Leishmania amazonensis: acidic organelles in amastigotes

Electron microscopy and cytochemistry analysis of the endocytic pathway of pathogenic protozoa

Endocytosis is essential for eukaryotic cell survival and has been well characterized in mammal and yeast cells. Among protozoa it is also important for evading from host immune defenses and to support intense proliferation characteristic of some life cycle stages. Here we focused on the contribution of morphological and cytochemical studies to the understanding of endocytosis in Trichomonas, Giardia, Entamoeba, Plasmodium, and trypanosomatids, mainly Trypanosoma cruzi, and also Trypanosoma brucei and Leishmania.

Ultrastructural localization of Trypanosoma cruzi lysosomes by aryl sulphatase cytochemistry

Lysosomes of trypanosomatid protozoa are poorly known. In this work we have cytochemically detected the lysosomal enzyme aryl sulphatase in the trypanosomatids Trypanosoma cruzi and Crithidia fasciculata, by using p-nitrocatecholsulphate as substrate. Positive reaction was located exclusively inside membrane-bound cytoplasmic vesicles distributed throughout the cell body. Electron-dense reaction was either dispersed homogeneously through the vesicular matrix or located at the vesicle periphery, apposed to the membrane, with fine granular deposits occasionally found at the vesicular matrix. Trypomastigote and epimastigote forms of T. cruzi lacked electron-dense deposits at the plasma membrane, thus indicating that aryl sulphatase was not secreted to the environment. Furthermore, no positive reaction was detected in epimastigote reservosomes, which are organelles considered as pre-lysosomal compartments. Thus, our data show that reservosomes and lysosomes are organelles that can be distinguished by the cytochemical localization of aryl sulphatase in T. cruzi epimastigotes and trypomastigotes. Positive reaction in cytoplasmic vesicles of C. fasciculata choanomastigotes confirmed the specificity of the reaction for lysosomes in other trypanosomatid species.

Leishmanicidal activity of amino acid and peptide esters

Amino acid and dipeptide esters kill intracellular and isolated L. amazonensis amastigotes. Several o f the compounds also restrict the growth o f mouse lesions after intralesional administration. However, the esters are known to be toxic in vitro for monocytes and certain lymphoid cells. Michel Rabinovitch surveys the mechanisms o f the leishmanicidal activity, describes some structure--activity relationships, and discusses strategies for the design of compounds more selective for the parasite.

Growth phase and medium ph modulate the expression of proteinase activities and the development of megasomes in axenically cultivated Leishmania (Leishmania) amazonensis amastigote-like organisms

Leishmania (Leishmania) amazonensis LV79 (MPRO/BR/72/M1841) has been adapted to grow at 33 C as amastigote-like (AL) organisms in modified UM-54 medium initially adjusted to a pH of 4.8-5.0. Axenic cultures could be routinely restarted from parasites recovered from footpad lesions obtained by inoculation of BALB/c mice with preadapted culture stages. Morphological features, proteinase activities, and infectivity of AL organisms were examined during the in vitro growth cycle, and differences were found between log- and stationary-phase parasites. Stationary-phase AL organisms were morphologically similar to lesion amastigotes, did not react with a paraflagellar rod-specific monoclonal antibody in western blots, and contained proteinase activities resolving identically to the enzymes of lesion amastigotes in gelatin gels. Whereas typical megasomes could be identified in about a third of the stationary-phase AL population, the organelles were rarely seen in log-phase organisms. Azocaseinolytic activity progressively increased during the exponential growth phase and reached its highest values (approximately 65-70% of those determined in lesion amastigotes) at the stationary phase; the association of total proteinase activity with increased expression of cysteine proteinases was indicated by the strong inhibition of azocasein hydrolysis by E-64, the intensified banding of the 28-, 31-, and 35-kDa proteinases in gelatin gels, and the higher susceptibility of stationary-phase AL organisms to L-leucine methyl ester. Although overall axenic amastigotes were less infective to BALB/c mice than were lesion-derived parasites, stationary-phase AL organisms were more infective than were log-phase parasites. Medium pH increased during the exponential growth phase, but dropped in the stationary phase, when the observed morphological, biochemical, and biological changes became apparent.

