Studies of the Numbers and Morphology of the Intracellular Form of Leishmania donovani Grown in Cell Culture*

SYNOPSIS. Macrophages were infected in vivo with the intracellular form of Leishmania donovani (LDs), harvested from the previously saline-stimulated peritoneal cavities of hamsters and explanted into Leighton tubes containing removable coverslips. Serum from either rabbit, chicken, human, calf, hamster or cotton rat blood was used as the 40% component of a Hanks' BSS₆₀ serum₄₀ medium used to maintain these Leighton tube cultures at 37 C. After varying lengths of time coverslips were removed from tubes, stained with Giemsa, and the parasites per infected macrophage, total number of hamster cells and total number of parasites on each coverslip were counted. Maerophages constituted more than 90% of the explanted cells on the coverslips. When cotton rat serum was used as a component of the medium, fibroblastic overgrowth of the coverslips followed. Some similarities and differences in the numbers of macrophages, fibroblasts and parasites were noted with regard to the serum used as part of the medium. Except for cotton rat serum, the serum component of the medium used apparently did not influence, to any great degree, the morphology of either the macrophages or parasites therein. Thus, vacuolarization and granularization of macrophages did not appear to be very distinctly correlated with the time of sampling or the type of serum in the medium used for maintenance nor could any morphologic variations of the LDs be ascribed to these factors. When cotton rat serum, but not any of the other sera, was the serum component of the medium, leptomonads were noted in the overlay fluid of the cultures after 6 days. Under these conditions of cell culture, fibroblasts could not be infected with LDs although macrophages on the same coverslip were heavily parasitized.     

Leishmania mexicana: distribution of intramembranous particles and filipin sterol complexes in amastigotes and promastigotes

The density and distribution of intramembranous particles was analyzed in freeze fracture replicas of the plasma membrane of amastigotes, and infective as well as noninfective promastigotes of Leishmania mexicana amazonensis. The density of intramembranous particles on both protoplasmic and extracellular faces was higher in infective than in noninfective promastigotes and it was lower in amastigotes than in promastigotes. Amastigotes purified immediately after tissue homogenization were surrounded by a membrane which corresponded to the membrane which lined the endocytic vacuoles where the parasites were located within the tissue macrophages. Aggregation of the particles was seen in the flagellar membrane at the point of emergence of the flagellum from the flagellar pocket. Differences in the organization of the particles were seen in the membrane which lined the flagellar pocket of amastigotes and promastigotes. The polyene antibiotic, filipin, was used as a probe for the detection of sterols in the plasma membrane of L. m. amazonensis. The effect of filipin in the parasite's structure was analyzed by scanning electron microscopy and by transmission electron microscopy of thin sections and freeze fracture replicas. Filipin sterol complexes were distributed throughout the membrane which lined the cell body, the flagellar pocket, and the flagellum. No filipin sterol complexes were seen in the cell body-flagellar adhesion zone. The density of filipin sterol complexes was lower in the membrane lining the flagellum than in that lining the cell body of promastigotes.     

Internalization of surface anionic sites and phagosome-lysosome fusion during interaction of Toxoplasma gondii with macrophages

The participation of cell surface anionic sites on the interaction between tachyzoites of Toxoplasma gondii and macrophages and the process of phagosome-lysosome fusion were analyzed using cationized ferritin as a marker of cell surface anionic sites and albumin-colloidal gold as a marker for secondary lysosomes. Incubation of either the macrophages or the parasites with cationized ferritin before the interaction increased the ingestion of parasites by macrophages. Anionic sites of the macrophage's surface, labeled with cationized ferritin before the interaction, were internalized together with untreated parasites. However, after interaction with glutaraldehyde-fixed or specific antibody-coated parasites, the cationized ferritin particles were observed in endocytic vacuoles which did not contain parasites. Macrophages previously labeled with albumin-gold at 37 degrees C, were incubated in the presence of cationized ferritin at 4 degrees C and then incubated with untreated or specific antibody-coated parasites. After interaction with opsonized parasites, the colloidal gold particles were observed in the parasitophorous vacuoles while the cationized ferritin particles were observed in cytoplasmic vesicles. However, when the interaction was carried out with untreated parasites, the parasitophorous vacuoles exhibited ferritin particles while the colloidal gold particles were observed in cytoplasmic vesicles. These observations, in association with studies previously reported, suggest that the state of the parasite surface determines the mechanism of parasite entry into the macrophage, the composition of the membrane lining the parasitophorous vacuole and the ability of lysosomes to fuse with the vacuoles.     

