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.     

Intralysosomal accumulation of polyanions. I. Fusion of pinocytic and phagocytic vacuoles with secondary lysosomes

The long-term exposure of macrophages to low concentrations of a number of polyanions leads to their accumulation in high concentration within secondary lysosomes. This was associated with enlargement of the lysosomes, the presence of membranous whorls, and intense toluidine blue staining of the organelles at pH 1.0. After the ingestion of a particulate load by these cells, newly formed phagocytic vacuoles failed to fuse with polyanion-laden lysosomes. The lack of fusion was evident in both fluorescence and electron micrographic studies which followed the transfer of acridine orange or Thorotrast from 2 degrees lysosomes to phagosomes. Agents that inhibited phagosome-lysosome (P-L) fusion included molecules containing high densities of sulfate, sulfonate, or carboxylate residues. Dextran sulfate (DS) in microgram/ml quantities was an excellent inhibitor, whereas nonsulfated dextran (D) was without effect at 1,000-fold higher concentrations. In contrast to their effects on P-L fusion, polyanions failed to influence the fusion of pinocytic vesicles with 2 degrees lysosomes. The uptake, intravacuolar distribution, and intralysosomal digestion of fluid-phase pinocytic markers were unaltered in lysosomes containing either D or DS. Furthermore, subcellular fractionation studies showed that the fluid-phase pinocytic marker HRP was efficiently transferred from pinosomes to large, dense 2 degrees lysosomes containing DS.     

Membrane flow during pinocytosis. A stereologic analysis

HRP has been used as a cytochemical marker for a sterelogic analysis of pinocytic vesicles and secondary lysosomes in cultivated macrophages and L cells. Evidence is presented that the diaminobenzidine technique (a) detects all vaculoes containing encyme and (b) distinguishes between incoming pinocytic vesicles and those which have fused with pre-existing lysosomes to form secondary lososomes. The HRP reactive pinocytic vesicle spaces fills completely within 5 min after exposure to enzyme, while the secondary lysosome compartment is saturated in 45--60 min. The size distribution of sectioned (profile) vaculoe diameters was measured at equilibrium and converted to actual (spherical) dimensions using a technique modified from Dr. S. D. Wicksell. The most important findings in this study have to do with the rate at which pinocytosed fluid and surface membrane move into the cell and on their subsequent fate. Each minute macrophages form at least 125 pinocytic vesicles having a fractional vol of 0.43% of the cell's volume and a fractional area of 3.1% of the cell's surface area. The fractional volume and surface area flux rates for L cells were 0.05% and 0.8% per minute respectively. Macrophages and L cells thus interiorize the equivalent of their cell surface area every 33 and 125 min. During a 3-period, the size of the secondary lysosome compartment remains constant and represents 2.5% of the cell volume and 18% of the surface area. Each hour, therefore, the volume and surface area of incoming vesicles is 10 times greater than the dimensions of the secondary lysosomes in both macrophages and L cells. This implies a rapid reduction in vesicle size during the formation of the secondary lysosome and the egress of pinocytosed fluid from the vacuole and the cell. In addition, we postulate that membrane components of the vacuole are subsequently recycled back to the cell surface.     

Anionic sites,fucose residues and class I human leukocyte antigen fate during interaction of Toxoplasma gondii with endothelial cells

Toxoplasma gondii invades and proliferates in human umbilical vein endothelial cells where it resides in a parasitophorous vacuole. In order to analyze which components of the endothelial cell plasma membrane are internalized and become part of the parasitophorous vacuole membrane, the culture of endothelial cells was labeled with cationized ferritin or UEA I lectin or anti Class I human leukocyte antigen (HLA) before or after infection with T. gondii. The results showed no cationized ferritin and UEA I lectin in any parasitophorous vacuole membrane, however, the Class I HLA molecule labeling was observed in some endocytic vacuoles containing parasite until 1 h of interaction with T. gondii. After 24 h parasite-host cell interaction, the labeling was absent on the vacuolar membrane, but presents only in small vesicles near parasitophorous vacuole. These results suggest the anionic site and fucose residues are excluded at the time of parasitophorous vacuole formation while Class I HLA molecules are present only on a minority of Toxoplasma-containing vacuoles.     