Intracellular Leishmania amazonensis amastigotes internalize and degrade MHC class II molecules of their host cells

In their amastigote stage, Leishmania live in mammalian macrophages within parasitophorous vacuoles (PV), organelles of phagolysosomal origin that, in macrophages activated with IFN-gamma, contain major histocompatibility complex (MHC) class II molecules apparently devoid of invariant chains. We have now studied the fate of PV-associated class II molecules in mouse bone marrow-derived macrophages infected with L. amazonensis amastigotes using immunocytochemical and biochemical approaches. We have found that at least a part of these class II molecules was internalized by amastigotes and reached structures very often located in their posterior poles. This process was much more obvious if infected macrophages were incubated with protease inhibitors like antipain, chymostatin, Z-Phe-AlaCHN2 and Z-Phe-PheCHN2, or if amastigotes were pre-treated with the irreversible cysteine protease inhibitor Z-Phe-AlaCHN2 before infection, clearly indicating that amastigotes also degraded the internalized class II molecules. Study of infected macrophage cryosections by immuno-electron microscopy allowed the identification of the class II-positive structures in amastigotes as the lysosome-like organelles known as megasomes. Other PV membrane components like the prelysosomal/lysosomal glycoproteins Igp110, Igp120 and macrosialin could not be detected in megasomes of amastigotes even after treatment of macrophages with protease inhibitors, suggesting the involvement of some specific mechanism(s) for the internalization of class II molecules. Interestingly, after treatment of infected macrophages with various protease inhibitors (antipain, leupeptin, E-64, Z-Phe-AlaCHN2, Z-Phe-PheCHN2), PV membrane as well as megasomes of amastigotes become positive for invariant chains. A quantitative analysis of amastigote-associated class II molecules based on enzyme immunoassays showed that: (a) amastigotes extracted from macrophages treated with both IFN-gamma and antipain or Z-Phe-AlaCHN2 contained a much greater amount of class II than amastigotes extracted from macrophages treated with IFN-gamma alone; (b) class II molecules associated with the former were mainly intracellular and, at least some of them, were complexed with invariant chains or fragments of invariant chains; (c) amastigotes pre-incubated with Z-Phe-AlaCHN2 before infection accumulated a greater amount of intracellular class II than amastigotes pre-incubated without inhibitor, clearly indicating that the blockade of parasite cysteine proteases was sufficient to enhance the pool of these molecules within megasomes. On the whole, these data are consistent with the idea that class II molecules reaching PV are newly synthesized and still complexed with intact invariant chains or with partially degraded invariant chains.(ABSTRACT TRUNCATED AT 400 WORDS)

Alterations induced by the antifungal compounds ketoconazole and terbinafine in Leishmania

The antiproliferative effects and ultrastructural alterations induced in vitro by two antifungal compounds, the azole ketoconazole and the allylamine terbinafine on Leishmania amazonensis are reported. Promastigotes treatment with ketoconazole and terbinafine induced growth arrest and cell lysis in 72 hours. Combination of the two agents produced additive effects on promastigote axenic growth and synergistic effects on intracellular amastigote proliferation. The amastigotes, either axenically grown or infecting murine macrophages, were about 100-fold more sensitive to the drugs. These compounds induced the appearance of large multivesicular bodies, especially after ketoconazole treatment, increased amount of lipid inclusions as well as numerous, polymorphic volutin granules, particularly in terbinafine-treated cells. Multivesicular bodies were observed in close apposition with organelles such as mitochondria, which also showed alterations in the distribution and appearance of cristae, and the formation of paracrystalline arrays within the matrix. Some cells presented large portions of cytoplasm wrapped by endoplasmic reticulum and many parasites also presented myelin-like endoplasmic reticulum profiles. Such alterations together with the strong acid phosphatase activity observed in the multivesicular bodies and volutin granules may indicate the existence of an unusual autophagic process in cells treated with ergosterol biosynthesis inhibitors.

Distribution of parasite cysteine proteinases in lesions of mice infected with Leishmania mexicana amastigotes

It is well established that Leishmania mexicana amastigotes contain large amounts of cysteine proteinases in their extended lysosomes. In this study it is shown that the cell-free supernatant of homogenized lesion tissue from infected mice contains large amounts of acid proteinases. The majority of this enzymatic activity also corresponds to cysteine proteinases from L. mexicana amastigotes. Immunoelectron microscopy of mouse lesion sections suggests, that frequently amastigotes lyse and release lysosomal cysteine proteinases into the parasitophorous vacuole of infected macrophages. The cysteine proteinases are also found extracellularly in the tissue presumably as a result of macrophage rupture and appear to persist in the lesion tissue, where they may damage host cells and the extracellular matrix.