The effect of flow on the interaction of isolated megakaryocytes with subendothelial extracellular matrix.

We have previously shown that human, guinea pig, or rat megakaryocytes, incubated under static conditions on an extracellular matrix (ECM) produced by endothelial cells, readily adhered to the matrix and underwent platelet-like shape change and thromboxane A2 secretion. We have now exposed megakaryocytes to ECM in a perfusion system similar to that used to study platelets circulated over aortic subendothelium. We used a continuous flow circuit incorporating a parallel plate perfusion chamber. Megakaryocytes were isolated to high purity from guinea pig marrow by centrifugal elutriation and velocity sedimentation. The cells were introduced into the flowing medium while the surface of an ECM-coated coverslip mounted in the chamber was observed continuously by phase-contrast video microscopy for up to 18 hours. Megakaryocytes from the flowing suspension started to adhere to the ECM within seconds. Significant adhesion occurred over a range of shear rates, from 10 to 190 seconds-1, did not appear above 300 seconds-1 and was greatest at a shear rate of 60 seconds-1. Adhesion to the ECM was specific, since there was no adherence to glass coverslips, glutaraldehyde-fixed ECM-coated coverslips, or to endothelial cells cultured on ECM-coated coverslips. At low shear rates large aggregates of megakaryocytes formed on the ECM surface; these could be detached and washed away by higher shear forces. Megakaryocytes thus acquire, even before platelet formation, an adhesive capacity similar to that of platelets. In addition, a significant fraction of the adherent megakaryocytes underwent elongation and pseudopod formation similar to that seen in marrow sinusoids.     

Acriflavin-Induced Dyskinetoplastic Leishmania donovani Grown in Monkey Kidney Cell Culture

SYNOPSIS. Monkey kidney cells (LLC-MK₂) grown in flasks and on coverslips in Leighton tubes were used as host cells for the growth of the intracellular stage, Leishman-Donovan bodies (LDs), of Leishmania donovani obtained from hamster spleen. These parasitized cultures were then used to determine the ability of acriflavin to induce dyskinetoplastic LDs.
LD-infected cells were somewhat fewer in number than uninfected cells at all times except for the 1st day after infection. The parasites attained their maximum numbers on the 5th day after infection of the cultures having a 1.9-fold increase at that time.
When acriflavin was added to the cell culture medium (250 mμ/ml) the numbers of monkey kidney cells did not differ greatly from non-treated cultures until 6–7 days after treatment with acriflavin. Similarly, the numbers of LDs in acriflavin-treated cell cultures, altho somewhat below those of untreated cultures, did not differ greatly from them.
The combined effect of acriflavin and LDs reduced the numbers of monkey kidney cells in treated, LD-infected cell cultures more than either alone.
Dyskinetoplastic LDs appeared in considerable numbers in acriflavin-treated, LD-infected cell cultures. Dyskinetoplastic and normal LDs harvested from cell cultures were inoculated into NIH medium and incubated at 27 C for transformation into leptomonads. There was no indication that dyskinetoplastic LDs were capable of transforming into leptomonads.     

Fine Structure of Microgametocytes and Macrogametes of Eimeria nieschulzi

SYNOPSIS. An electron microscope study of microgametocytes and macrogametes of Eimeria nieschulzi Dieben, 1924 revealed that they lie within vacuoles bounded by a host unit membrane. The vacuole surrounding the microgametocyte contains granular material. The vacuole around the macrogamete is narrower and contains vesicles and membranes. Micropores were seen on the surface of the plasma membrane of microgametocytes and macrogametes. Microtubules were seen in macrogametes. Young microgametocytes and macrogametes have a similar cytoplasmic matrix, mitochondria and nuclei. Glycogen granules apparently develop around vacuoles in both microgametocytes and macrogametes. Glycogen granules were also seen along the margins of parallel bundles of fibers in microgametocytes. As nuclei of the microgametocyte divide, they move to the periphery of the parasite. Three basal bodies, each with 9 fibers in triplet form, develop in association with each nucleus. Microgametes have 2 free flagella and a central short, attached flagellum. Basal granules lie along the outer fibers of the central flagellum. Each microgamete has an elongate mitochondrion in close contact with the nucleus. In macrogametes wall-forming bodies develop in lacunae in the cytoplasm. Smaller dark bodies with areas of low density were also seen. Wall-forming bodies and dark bodies move to the periphery of mature macrogametes.     