Autophagy, cathepsin L transport, and acidification in cultured rat fibroblasts.

The mechanisms of enzyme delivery to and acidification of early autophagic vacuoles in cultured fibroblasts were elucidated by cryoimmunoelectron microscopic methods. The cation-independent mannose-6-phosphate receptor (MPR) was used as a marker of the pre-lysosomal compartment, and cathepsin L and an acidotropic amine (3-(2,4-dinitroanilino)-3'-amino-N-methyl-dipropylamine (DAMP), a cytochemical probe for low-pH organelles) as markers of both pre-lysosomal and lysosomal compartments. In addition, cationized ferritin was used as an endocytic marker. In ultrastructural double labeling experiments, the bulk of all the antigens was found in vesicles containing tightly packed membrane material. These vesicles also contained small amounts of endocytosed ferritin and probably correspond to the MPR-enriched pre-lysosomal compartment. Some immunolabeling was also visible in the trans-Golgi network. In addition, cathepsin L, DAMP, and large amounts of ferritin were found in smaller vesicles which can be classified as mature lysosomes. Early autophagic vacuoles were defined as vesicles containing recognizable cytoplasm. MPR, cathepsin L, and DAMP, but not ferritin, were detected in the early vacuoles. Inhibition of the acidification in the early vacuoles by monensin did not prevent the delivery of MPR and cathepsin L. The presence of MPR in the vacuoles suggests that cathepsin L is not delivered to early autophagic vacuoles solely by fusion with mature, MPR-deficient lysosomes. Furthermore, although lysosomes were loaded with endocytosed ferritin, it was not detected in autophagic vacuoles. Either the trans-Golgi network or the MPR-enriched pre-lysosomes may be the main source of enzymes and acidification machinery for the autophagic vacuoles in fibroblasts.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tritrichomonas foetus: ultrastructure and cytochemistry of endocytosis

Tritrichomonas foetus ingests horseradish peroxidase, native ferritin, cationized ferritin, and 0.08 micron latex beads by a process which involves the formation of pinocytic vesicles. These vesicles fuse with each other and with lysosomes forming large vacuoles. Biochemical determinations on the ingestion of horseradish peroxidase and morphometric analysis on the ingestion of cationized ferritin covered latex beads indicated that T. foetus has high endocytic activity. The process of ingestion of the various tracers used was analyzed by transmission electron microscopy of thin sections and freeze fracture replicas.     

3D reconstruction of Trypanosoma cruzi-macrophage interaction shows the recruitment of host cell organelles towards parasitophorous vacuoles during its biogenesis

Trypanosoma cruzi has a complex life cycle where two infective developmental stages, known as trypomastigote and amastigote, can be found in the vertebrate host. Both forms can invade a large variety of cellular types and induce the formation of a parasitophorous vacuole (PV), that, posteriorly, disassembles and releases the parasites into the host cell cytoplasm. The biogenesis of T. cruzi PVs has not been analyzed in professional phagocytic cells. We investigated the biogenesis of PVs containing trypomastigotes or amastigotes in peritoneal macrophages. We observed the presence of profiles of the endoplasmic reticulum and lysosomes from the host cell near PVs at early stages of interaction in both developmental stages, suggesting that both organelles may participate as possible membrane donors for the formation of the PVs. The Golgi complex, however, was observed only near already formed PVs. Electron microscopy tomography and FIB-SEM microscopy followed by 3D reconstruction of entire PVs containing amastigotes or trypomastigotes confirmed the presence of both endoplasmic reticulum and lysosomes in the initial stages of PV formation. In addition, Golgi complex and mitochondria localize around PVs during their biogenesis. Taken together these observations provide a whole view of the invasion process in a professional phagocytic cell.     

