Monoclonal antibodies to Leishmania mexicana promastigote antigens. II. Cellular localization of antigens in promastigotes and infected macrophages

The major surface protease (MSP or GP63) in the intracellular amastigote stage of Leishmania chagasi

The Leishmania spp. protozoa have an abundant surface metalloprotease called MSP (major surface protease), which in Leishmania chagasi is encoded by three distinct gene classes (MSPS, MSPL, MSPC). Although MSP has been characterized primarily in extracellular promastigotes, it also facilitates survival of intracellular amastigotes. Promastigotes express MSPS, MSPL, and two forms of MSPC RNAs, whereas amastigotes express only MSPL RNA and one MSPC transcript. We confirmed the presence of MSPC protein in both promastigotes and amastigotes by liquid chromatography-tandem mass spectrometry (LC-MS/MS). More than 10 MSP isoforms were visualized in both amastigotes and promastigotes using two-dimensional immunoblots, but amastigote MSPs migrated at a more acidic pI. Promastigote MSPs were N-glycosylated, whereas most amastigote MSPs were not. Immuno-electron microscopy showed that two-thirds of the promastigote MSP is distributed along the cell surface. In contrast, most amastigote MSP localized at the flagellar pocket, the major site of leishmania endocytosis/exocytosis. Biochemical analyses indicated that most amastigote MSP is soluble in the cytosol, vesicles or organelles, whereas most promastigote MSP is membrane-associated and GPI anchored. Activity gels and immunoblots confirmed the presence of a novel proteolytically active amastigote MSP of higher Mr than the promastigote MSPs. Furthermore, promastigote MSP is shed extracellularly whereas MSP is not shed from axenic amastigotes. We conclude that amastigotes and promastigotes both express multiple MSP isoforms, but these MSPs differ biochemically and localize differently in the two parasite stages. We hypothesize that MSP plays different roles in the extracellular versus intracellular forms of Leishmania spp.

Leishmania (Viannia) braziliensis: interaction of mannose-binding lectin with surface glycoconjugates and complement activation. An antibody-independent defence mechanism

The activation of complement on the surface of Leishmania promastigotes appears to be an important factor for parasite infectivity in the mammalian host, allowing their attachment and the invasion of macrophages via complement receptors. Mannose-binding lectin (MBL) is a well-known complement activator and an efficient opsonine. We have investigated here whether serum and purified MBL bind to and promote lysis of live promastigotes of L. braziliensis; and evaluated the deposition of MBL, C1q, C4 and C3 on the parasite surface after interaction with non-immune normal human serum (NHS). We observed that both serum MBL and the purified MBL-MASP complex bind to the surface of L. braziliensis and that this binding occurred via the carbohydrate recognition domains of MBL. The binding of MBL, however, did not affect the lytic effect of complement on the parasites. The deposition of C1q, C4, C3 and parasite lysis was observed after incubation with NHS. EDTA but not EGTA abolished C3 deposition on the parasite surface, indicating the involvement of the alternative pathway in this process. Our results indicate that MBL binds to L. braziliensis and that this is mediated by a specific carbohydrate on the surface of parasites and provides evidence for antibody-independent mechanisms that complement activation on the parasite surface.

Cutaneous leishmaniasis in red kangaroos: isolation and characterisation of the causative organisms

This is the first report of cutaneous leishmaniasis in kangaroos where infection was acquired within Australia. The diagnosis is based on the clinical criteria used for humans, the lesion histopathology, the detection and isolation of parasites from the lesions, and the analysis of the small subunit ribosomal RNA genes using the polymerase chain reaction. Despite a clear indication that the parasites belong to the genus Leishmania, no assignation to a known Leishmania species could be made using these or other less conserved genetic loci such as the non-transcribed spacer of the mini-exon repeat. As is the case in humans, some but not all animals harbouring lesions had antibodies to the isolated parasites or to several other Leishmania species. The isolated parasites displayed two well characterised Leishmania glycoconjugates, the lipophosphoglycan and proteophosphoglycan. They were infectious for mouse macrophages in vitro and established long-term infection at 33 degrees C but not at 37 degrees C. Our findings raise the possibility of transmission to humans, which may be unrecognised and suggest the possibility that imported species of Leishmania could become endemic in Australia.