Flow cytometry in the study of the interaction between murine macrophages and the protozoan parasite Leishmania amazonensis.

A flow cytometry method was adapted to study interaction between murine macrophages and Leishmania amazonensis. Using this method it was possible to detect internalization of parasites through an increase in macrophage granularity (side scatter), with the latter indicating the presence of parasites inside parasitophorus vacuoles. A quenching technique was used to confirm the feasibility of the method and to distinguish between internalized and externally attached parasites. Experiments using fixed-labeled and killed-unlabeled parasites gave similar results, demonstrating that granularity was an adequate parameter in the study of parasite-macrophage interaction, when compared with labeling methods. Experiments that measured internalization using only the increase in macrophage granularity as an indicator showed that living L. amazonensis was internalized to a greater extent than killed-unlabeled parasites. This finding suggests that the parasite has an active role in the process of internalization. The 2 methods in combination, flow cytometry and labeling, can be used to study murine peritoneal cell-L. amazonensis interactions and to sort phagocytosing and nonphagocytosing subpopulations of macrophages for further studies.     

Fusion of Host Cell Secondary Lysosomes with the Parasitophorous Vacuoles of Leishmania mexicana-inlected Macrophages

SYNOPSIS. Secondary lysosomes of cultured mouse peritoneal macrophages were labeled with the electron-dense colloid saccharated iron oxide; the identity of the labeled structures was checked by the Gomori reaction for acid phosphatase. Amastigotes of Leishmania mexicana mexicana derived from mouse lesions were used to infect these macrophages in vitro. In electron micrographs of thin sections of infected macrophages the labeled secondary lysosomes were seen fused with the parasitophorous vacuoles without preventing subsequent multiplication of the parasites. A similar fusion probably occurs in vivo , and may provide a pathway through which not only nutrients but also drugs and host antibodies could reach the intracellular parasite.     

Fusion of host cell secondary lysosomes with the parasitophorous vacuoles of Leishmania mexicana-infected macrophages.

Secondary lysosomes of cultured mouse peritoneal macrophages were labeled with the electron-dense colloid saccharated iron oxide; the identity of the labeled structures was checked by the Gomori reaction for acid phosphatase. Amastigotes of Leishmania mexicana mexicana derived from mouse lesions were used to infect these macrophages in vitro. In electron micrographs of thin sections of infected macrophages the labeled secondary lysosomes were seen fused with the parasitophorous vacuoles without preventing subsequent multiplication of the parasites. A similar fusion probably occurs in vivo, and may provide a pathway through which not only nutrients but also drugs and host antibodies could reach the intracellular parasite.     

Leishmania donovani: role of microviscosity of macrophage membrane in the process of parasite attachment and internalization

Host macrophage infection by the parasite Leishmania donovani is heterogeneous, but it is not clear which factors are responsible for parasite recognition within the macrophages. One possible factor may be the alteration of the microviscosity of the macrophage membrane. This in turn may affect receptor expression and hence parasite infection. In this paper we describe alteration of the lipid composition and hence the microviscosity of the macrophage membrane in a controlled manner using liposome fusion technique. At a higher macrophage membrane microviscosity a larger number of parasites have been found to adhere to the macrophage surface. However, the proportion of parasites finally internalized when compared to parasites adhering to macrophages is inversely correlated with the artificially altered macrophage membrane microviscosity. The process of endocytosis has been examined in both native and lipid modified macrophages in the presence of several sugar antagonists. The results indicate (i) glucose and mannose are specifically involved in the binding process, and (ii) the microviscosity has a key role in controlling the macrophage parasite interaction. The results obtained so far support a model of endocytosis where expression of the receptor is a critical initial process dependent on the microviscosity of the membrane.     