Uptake and intracellular transport of cationic ferritin in the bronchiolar and alveolar epithelia of the rat

Summary Cationic ferritin was used as a marker to reveal the processes of endocytosis and intracellular transport in bronchiolar and alveolar epithelia. The marker was injected into the lung via the trachea, and ultrastructural observation of the distribution of ferritin particles in bronchiolar and alveolar epithelial cells was carried out at intervals of 5, 15, 30 and 60 min after the injection. The luminal surface of the airway and the alveolar epithelium showed diffuse labeling with cationic ferritin. In general, ferritin particles were observed in vesicles and vacuoles of the bronchiolar and alveolar epithelial cells within 5 min of injection; they appeared in multivesicular bodies within 15 min. Multivesicular bodies and secondary lysosomes containing ferritin particles, some of which showed a positive reaction for acid phosphatase, were seen in the basal cytoplasm within 30 min; ferritin particles appeared in the basal lamina below the Clara cells, ciliated cells and type 2 alveolar cells within 30 min. Ferritin particles were seen in ovoid granules of some Clara cells and in lamellar inclusion bodies of many type 2 alveolar cells. Brush cells and type 1 alveolar cells took up only a small quantity of ferritin particles.     

Depletion of secondary lysosomes in mouse macrophages infected with Leishmania mexicana amazonensis: a cytochemical study

Leishmania amastigotes lodge and multiply within parasitophorous vacuoles, which can fuse with secondary lysosomes of the host macrophages. This study examines the effect of infection with amastigotes of L. mexicana amazonensis on the secondary lysosomes of mouse macrophage cultures. The cultures were stained for the activities of two lysosomal enzyme markers, acid phosphatase and arylsulfatase, and the light microscopic observations were supplemented by electron microscopy. Nearly all noninfected macrophages contained numerous stained secondary lysosomes. The number of such lysosomes was markedly reduced 24 h postinfection, and the reduction persisted for at least 10 days. Stained secondary lysosomes reappeared after the amastigotes were destroyed by exposure of the cultures to phenazine methosulfate or by placing them at 37.5 degrees C. The depletion of lysosomes shown by cytochemical methods may reflect a high rate of fusion of the lysosomes with the parasitophorous vacuoles, exceeding the rate of formation of new secondary lysosomes. Alternatively, the parasites may inhibit the synthesis of lysosomal hydrolases, or the assembly or formation of primary or secondary lysosomes.     

Endocytic pathways and time sequence of lysosomal transfer of macromolecules in cultured mouse peritoneal macrophages

Summary A double-labeling protocol was used to study endocytic pathways and lysosomal transfer of exogenous macromolecules in cultured mouse peritoneal macrophages. After pulse-chase labeling of lysosomes with horseradish peroxidase (visualized cytochemically), the cells were exposed to native, anionic ferritin for 0–45 min at 37° C and then analysed by transmission electron microscopy. The results show that ferritin binds to the plasma membrane, accumulates in coated pits, and is rapidly taken up in small, smooth-surfaced endocytic vesicles. The latter carry the ferritin molecules directly to lysosomes, recognized by their peroxidase labeling, or fuse with each other to form larger endocytic vacuoles (endosomes) which in turn fuse with and empty their content into lysosomes. The first signs of transfer of ferritin into the lysosomes were seen after 5–10 min of exposure and after 25–30 min most of the lysosomes were labeled. Union of ferritin-labeled and other lysosomes was also noted, suggesting that the contents of the lysosomes were spread within the lysosomal compartment by fusion-fission processes. It is concluded that a multiplicity of structures is involved in the uptake and intracellular transport of exogenous macromolecules in macrophages and that the time sequence of lysosomal transfer of the interiorized material is highly variable.     

Magnetic separation of pinocytic vesicles of defined age from Entamoeba histolytica

We describe a rapid and simple method to isolate pinocytic vesicles of defined age (residing time within the cell) from Entamoeba histolytica. Amoebas are allowed to pinocytize for greater than 5 min a suspension of superparamagnetic iron oxide particles, washed, and resuspended for predetermined periods (up to 150 min) in iron oxide-free medium. Subsequently, the cells are homogenized and iron oxide-containing vesicles are separated magnetically. Recovery of vesicles (estimated with fluorescein isothiocyanate-dextran as a quantitative marker for pinocytosis) was 20-40%. Contamination with "older" vesicles or with plasma membrane (estimated with fluorescein isothiocyanate-dextran and with fluorescein isothiocyanate-conjugated, succinylated concanavalin A, respectively) was negligible. Using this method we obtained evidence that in E. histolytica, contrary to the situation in animal cells, pinocytic vesicles within 150 min after invagination neither shrunk nor fused with each other to any significant extent. The method should be generally applicable to protozoa for the isolation of pinocytic vesicles and digestive vacuoles.     