Antigenuria in visceral leishmaniasis: detection and partial characterisation of a carbohydrate antigen

The detection of antigen in the urine is increasingly being used for diagnosis of parasitic infections. A urinary antigen has recently been demonstrated in visceral leishmaniasis (VL), using a latex agglutination test. The results of our study show that the detected antigen is: heat-stable, precipitates with acetone and ethanol but not TCA, is sensitive to periodate and acid hydrolysis but not to pronase E, lipase, or neuraminidase. The antigen is a low molecular weight glycoconjugate that can be extracted by phenol-water, partitions into the aqueous phase when extracted with Triton X-114 or chloroform/methanol, and can be labelled by biotin hydrazide. Since this urinary antigen cannot be characterised by conventional SDS-PAGE and Western blotting, we used an affinity transfer blotting system in which antigens were captured onto nitro-cellulose paper previously coated with a specific antibody. Using this system a low molecular weight antigen (LMWA) spanning an area of the nitro-cellulose membrane corresponding to molecular weight of 5-20 kDa was detected in the urine of VL patients (from Nepal, Sudan, Brazil, Yemen and Spain) and of experimentally infected animals. No LMWA was detected in the urine of patients with malaria, schistosomiasis, or other nonparasitic diseases including typhoid and brucellosis. Immunoprecipitation, using antibody-coated latex, followed by immunoblotting showed that the LMWA is the target antigen in the previously described latex agglutination test ('KATEX'). The antigen is detectable in both the promastigote and amastigote stages of the parasite. Monoclonal antibodies (mAbs) against Leishmania glycoconjugates strongly react with this molecule. These results suggest that the detected antigen is highly specific and diagnostic for VL.

Membrane surface of Mycobacterium microti-infected macrophages antigenically differs from that of uninfected macrophages

Identification of the antigenic changes in mycobacteria-infected macrophage may be important in understanding the mechanisms responsible for the intracellular survival of the bacteria. In the present study, Mycobacterium microti-infected macrophages were utilized to investigate the possibility of differentiating the infected cells from normal cells, based on the antigenic changes occurring in the membranes. Antisera were generated against bacterial extract, heat-killed bacteria and crude preparation of M. microti-infected homologous macrophage membrane. The reactivity of these antisera, towards in vitro infected macrophages, was compared by flow cytometry. Unlike anti-bacterial extract antiserum or anti-heat-killed bacterial antiserum, anti-infected macrophage membrane antiserum reacted with infected macrophage surface. This reactivity increased with the increase in post-infection time. However, it was not observed with uninfected macrophages, PMA- or lipopolysaccharide-activated macrophages and those harboring Mycobacterium tuberculosis H37Ra, heat-killed M. microti and Leishmania donovani. Interestingly, anti-infected macrophage membrane antiserum identified a 63-kDa antigen in M. microti-infected macrophage membranes which was not present in the membranes of normal macrophages, activated macrophages and of those infected with M. tuberculosis H37Ra, heat-killed M. microti and L. donovani. Thus, membranes of M. microti-infected macrophages differ antigenically from those of the normal macrophages and infected homologous macrophage membrane antiserum provides a useful tool in studying such changes.

Comparison of different staining procedures for the flow cytometric analysis of U-937 cells infected with different Leishmania-species

The human macrophage cell line U-937 infected with different Leishmania species, Leishmania mexicana amazonensis (Lma), Leishmania donovani (Ld) and Leishmania infantum (Li), was analyzed by flow cytometry (FCM). Leishmania spp. were labeled with different stains prior to the infection of the U-937 cells (BCECF-Am, PKH2-GL and SYTO 17) or after the infection (AO, FITC-conjugated monoclonal antibodies, PI). Infected cells were analyzed by flow cytometry, fluorescence microscopy and in parallel microscopically after Giemsa staining. The data obtained by these two methods were compared to decide which method is mostly appropriate for detection and estimation of the infection rate. Three fluorescent stains were suitable: BCECF-Am, SYTO 17 and FITC-conjugated MoAb with 0.02% digitonin. None of the vital stains gave evaluable results after 3 days of incubation.

The biogenesis and properties of the parasitophorous vacuoles that harbour Leishmania in murine macrophages

Leishmania are protozoan parasites that, as amastigotes, live in the macrophages of mammalian hosts within compartments called parasitophorous vacuoles. These organelles share features with late endosomes/lysosomes and are also involved in the trafficking of several major histocompatibility complex (MHC)-encoded molecules. Improved knowledge of the parasitophorous vacuoles may help clarify how these protozoa persist in their hosts.