Importance of lymphokines in the control of multiplication and dispersion of Leishmania donovani within liver macrophages of resistant and susceptible mice

Leishmania donovani is an obligate intracellular parasite of mammalian macrophages. The immunosuppressant cyclosporin A (CsA), which inhibits the production of interleukin (IL)-1, IL-2, and interferon-gamma, increased infections 3-fold without affecting expression of the Lsh gene. The objective of this study was to determine how activation of macrophages by lymphokines affects the multiplication and propagation of the parasite within liver macrophages. Susceptible C57BL/6J and resistant C57L/J mice were treated with 200 mg/kg CsA and then infected intravenously with 10(7) amastigotes. Two weeks later macrophages were collected from the liver by perfusion, plated on coverslips, and incubated for 4, 24, and 48 hr. The percentage of infected macrophages and the number of amastigotes/100 cells were determined after staining the cells with Giemsa's stain. The number of infected macrophages and amastigotes per macrophage was significantly greater in animals of both strains that had been treated with CsA. This study demonstrated clearly that lymphokines or other soluble mediators produced by T cells act, in part, to control infection by L. donovani by minimizing both multiplication within macrophages and their dispersion.     

Key role of the macrophage microtubule network in the intracellular lifestyle of Leishmania amazonensis

We conducted a study to decipher the mechanism of the formation of the large communal Leishmania amazonensis‐containing parasitophorous vacuole (PV) and found that the macrophage microtubule (MT) network dynamically orchestrates the intracellular lifestyle of this intracellular parasite. Physical disassembly of the MT network of macrophage‐like RAW 264.7 cells or silencing of the dynein gene, encoding the MT‐associated molecular motor that powers MT‐dependent vacuolar movement, by siRNA resulted in most of the infected cells hosting only tight parasite‐containing phagosome‐like vacuoles randomly distributed throughout the cytoplasm, each insulating a single parasite. Only a minority of the infected cells hosted both isolated parasite‐containing phagosome‐like vacuoles and a small communal PV, insulating a maximum of two to three parasites. The tight parasite‐containing phagosome‐like vacuoles never matured, whereas the small PVs only matured to a small degree, shown by the absence or faint acquisition of host‐cell endolysosomal characteristics. As a consequence, the parasites were unable to successfully complete promastigote‐to‐amastigote differentiation and died, regardless of the type of insulation.     

Sporozoites of mammalian malaria: attachment to, interiorization and fate within macrophages

Sporozoites of Plasmodium berghei and Plasmodium knowlesi, incubated in normal serum readily interact with peritoneal macrophages of mice or rhesus monkeys, respectively. Interiorization of the sporozoite requires that both serum and macrophages be obtained from an animal susceptible to infection by the malaria parasite. Serum requirements for sporozoite attachment to the macrophage are less specific. Phagocytosis is not essential for the parasites to become intracellular. Our findings indicate that active penetration of the sporozites into the macrohages does occur. Antibodies present in the serum of sporozoite-immunized mice are important in determining the fate of both the intracellular sporozoites and the macrophages containing the parasite. Sporozoites coated with antibodies degenerate within vacuoles of the macrophages, which have no morphologic alteration. Sporozoites incubated in normal serum do not degenerate within macrophages, but the parasitized macrophages become morphologically altered and are destroyed. Preliminary experiments indicate that sporozoites appear to interact with rat Kupffer cells in the same way as with the peritoneal mouse macrophages. It is postulated that Kupffer cells play a dual role in sporozoite-host cell interaction. In normal animals these cells might serve to localize the sporozoites in the immediate vicinity of the hepatocytes. In the immunized animals, macrophages would remove and destroy the antibody-coated parasites, thus contributing to sporozoite-induced resistance.     

Leishmania mexicana: acid phosphatase ultrastructural cytochemistry of infected mouse macrophage cultures treated with phenazine methosulfate

Bone marrow-derived mouse macrophage cultures infected with Leishmania mexicana amazonensis amastigotes were given a 2-hr pulse with 10 microM phenazine methosulfate (PMS), a cationic electron carrier which destroys the intracellular parasites. Cultures were fixed at different times after the PMS pulse and processed for the detection of acid phosphatase (AcP) activity at the electron microscopic level. Only a small proportion of nontreated, infected macrophages stained for AcP. In contrast, 2 to 6 hr after exposure to PMS, many infected cells displayed AcP-positive lysosomes and parasitophorous vacuoles. This increased AcP reactivity paralleled the reduction in the percentage of morphologically intact parasites. In addition, qualitative observations indicated that while nontreated infected cells contained only few recognizable lysosomes, the lysosomal complement noticeably increased a few hours after exposure to PMS. Most intact intracellular amastigotes were not stained, but damaged parasites were often positive for AcP. Twenty hours after the PMS pulse, the percentage of AcP-positive macrophages dropped to the levels initially present in noninfected cultures and all of the parasites were destroyed. Exposure of noninfected macrophages to PMS did not affect their AcP reactivity.     