Distribution of MHC class I and of MHC class II molecules in macrophages infected with Leishmania amazonensis

Macrophages, being apparently the only cells that in vivo allow the growth of the intracellular pathogen Leishmania, are likely candidates to present antigens to Leishmania-specific CD4+ and CD8+ T lymphocytes, known to be involved in the resolution or in the development of lesions induced by these parasites, and recognizing processed antigens bound to MHC class I and MHC class II molecules, respectively. In the present study, we analysed by confocal microscopy and by immunoelectron microscopy the subcellular distribution of both MHC class I and class II molecules in mouse (Balb/c and C57BL/6 strains) bone marrow-derived macrophages infected for 12 to 48 hours with Leishmania amazonensis amastigotes and activated with gamma interferon to determine the intracellular sites where Leishmania antigens and MHC molecules meet and can possibly interact. Double labelings with anti-MHC molecule antibodies and with either propidium iodide or an anti-amastigote antibody allowed localization of MHC molecules with regard to the endocytic compartments housing Leishmania amastigotes, organelles known as the parasitophorous vacuoles (PV) and which most likely contain the highest concentration of parasite antigens in the host cell. Both uninfected and infected macrophages from Balb/c mice expressed the MHC class I molecules H-2Kd and H-2Dd on their cell surface but no significant amount of these molecules could be detected in the PV, which indicates that, if infected macrophages play a role in the induction of Leishmania-specific CD8+ T lymphocytes, PV are probably not loading compartments for MHC class I molecules. In contrast, MHC class II molecules were found to be associated with the PV membranes as shown previously with microscopic techniques at lower resolution (Antoine et al. Infect. Immun. 59, 764–775, 1991). In addition, we show here that, 48 hours after infection of Balb/c macrophages, in about 90% of PV containing MHC class II molecules, the latter were mainly or solely localized at the attachment zone of amastigotes to PV membranes. This peculiar distribution, especially well demonstrated using confocal microscopy, was confirmed by subcellular fluorescence cytometry of infected macrophages stained for the MHC class II molecules. The following data agree with the idea that PV-associated MHC class II molecules establish specific interactions with plasma membrane components of amastigotes. First, the polarized localization of class II appeared specific to these molecules, since the distribution of the lysosomal glycoproteins Igp110 and Igp120, of the macrosialin (a macrophage-specific marker of endocytic compartments) and of the GTP-binding protein rab7p, shown here as being PV membrane components, was homogeneous.(ABSTRACT TRUNCATED AT 400 WORDS)

Leishmania amazonensis: specific labeling of amastigote cysteine proteinases by radioiodinated N-benzyloxycarbonyl-tyrosyl-alanyl diazomethane

Living Leishmania amazonensis amastigotes were incubated with radioiodinated N-benzyloxycarbonyl-L-tyrosyl-L-alanyl diazomethane (Z-Tyr-AlaCHN2), an irreversible inhibitor of mammalian cathepsins B and L. Parasite lysates were subjected to electrophoresis in gelatin-containing sodium dodecyl sulfate-acrylamide gels to detect regions of proteolytic activity, and the distribution of the inhibitor was ascertained by autoradiography. Of the three main bands of proteolysis associated with cysteine proteinases, two, with apparent molecular weights of 28 and 31 kDa, were shown to be labeled. The third enzyme activity, detected at the 35-kDa region in substrate gels, was only faintly labeled. The distribution of labeled bands was similar when lysates of untreated parasites were electrophoresed and the gels incubated with the radioiodinated inhibitor. Under reducing conditions, the inhibitor bound to polypeptides of 29, 31, 32, and 34 kDa, of which the first and the last were the most intensely labeled. Polypeptides with the same apparent molecular weights were labeled when amastigote lysates were incubated with the 125I inhibitor. Uptake of radioactivity by the parasites was time and concentration-dependent and more than 80% of the total counts could be precipitated with trichloroacetic acid. Radioactivity associated with the amastigotes was quite stable after they were pulsed with labeled inhibitor and chased for up to 24 hr in inhibitor-free medium. Both total uptake and labeling of cysteine proteinases were markedly reduced in parasites preincubated with Z-Phe-AlaCHN2 prior to exposure to Z-Tyr(125I)-AlaCHN2. However, more radioiodinated inhibitor was taken up by parasites preincubated with cold inhibitor and chased in inhibitor-free medium, suggesting de novo synthesis or processing of inactive enzyme precursors.

