, Ismail N, Goff RD, Cantu C 3rd, et al. (2005) Exogenous and endogenous glycolipid antigens activate NKT cells during microbial infections. Nature 434: 525–529.
  18. 18. Kinjo Y, Tupin E, Wu D, Fujio M, Garcia-Navarro R, et al. (2006) Natural killer T cells recognize diacylglycerol antigens from pathogenic bacteria. Nat Immunol 7: 978–986.
  19. 19. Kawakami K, Kinjo Y, Yara S, Koguchi Y, Uezu K, et al. (2001) Activation of Valpha14(+) natural killer T cells by alpha-galactosylceramide results in development of Th1 response and local host resistance in mice infected with Cryptococcus neoformans. Infect Immun 69: 213–220.
  20. 20. Isibasi A, Santa Cruz M, Soto Montano X, Ramirez A, Kumate J (1982) [Localization of a lipopeptidophosphoglycan extracted by phenol-water from trophozoites of the HK-9 strain of Entamoeba histolytica]. Arch Invest Med (Mex) 13: (Suppl 3)57–62.
  21. 21. Bhattacharya A, Prasad R, Sacks DL (1992) Identification and partial characterization of a lipophosphoglycan from a pathogenic strain of Entamoeba histolytica. Mol Biochem Parasitol 56: 161–168.
  22. 22. Srivastava G, Anand MT, Bhattacharya S, Bhattacharya A (1995) Lipophosphoglycan is present in distinctly different form in different Entamoeba histolytica strains and absent in Entamoeba moshkovskii and Entamoeba invadens. J Eukaryot Microbiol 42: 617–622.
  23. 23. Moody S, Becker S, Nuchamowitz Y, Mirelman D (1997) Virulent and avirulent Entamoeba histolytica and E. dispar differ in their cell surface phosphorylated glycolipids. Parasitology 114 (Pt 2): 95–104.
  24. 24. Moody S, Becker S, Nuchamowitz Y, Mirelman D (1998) Identification of significant variation in the composition of lipophosphoglycan-like molecules of E. histolytica and E. dispar. J Eukaryot Microbiol 45: 9S–12S.
  25. 25. Maldonado-Bernal C, Kirschning CJ, Rosenstein Y, Rocha LM, Rios-Sarabia N, et al. (2005) The innate immune response to Entamoeba histolytica lipopeptidophosphoglycan is mediated by toll-like receptors 2 and 4. Parasite Immunol 27: 127–137.
  26. 26. Isibasi A, Santa Cruz M, Ramirez A, Kumate J (1982) [Immunochemistry of a lipopeptidophosphoglycan extracted from trophozoites of Entamoeba histolytica strain HK-9 cultivated in axenic media, using the phenol-water method]. Arch Invest Med (Mex) 13: (Suppl 3)51–55.
  27. 27. Moody-Haupt S, Patterson JH, Mirelman D, McConville MJ (2000) The major surface antigens of Entamoeba histolytica trophozoites are GPI-anchored proteophosphoglycans. J Mol Biol 297: 409–420.
  28. 28. Marinets A, Zhang T, Guillen N, Gounon P, Bohle B, et al. (1997) Protection against invasive amebiasis by a single monoclonal antibody directed against a lipophosphoglycan antigen localized on the surface of Entamoeba histolytica. J Exp Med 186: 1557–1565.
  29. 29. Kawano T, Cui J, Koezuka Y, Toura I, Kaneko Y, et al. (1997) CD1d-restricted and TCR-mediated activation of valpha14 NKT cells by glycosylceramides. Science 278: 1626–1629.
  30. 30. Treumann A, Lifely MR, Schneider P, Ferguson MA (1995) Primary structure of CD52. J Biol Chem 270: 6088–6099.
  31. 31. Treumann A, Guther ML, Schneider P, Ferguson MA (1998) Analysis of the carbohydrate and lipid components of glycosylphosphatidylinositol structures. Methods Mol Biol 76: 213–235.
  32. 32. Prigozy TI, Naidenko O, Qasba P, Elewaut D, Brossay L, et al. (2001) Glycolipid antigen processing for presentation by CD1d molecules. Science 291: 664–667.
  33. 33. Takeuchi O, Kawai T, Muhlradt PF, Morr M, Radolf JD, et al. (2001) Discrimination of bacterial lipoproteins by Toll-like receptor 6. Int Immunol 13: 933–940.
  34. 34. Nagarajan NA, Kronenberg M (2007) Invariant NKT cells amplify the innate immune response to lipopolysaccharide. J Immunol 178: 2706–2713.
  35. 35. Gonzalez-Aseguinolaza G, de Oliveira C, Tomaska M, Hong S, Bruna-Romero O, et al. (2000) alpha -galactosylceramide-activated Valpha 14 natural killer T cells mediate protection against murine malaria. Proc Natl Acad Sci U S A 97: 8461–8466.
  36. 36. Duthie MS, Kahn SJ (2002) Treatment with alpha-galactosylceramide before Trypanosoma cruzi infection provides protection or induces failure to thrive. J Immunol 168: 5778–5785.
  37. 37. Prasad R, Tola M, Bhattacharya S, Sharma MP, Bhattacharya A (1992) Recognition of Entamoeba histolytica lipophosphoglycan by a strain-specific monoclonal antibody and human immune sera. Mol Biochem Parasitol 56: 279–287.