Pre-embedding immunolabeling for electron microscopy: an evaluation of permeabilization methods and markers

For scarce antigens or antigens which are embedded in a dense macromolecular structure, on-section labeling, the first method of choice, is not always successful. Often, the antigen can be localized by immunofluorescence microscopy, usually by a pre-embedding labeling method. Most of these methods lead to loss of ultrastructural details and, hence, labeling at electron microscope resolution does not add essential information. The scope of this paper is to compare five permeabilization methods for pre-embedding labelling for electron microscopy. We aim for a method that is easy to use and suitable for routine investigations. For our ongoing work, special attention is given to labeling of the cell nucleus. Accessibility of cytoplasmic and nuclear antigens is monitored with a set of different marker antibodies. From this investigation, we suggest that prefixation with formaldehyde/glutaraldehyde is necessary to stabilize the ultrastructure before using a detergent (Triton X-100 or Brij 58) to permeabilize or remove the membranes. The experimental conditions for labeling should be checked first with fluorescence or fluorescence-gold markers by fluorescence microscopy. Then either ultrasmall gold particles (with or without fluorochrome) with silver enhancement or, if the ultrasmall gold particles are obstructed, peroxidase markers are advised. The most promising technique to localize scarce antigens with good contrast is the combination of a pre-embedding peroxidase/tyramide-FITC or -biotin labeling followed by an on-section colloidal gold detection.

Developmental changes in the expression of Leishmania chagasi gp63 and heat shock protein in a human macrophage cell line

The ability of the protozoan Leishmania chagasi to infect a vertebrate host depends on its ability to survive intracellularly in a mammalian macrophage. Novel patterns of gene expression are probably important for conversion from the extracellular promastigote to the obligate intracellular amastigote parasite form. We found that the human macrophage-like cell line U937 provided an in vitro model of phagocytosis of L. chagasi promastigotes and intracellular conversion to amastigotes, allowing examination of parasite protein and RNA expression. The Leishmania surface protease gp63 assumed three isoforms during stage conversion, and a 64-kDa form of gp63 not present in promastigotes became the most prominent form in amastigotes. gp63 RNAs derived from the three different classes of msp genes (mspS, mspL, and mspC) were also differentially expressed. Infectious promastigotes contained mRNAs from mspS and mspC genes, whereas converting parasites expressed only mspL and mspC mRNAs. Sequence analysis of clones from an amastigote cDNA library confirmed the presence of gp63 mRNAs only from mspL and mspC class genes in tissue-derived amastigotes. Finally, 24 h after phagocytosis, there was a transient increase in the level of hsp70 and hsp90 proteins that subsequently decreased to baseline; this increase was not due to heat shock alone. We conclude that a unique pattern of selected L. chagasi proteins and RNAs is induced following phagocytosis by macrophages.

The role of macrophage receptors in adhesion and uptake of Leishmania mexicana amastigotes

Amastigotes of the protozoan parasite Leishmania proliferate in phagolysosomes of mammalian macrophages. Propagation of the infection is considered to occur by host-cell rupture and uptake of released parasites by uninfected macrophages. In this study, the kinetics of binding of L mexicana mexicana amastigotes to COS cells and to COS cells transfected with three different macrophage receptors (FcRII-B2, receptor for the Fc-domain of immunoglobulins; CR3, complement type 3 receptor and the mannose receptor) is compared to the rate of adhesion to peritoneal macrophages. Amastigotes isolated from macrophages cultivated in vitro bind with slow, sigmoid kinetics to COS cells expressing either of the three receptors, or to peritoneal macrophages. In contrast, amastigotes isolated from mouse lesions bind with rapid, hyperbolic kinetics to COS cells expressing the Fc receptor or to peritoneal macrophages but with slow, sigmoid kinetics to COS cells expressing the CR3 or the mannose receptor. As shown by immunofluorescence experiments, lesion-derived amastigotes contain host-derived immunoglobulins (Ig) but no complement component 3 at their surface. It is concluded that amastigotes contain no intrinsic ligand at their surface, which enables high-affinity interactions with macrophages. Opsonization by specific Ig may be of relevance in vivo because firstly, in cryosections of mouse lesions extracellular amastigotes containing surface Ig can be detected and, secondly, B cell-deficient mice reconstituted with parasite-specific Ig show a modest increase in the rate of lesion development. In addition, it is shown that amastigotes are internalized by COS cells and grow in large parasitophorous vacuoles similar to those observed in macrophages.