Vacuoles in macrophages and reticular cells of regional lymph nodes of the rat after injection of large doses of steroids

The ultrastructure of macrophages and reticular cells of regional lymph nodes of the rat after administration of large doses of cortisone acetate, estrone, progesterone, and cholesterol in aqueous suspensions was investigated. A large number of vacuoles, most of which were surrounded by unit membrane, and lipid droplets not surrounded by unit membrane were observed in the cytoplasm of both macrophages and reticular cells. They were not seen in these cells of control animals and in experimental animals that had received smaller doses of these steroid hormones. After cholesterol injection, many lipid droplets were observed in the cytoplasm of macrophages. These observations suggest that steroids injected in suspension accumulate in macrophages and reticular cells of the regional lymph nodes. Electron-dense material was often present in vacuoles of macrophages but not in those of reticular cells.     

Development of Eimeria crandallis Honess from Sheep in Cultured Cells*

SYNOPSIS. Cell lines of embryonic lamb trachea (LETr), lamb thyroid (LETh), and bovine liver (BEL) as well as an established cell line of Madin-Darby bovine kidney (MDBK) were used in a study of the in vitro development of Eimeria crandallis from sheep. Excysted sporozoites were inoculated into Leighton tubes containing coverslips with monolayers of the different cell types. Coverslips were examined with phase-contrast and interference-contrast at various intervals up to 20 days after inoculation; thereafter the monolayers were fixed and stained in various ways. Freshly excysted sporozoites, with 2–10 spheroidal refractile bodies, entered all of the cell types in relatively small numbers; intracellular sporozoites were first seen 2 min after inoculation. After 24 hr, most intracellular sporozoites had only 1 or 2 refractile bodies. Before and during transformation of sporozoites, the nucleus and peripheral nucleolus increased markedly in size. Transformation resulted in usually spheroid but sometimes ellipsoid trophozoites. Trophozoites were seen first 3–4 days, and binucleate schizonts at 4–5 days after inoculation. Immature schizonts increased considerably in size and eventually had large numbers of nuclei. Some of the parasites became lobulated and the lobules often separated to form individual schizonts. In BEL, LETr and LETh cells, mature schizonts, up to 150 μm in diameter, were seen first 11–14 days after inoculation. The BEL cells were the most favorable for development. Merozoites were formed by a budding process from the surface of the schizonts as well as from blastophores. Some merozoites were seen leaving mature schizonts, but no further development was observed. Merozoites frequently were motile and had a sharply bent posterior end. Marked nuclear and cytoplasmic changes were observed in parasitized cells.     

Phagotrophy and two new structures in the malaria parasite Plasmodium berghei

Blood collected from rats infected with Plasmodium berghei was centrifuged and the pellet was fixed for 1 hour in 1 per cent buffered OsO(4) with 4.9 per cent sucrose. The material was embedded in n-butyl methacrylate and the resulting blocks sectioned for electron microscopy. The parasites were found to contain, in almost all sections, oval bodies of the same density and structure as the host cytoplasm. Continuity between these bodies and the host cytoplasm was found in a number of electron micrographs, showing that the bodies are formed by invagination of the double plasma membrane of the parasite. In this way the host cell is incorporated by phagotrophy into food vacuoles within the parasite. Hematin, the residue of hemoglobin digestion, was never observed inside the food vacuole but in small vesicles lying around it and sometimes connected with it. The vesicles are pinched off from the food vacuole proper and are the site of hemoglobin digestion. The active double limiting membrane is responsible not only for the formation of food vacuoles but also for the presence of two new structures. One is composed of two to six concentric double wavy membranes originating from the plasma membrane. Since no typical mitochondria were found in P. berghei, it is assumed that the concentric structure performs mitochondrial functions. The other structure appears as a sausage-shaped vacuole surrounded by two membranes of the same thickness, density, and spacing as the limiting membrane of the body. The cytoplasm of the parasite is rich in vesicles of endoplasmic reticulum and Palade's small particles. Its nucleus is of low density and encased in a double membrane. The host cells (reticulocytes) have mitochondria with numerous cristae mitochondriales. In many infected and intact reticulocytes ferritin was found in vacuoles, mitochondria, canaliculi, or scattered in the cytoplasm.     