  38. 38. McConville MJ, Thomas-Oates JE, Ferguson MA, Homans SW (1990) Structure of the lipophosphoglycan from Leishmania major. J Biol Chem 265: 19611–19623.
  39. 39. Ferguson MA (1999) The structure, biosynthesis and functions of glycosylphosphatidylinositol anchors, and the contributions of trypanosome research. J Cell Sci 112 (Pt 17): 2799–2809.
  40. 40. Naik RS, Branch OH, Woods AS, Vijaykumar M, Perkins DJ, et al. (2000) Glycosylphosphatidylinositol anchors of Plasmodium falciparum: molecular characterization and naturally elicited antibody response that may provide immunity to malaria pathogenesis. J Exp Med 192: 1563–1576.
  41. 41. Field MC, Menon AK, Cross GA (1991) A glycosylphosphatidylinositol protein anchor from procyclic stage Trypanosoma brucei: lipid structure and biosynthesis. Embo J 10: 2731–2739.
  42. 42. Joyce S, Woods AS, Yewdell JW, Bennink JR, De Silva AD, et al. (1998) Natural ligand of mouse CD1d1: cellular glycosylphosphatidylinositol. Science 279: 1541–1544.
  43. 43. McCarthy C, Shepherd D, Fleire S, Stronge VS, Koch M, et al. (2007) The length of lipids bound to human CD1d molecules modulates the affinity of NKT cell TCR and the threshold of NKT cell activation. J Exp Med 204: 1131–1144.
  44. 44. Miyamoto K, Miyake S, Yamamura T (2001) A synthetic glycolipid prevents autoimmune encephalomyelitis by inducing TH2 bias of natural killer T cells. Nature 413: 531–534.
  45. 45. Janeway CA Jr, Medzhitov R (2002) Innate immune recognition. Annu Rev Immunol 20: 197–216.
  46. 46. Brigl M, Bry L, Kent SC, Gumperz JE, Brenner MB (2003) Mechanism of CD1d-restricted natural killer T cell activation during microbial infection. Nat Immunol 4: 1230–1237.
  47. 47. Mallevaey T, Zanetta JP, Faveeuw C, Fontaine J, Maes E, et al. (2006) Activation of invariant NKT cells by the helminth parasite schistosoma mansoni. J Immunol 176: 2476–2485.
  48. 48. Shacka JJ, Klocke BJ, Roth KA (2006) Autophagy, bafilomycin and cell death: the “a-B-cs” of plecomacrolide-induced neuroprotection. Autophagy 2: 228–230.
  49. 49. O'Neill LA, Bowie AG (2007) The family of five: TIR-domain-containing adaptors in Toll-like receptor signalling. Nat Rev Immunol 7: 353–364.
  50. 50. Farhat K, Riekenberg S, Heine H, Debarry J, Lang R, et al. (2008) Heterodimerization of TLR2 with TLR1 or TLR6 expands the ligand spectrum but does not lead to differential signaling. J Leukoc Biol 83: 692–701.
  51. 51. Becker I, Salaiza N, Aguirre M, Delgado J, Carrillo-Carrasco N, et al. (2003) Leishmania lipophosphoglycan (LPG) activates NK cells through toll-like receptor-2. Mol Biochem Parasitol 130: 65–74.
  52. 52. Voss S, Ulmer AJ, Jung G, Wiesmuller KH, Brock R (2007) The activity of lipopeptide TLR2 agonists critically depends on the presence of solubilizers. Eur J Immunol 37: 3489–3498.
  53. 53. Lee HK, Lee J, Tobias PS (2002) Two lipoproteins extracted from Escherichia coli K-12 LCD25 lipopolysaccharide are the major components responsible for Toll-like receptor 2-mediated signaling. J Immunol 168: 4012–4017.
  54. 54. Haque R, Mondal D, Shu J, Roy S, Kabir M, et al. (2007) Correlation of interferon-gamma production by peripheral blood mononuclear cells with childhood malnutrition and susceptibility to amebiasis. Am J Trop Med Hyg 76: 340–344.
  55. 55. Diamond LS, Harlow DR, Cunnick CC (1978) A new medium for the axenic cultivation of Entamoeba histolytica. Trans R Soc Trop Med Hyg 72: 431–432.
  56. 56. Chadee K, Meerovitch E (1984) The pathogenesis of experimentally induced amebic liver abscess in the gerbil (Meriones unguiculatus). Am J Pathol 117: 71–80.
  57. 57. Leippe M, Ebel S, Schoenberger OL, Horstmann RD, Muller-Eberhard HJ (1991) Pore-forming peptide of pathogenic Entamoeba histolytica. Proc Natl Acad Sci U S A 88: 7659–7663.
  58. 58. Westphal O, Jann K, Himmelspach K (1983) Chemistry and immunochemistry of bacterial lipopolysaccharides as cell wall antigens and endotoxins. Prog Allergy 33: 9–39.
  59. 59. Macrae JI, Ferguson MA (2005) A robust and selective method for the quantification of glycosylphosphatidylinositols in biological samples. Glycobiology 15: 131–138.
  60. 60. Lutz MB, Kukutsch N, Ogilvie AL, Rossner S, Koch F, et al. (1999) An advanced culture method for generating large quantities of highly pure dendritic cells from mouse bone marrow. J Immunol Methods 223: 77–92.
  61. 61. Tsai CM, Frasch CE (1982) A sensitive silver stain for detecting lipopolysaccharides in polyacrylamide gels. Anal Biochem 119: 115–119.