Surface antigens of Leishmania mexicana amastigotes: characterization of glycoinositol phospholipids and a macrophage-derived glycosphingolipid

Amastigotes of the protozoan parasite Leishmania proliferate in phagolysosomes of macrophages. They abundantly express glycoinositol phospholipids (GIPLs), which are considered necessary for parasite survival by providing a shield at the surface against lysosomal hydrolases and by serving as receptors for the interaction with host cells. The structures of four GIPLs of L. mexicana amastigotes were characterized by a combination of gas-liquid chromatography-mass spectrometry, methylation linkage analysis and enzymatic treatments. They contain the glycan structures Man alpha 1–3Man alpha 1–4GlcN (iM2), Man alpha 1–6(Man alpha 1–3)Man alpha 1–4GlcN (iM3), Man alpha 1–2Man alpha 1–6(Man alpha 1–3)-Man alpha 1–4GlcN (iM4) and (NH2-CH2CH2-PO4)Man alpha 1–6(Man alpha 1–3)Man alpha 1–4GlcN (EPiM3), which are linked to alkylacyl-phosphatidylinositol. The predominant amastigote GIPL, EPiM3 (approximately 2 × 10(7) molecules/cell), is located at the parasite cell surface, in the flagellar pocket and in lysosomal membranes, but not on host cell structures as shown by immunofluorescence and immunoelectron microscopy. In addition, amastigotes in infected Balb/c mice contain a glycolipid with similar distribution as EPiM3, which has the same characteristics as the Forssman antigen of mammalian cells. In contrast to EPiM3, there is strong evidence that this glycosphingolipid is not synthesized by amastigotes but by macrophages in the lesion. This suggests a mechanism of lipid transfer from the macrophage to the parasite.

Characterization of phosphoglycan-containing secretory products of Leishmania

This article presents an overview on phosphoglycan-containing components secreted by the insect and mammalian stages of several species of Leishmania, the causative agents of leishmaniasis in the Old and New World. Firstly, promastigotes of all three species considered, L. mexicana, L. donovani and L. major, shed lipophosphoglycan (LPG) into the culture medium possibly by release of micelles from the cell surface. Like the cell-associated LPG, culture supernatant LPG is amphiphilic and composed of a lysoalkylphosphatidylinositol-phosphosaccharide core connected to species-specific phosphosaccharide repeats and oligosaccharide caps. Secondly, all three species release hydrophilic phosphoglycan. Thirdly, all three species appear to secrete proteins covalently modified by phosphosaccharide repeats and oligosaccharide caps. In the case of promastigotes of L. mexicana, these components are organized as two filamentous polymers released from the flagellar pocket: the secreted acid phosphatase (sAP) composed of a 100 kDa phosphoglycoprotein and a protein-containing high-molecular-weight-phosphoglycan (proteo-HMWPG) and fibrous networks likewise composed of phosphoglycan possibly linked to protein. Structural analyses and gene cloning suggest that the parasites can covalently modify protein regions rich in serine and threonine residues by the attachment of phosphosaccharide repeats capped by oligosaccharides. We propose that the networks formed in vitro correspond to fibrous material previously demonstrated in the digestive tract of infected sandflies. In the case of L. donovani, the sAP is also modified by phosphoglycans but contains neither proteo-HMWPG nor does it aggregate to filaments. Finally, L. mexicana amastigotes release proteo-HMWPG via the flagellar pocket into the parasitophorous vacuole of infected macrophages.(ABSTRACT TRUNCATED AT 250 WORDS)

Complete developmental cycle of Leishmania mexicana in axenic culture

A complete developmental sequence of Leishmania mexicana has been produced in axenic culture for the first time. This was achieved by manipulation of media, pH and temperature conditions over a period of 16 days. All experiments were initiated with lesion amastigotes that were transformed to multiplicative promastigotes by culture in HOMEM, 10% foetal calf serum, pH 7.5, at 25 degrees C. Metacyclogenesis was induced by subpassage in Schneider's Drosophila medium, 20% foetal calf serum, pH 5.5, and the resulting forms transformed to axenically growing amastigotes by subpassage in the same medium and raising the temperature to 32 degrees C. Parasites from each day were characterized with respect to their general morphology using light microscopy of Giemsa-stained smears, and biochemically by analysis of total protein content, proteinases, nucleases and secretory acid phosphatase. The results demonstrated that the three main stages identified--amastigotes, multiplicative promastigotes and metacyclic promastigotes--each exhibited the expected suite of biochemical properties. Further, the changes in morphology observed as the developmental sequence proceeded from stage to stage were accompanied by appropriate changes in biochemical properties. These results provide both useful biochemical markers and a culture system in which to examine the regulation of differentiation and transformation during the Leishmania life-cycle.