Phagotrophy and Two New Structures in the Malaria Parasite Plasmodium berghei

Blood collected from rats infected with Plasmodium berghei was centrifuged and the pellet was fixed for 1 hour in 1 per cent buffered OsO₄ with 4.9 per cent sucrose. The material was embedded in n-butyl methacrylate and the resulting blocks sectioned for electron microscopy. The parasites were found to contain, in almost all sections, oval bodies of the same density and structure as the host cytoplasm. Continuity between these bodies and the host cytoplasm was found in a number of electron micrographs, showing that the bodies are formed by invagination of the double plasma membrane of the parasite. In this way the host cell is incorporated by phagotrophy into food vacuoles within the parasite. Hematin, the residue of hemoglobin digestion, was never observed inside the food vacuole but in small vesicles lying around it and sometimes connected with it. The vesicles are pinched off from the food vacuole proper and are the site of hemoglobin digestion. The active double limiting membrane is responsible not only for the formation of food vacuoles but also for the presence of two new structures. One is composed of two to six concentric double wavy membranes originating from the plasma membrane. Since no typical mitochondria were found in P. berghei, it is assumed that the concentric structure performs mitochondrial functions. The other structure appears as a sausage-shaped vacuole surrounded by two membranes of the same thickness, density, and spacing as the limiting membrane of the body. The cytoplasm of the parasite is rich in vesicles of endoplasmic reticulum and Palade's small particles. Its nucleus is of low density and encased in a double membrane. The host cells (reticulocytes) have mitochondria with numerous cristae mitochondriales. In many infected and intact reticulocytes ferritin was found in vacuoles, mitochondria, canaliculi, or scattered in the cytoplasm.     

Leishmania amazonensis infection: a comparison of in vivo leishmanicidal mechanisms between immunized and naive infected BALB/c mice.

In vitro studies have shown that both macrophage activation and destruction of parasitized macrophages lead to leishmania destruction. The relative role played by such mechanisms in vivo have not been properly evaluated. We took advantage of the model of intravenous immunization with solubilized leishmanial antigen which renders partially resistant the otherwise highly susceptible BALB/c mice to address this issue avoiding the interference of different genetic backgrounds. Leishmania destruction occurred in three situations: destruction of the parasitized macrophage, which were in close contact with lymphocytes or eosinophils; extracellular damage, always surrounded by small foci of granulocytes; and parasite damage inside activated macrophages. Destruction of the parasitized macrophages was frequently seen in immunized and protected animals. Our observations suggest that destruction of parasite-loaded macrophages is an important mechanism of host protection in experimental cutaneous leishmaniasis.     

Cysteine and serine protease inhibitors block intracellular development and disrupt the secretory pathway of Toxoplasma gondii

A number of cysteine and serine protease inhibitors blocked the intracellular growth and replication of Toxoplasma gondii tachyzoites. Most of these inhibitors caused only minor alterations to parasite morphology irrespective of the effects on the host cells. However, three, cathepsin inhibitor III, TPCK and subtilisin inhibitor III, caused extensive swelling of the secretory pathway of the parasite (i.e. the ER, nuclear envelope, and Golgi complex), caused the breakdown of the parasite surface membrane, and disrupted rhoptry formation. The disruption of the secretory pathway is consistent with the post-translational processing of secretory proteins in Toxoplasma, and with the role of proteases in the maturation/activation of secreted proteins in general. Interestingly, while all parasites in an individual vacuole (the clonal progeny of a single invading parasite) were similarly affected, parasites in different vacuoles in the same host cell showed different responses to these inhibitors. Such observations imply that there are major differences in the biochemistry/physiology between tachyzoites within different vacuoles and argue that adverse effects on the host cell are not always responsible for changes in the parasite. Treatment of established parasites also leads to an accumulation of abnormal materials in the parasitophorous vacuole implying that materials deposited into the vacuole normally undergo proteolytic modification or degradation. Despite the often extensive morphological changes, nothing resembling lysosomal bodies was seen in any treated parasites, consistent with previous observations showing that mother cell organelles are not recycled by any form of autophagic-lysosomal degradation, although the question of how the parasite recycles these organelles remains unanswered.