Purification and characterization of a membrane-bound acid phosphatase of Leishmania mexicana

As defined by the reaction with monoclonal antibodies, Leishmania mexicana promastigotes contain two acid phosphatases which together comprise about 90% of the cellular activity. A first enzyme recognized by monoclonal antibody AP4 is largely membrane-bound. The protein has an apparent molecular weight of 70,000-72,000, carries about seven N-linked glycan chains and is present in approximately 16,000 copies per cell. The protein is also expressed in the amastigote stage. A second enzyme reactive with monoclonal antibody AP3, that also recognizes lipophosphoglycan and a secreted acid phosphatase, is mainly found in the soluble fraction of promastigote lysates. It is suggested that this enzyme is the precursor of the secreted protein. The N-terminal sequences of the phosphatase recognized by AP4 and the secreted enzyme are similar but not identical. AP4 does not cross-react with phosphatase activity of Leishmania major or Leishmania donovani promastigotes, while AP3 recognizes part of the cellular and all of the secreted phosphatase activity of L. donovani promastigotes but not that of L. major which does not release an acid phosphatase into the culture medium.

The comparative fine structure and surface glycoconjugate expression of three life stages of Leishmania major

The cellular ultrastructure and surface glycoconjugate expression of three life stages of Leishmania major were compared. Noninfective logarithmic phase promastigotes (LP) are immature cells bearing a thin cell coat, short flagellum, small and empty flagellar pocket, and a loose cytoplasm filled with profiles of ER and large Golgi complex. LP also contain subpopulations of maturing cells containing less ER and Golgi and synthesizing cytoplasmic granules of different size, number, and electron-density. Infective or metacyclic promastigotes (MP) are fully differentiated nondividing forms with a thickened, prominent cell coat, long flagellum, distended flagellar pocket filled with secretory material, and few cytoplasmic organelles other than abundant electron-dense granules. Tissue amastigotes also contain electron-dense cytoplasmic granules, their flagellar pockets are also enlarged and contain secretory material, but they lack a discernable cell coat. Immunogold labeling of GP63 on the cell surface was extensive only on amastigotes. Promastigote GP63 appeared to be masked by the presence of a densely packed lipophosphoglycan (LPG) coat which was extensively labeled on the entire surface of MP and LP. An elongated, developmentally modified form of LPG was abundantly labeled only on MP. LPG was poorly labeled on amastigotes, arguing that the promastigote cell coat is a stage-specific structure which is lost during intracellular transformation.

Localization and activity of various lysosomal proteases in Leishmania amazonensis-infected macrophages

In mammalian hosts, Leishmania amastigotes are obligatory intracellular parasites of macrophages and multiply within parasitophorous vacuoles of phagolysosomal origin. To understand how they escape the harmful strategies developed by macrophages to kill ingested microorganisms, it is important to obtain information on the functional state of parasitophorous vacuole. For this purpose, we studied the intracellular distribution and activity of host lysosomal proteases in rat bone marrow-derived macrophages infected with Leishmania amazonensis amastigotes. Localization of cathepsins B, H, L, and D was investigated by using specific immunoglobulins. In uninfected macrophages, these enzymes were located in perinuclear granules (most of them were probably secondary lysosomes) which, after infection, disappeared progressively. In infected macrophages, cathepsins were detected mainly in the parasitophorous vacuoles, suggesting that the missing secondary lysosomes had fused with these organelles. Biochemical assays of various proteases (cathepsins B, H, and D and dipeptidyl peptidases I and II) showed that infection was accompanied by a progressive increase of all activities tested, except that of dipeptidyl peptidase II, which remained constant. No more than 1 to 10% of these activities could be attributed to amastigotes. These data indicate that (i) Leishmania infection is followed by an increased synthesis and/or a reduced catabolism of host lysosomal proteases, and (ii) amastigotes grow in a compartment rich in apparently fully active proteases. Unexpectedly, it was found that infected and uninfected macrophages degraded endocytosed proteins similarly. The lack of correlation in infected macrophages between increase of protease activities and catabolism of exogenous proteins could be linked to the huge increase in volume of the lysosomal compartment.