Monoclonal antibodies directed against Leishmania secreted acid phosphatase and lipophosphoglycan. Partial characterization of private and public epitopes

Leishmania promastigotes, the stage of the parasite characteristic for the sandfly vector, express an abundant glycoconjugate, called lipophosphoglycan, at their surface. Lipophosphoglycan consists of lysoalkyl-sn-glycerophosphoinositol linked to a phosphosaccharide core conserved in all species, which is connected to PO4-6Gal beta 1,4Man alpha 1 repeats with species-specific substitutions at the Gal residue; the repeats are capped by conserved and species-specific oligosaccharides. Most Leishmania species also secrete an acid phosphatase, which, in Leishmania mexicana, is a filamentous complex composed of a phosphorylated glycoprotein and non-covalently associated proteo-(high-molecular-mass)phosphoglycan. The secreted acid phosphatase complex was used as an antigen to derive a panel of monoclonal antibodies (mAbs). A total of 25 mAbs (17 novel and 8 previously described) were tested by different techniques for their specificity against lipophosphoglycan and secreted acid phosphatase from several Leishmania species. This comparison and the modification of the antigens by chemical or enzymic treatments allowed a classification of the mAbs into several groups. First, from 25 mAbs examined, 22 recognize lipophosphoglycan and the enzyme complex of L. mexicana; only three are specific for secreted acid phosphatase. Two of the latter group are also directed against carbohydrate structures, whereas the third mAb recognizes the 100-kDa polypeptide of the complex. The secreted acid-phosphatase-specific class detects antigen in the flagellar pocket of promastigotes while all anti-lipophosphoglycan mAbs bind to the cell surface. Second, all 15 anti-lipophosphoglycan mAbs investigated in detail appear to be directed against the phosphosaccharide repeats or the cap structure rather than the phosphosaccharide core. Two mAbs recognize terminal cap-structures containing Man alpha 1,2Man residues. Four antibodies are specific for L. mexicana and are probably directed against PO4-6[Glc beta 1,3]Gal beta 1,4Man alpha 1 repeats while six mAbs react with the unmodified repeats. Two antibodies specific for Leishmania major recognize Gal beta 1,3-substituted repeats unique for lipophosphoglycan from this species. Analysis by immunoblotting indicates that the high-molecular-mass proteo-phosphoglycan of L. mexicana secreted acid phosphatase carries epitopes for all anti-lipophosphoglycan mAbs suggesting the presence of capped phosphosaccharide repeats while the enzymically active glycoprotein subunit is modified by caps but probably not by repeats. In the case of Leishmania donovani secreted acid phosphatase, the enzymically active polypeptide may be directly modified by repeats. The mAbs are used to characterize changes in lipophosphoglycan structure, which occur in culture during the transition of promastigotes from the logarithmic to the stationary growth phase.(ABSTRACT TRUNCATED AT 400 WORDS)

The flagellar pocket of trypanosomatids

The surface of the trypanosomatid forms the interface between the parasite and its host, and has evolved to repel a variety of host anti-microbial defences. The flagellar pocket constitutes a highly differentiated region of the trypanosomatid surface that facilitates internalization of host macromolecules, while restricting host access to the exposed, endocytic receptors of the parasite. In this review, Paul Webster and David Russell discuss the ability of this organelle to accumulate efficiently nutrients obtained from the host as a major factor in the success of this group of parasites.

The Golgi apparatus of Tetrahymena thermophila

Electron microscopic investigations reveal that the Golgi apparatus of Tetrahymena thermophila consists of numerous tiny dictyosomes, each consisting of one or two cisternae. The dictyosomes are localized predominantly in the cell cortex closely associated with the mitochondria, arranged in meridians alternating with the ciliary meridians. We estimated about 300-400 of these dictyosomes in the periphery of a cell, a value corresponding to the number of somatic cilia per cell. Cytochemical assays of thiamine pyrophosphatase and acid phosphatase, both marker enzymes of trans Golgi cisternae, resulted in deposits of lead or cerium phosphate in the outermost cisternae of the dictyosomes. In addition, cisternae located at the bases of the basal body/parasomal sac arrangements are stained. This indicates that these cisternae may belong to the Golgi apparatus of the cell.