Parasitophorous vacuoles of Leishmania amazonensis-infected macrophages maintain an acidic pH

Leishmania amastigotes are intracellular protozoan parasites of mononuclear phagocytes which reside within parasitophorous vacuoles of phagolysosomal origin. The pH of these compartments was studied with the aim of elucidating strategies used by these microorganisms to evade the microbicidal mechanisms of their host cells. For this purpose, rat bone marrow-derived macrophages were infected with L. amazonensis amastigotes. Intracellular acidic compartments were localized by using the weak base 3-(2,4-dinitroanilino)-3'-amino-N-methyldipropylamine as a probe. This indicator, which can be detected by light microscopy by using immunocytochemical methods, mainly accumulated in perinuclear lysosomes of uninfected cells, whereas in infected cells, it was essentially localized in parasitophorous vacuoles, which thus appeared acidified. Phagolysosomal pH was estimated quantitatively in living cells loaded with the pH-sensitive endocytic tracer fluoresceinated dextran. After a 15- to 20-h exposure, the tracer was mainly detected in perinuclear lysosomes and parasitophorous vacuoles of uninfected and infected macrophages, respectively. Fluorescence intensities were determined from digitized video images of single cells after processing and automatic subtraction of background. We found statistically different mean pH values of 5.17 to 5.48 for lysosomes and 4.74 to 5.26 for parasitophorous vacuoles. As for lysosomes of monensin-treated cells, the pH gradient of parasitophorous vacuoles collapsed after monensin was added. This very likely indicates that these vacuoles maintain an acidic internal pH by an active process. These results show that L. amazonensis amastigotes are acidophilic and opportunistic organisms and suggest that these intracellular parasites have evolved means for survival under these harsh conditions and have acquired plasma membrane components compatible with the environment.

Megasomes as the targets of leucine methyl ester in Leishmania amazonensis amastigotes

Certain L-amino acid esters, such as L-leucine methyl ester (Leu-OMe), can kill intracellular and isolated Leishmania amazonensis amastigotes. Killing appears to involve ester trapping and hydrolysis within an acidified parasite compartment (M. Rabinovitch and S. C. Alfieri, 1987, Brazilian Journal of Medical and Biological Research 20, 665-74). We show here by acid phosphatase light microscopic cytochemistry and by ultrastructural morphometry that megasomes, lysosome-like amastigote organelles, are the putative parasite targets of Leu-OMe. This conclusion is supported by the following observations. (a) Control amastigotes displayed a string of electron-dense, acid phosphatase-positive megasomes mostly located in the cellular poles opposite the flagellar pockets. Incubation of the amastigotes with Leu-OMe resulted in concentration-dependent swelling and fusion of the organelles as well as decreased electron density of the internal contents. These changes, which preceded parasite disruption, were followed by the progressive loss of parasite viability and the release of acid phosphatase activity into the medium. (b) Incubation of the amastigotes with L-isoleucine methyl ester, a non-leishmanicidal compound, induced only moderate fusion of the megasomes. (c) Pre-incubation of the parasites with the proteinase inhibitors antipain and chymostatin, previously shown to confer protection from Leu-OMe toxicity, nearly completely prevented the morphological changes of megasomes. (d) Exposure of amastigotes to tryptophanamide (Trp-NH2), the leishmanicidal activity of which is not reduced by antipain and chymostatin, did not result in swelling and fusion of the megasomes. This last finding suggests that different mechanisms underlie the destruction of amastigotes by Trp-NH2 and Leu-OMe.(ABSTRACT TRUNCATED AT 250 WORDS)

Leishmania amazonensis: involvement of cysteine proteinases in the killing of isolated amastigotes by L-leucine methyl ester

L-leucine-methyl ester (Leu-OMe) kills Leishmania mexicana amazonensis amastigotes by a mechanism which requires proteolytic cleavage of the ester. N-Benzyloxycarbonyl-phenylalanyl-alanyl diazomethane (Z-Phe-AlaCHN2), a specific and irreversible inhibitor of cysteine proteinases, was used to characterize the enzymes involved in parasite destruction. It was shown that (1) amastigotes preincubated with micromolar concentrations of Z-Phe-AlaCHN2 survived challenge with Leu-OMe concentrations lethal to control parasites; (2) the proteolytic activity of 25- to 33-kDa cysteine proteinases in parasite lysates subjected to electrophoresis in gelatin-containing acrylamide gels was selectively inhibited in parasites pretreated with Z-Phe-AlaCHN2 and chased in inhibitor-free medium; and (3) cysteine proteinase activity was also inhibited in gels incubated with amino acid and dipeptide esters, possibly because the compounds were acting either as substrates (e.g., Leu-Leu-OMe) or as inhibitors (e.g., Ile-OMe) of the enzyme. The results support the involvement of low molecular weight cysteine proteinases in the destruction of amastigotes by Leu-OMe. Characterization of the structure and substrate specificity of the enzymes may permit the rational development of more selectively leishmanicidal amino acid derivatives.