Analysis of the pinocytic process in rat kidney II. Biochemical composition of pinocytic vesicles compared to brush border microvilli,lysosomes and basolateral plasma membranes

Pinocytic vesicles, brush border microvilli, lysosomes and basolateral plasma membranes were isolated from rat kidney cortex and their biochemical composition and membrane turnover compared. Pinocytic vesicles are devoid of marker enzymes of brush border microvilli, such as alkaline phosphatase and 5′-nucleotidase, and of lysosomes, such as acid phosphatase and β-glucuronidase. The protein pattern as revealed by polyacrylamide gel electrophoresis differs for all four membranes. Analysis of the phospholipid composition shows that pinocytic vesicles are rich in the negatively charged phospholipid phosphatidylserine and have a low content of sphingomyelin and phosphatidylethanolamine.[¹⁴C]guanido-arginine, [³H]fucose and $\text{myo-}\text{[}{}^3\text{H]inositol}$ were preferentially incorporated into the pinocytic vesicles. Using a double label technique with leucine also, evidence of a more rapid turnover of the pinocytic vesicle membrane proteins was obtained.The results suggest that pinocytic vesicles are not derived from the brush border microvillous membrane but are independent entities that are newly synthesized during the pinocytic process.     

Liposomal chemotherapy in visceral leishmaniasis: an ultrastructural study of an intracellular pathway

The intracellular fate of liposomes administered intracardially was examined in the liver and spleen of hamsters experimentally infected with Leishmania donovani. Separate groups of animals were treated with liposomes containing either an antileishmanial agent, a colloidal gold marker, or saline. Ultrastructural examinations of lysosomal interactions with the parasitophorous vacuole and with phagocytized liposomes were made. Lysosomes readily fused with the parasitophorous vacuoles but appeared to have little effect on the parasite, possibly due to the production of enzyme inhibitors. Liposomes rapidly became localized in lysosomes subsequent to endocytosis by macrophages. Morphologic evidence suggested that secondary lysosomes containing liposomal residues then fused with the parasitophorous vacuole. Aspects of one possible pathway are discussed which may account for the greatly enhanced effectiveness of liposomal chemotherapy for experimental visceral leishmaniasis.     

Cytochemical localization of acid phosphatase in light- and dark-adapted eyes of a polychaete worm,Nereis limnicola

Summary The amount and distribution of the lysosomal enzyme acid phosphatase in light- and dark-adapted eyes of the brackish-water annelid Nereis limnicola were studied by standard cytochemical techniques. Precipitate from the acid phosphatase reaction was observed in Golgi-endoplasmic reticulum-lysosomal complexes, primary lysosomes, and secondary lysosomes, formed by fusion of primary lysosomes with phagocytic and pinocytic vesicles containing products of presumed rhabdomeric degradation. The acid phosphatase reaction occurred in these organelles in both sensory and supportive cells of both light- and darkadapted ocelli. Secondary lysosomes were more abundant in sensory cells of illuminated ocelli than in those maintained in the dark. Sparse reaction product was found in Golgi cisternae, none in rough endoplasmic reticulum. We suggest that the increase of lysosomal activity in light-adapted eyes is correlated with the breakdown of photosensory microvilli upon exposure to light. A diagram of our interpretation of recycling of photoreceptoral membrane in N. limnicola is presented.     

APPEARANCE AND DISTRIBUTION OF FERRITIN IN MOUSE PERITONEAL MACROPHAGES IN VITRO AFTER UPTAKE OF HETEROLOGOUS ERYTHROCYTES

Mouse peritoneal macrophages have been studied in vitro after ingestion of treated rat, rabbit, or sheep erythrocytes. Under light microscopy, phagocytic vacuoles persist up to 24 h. Macrophages lose benzidine reactivity about 5 h after red cell ingestion, and they become prussian blue positive at 2 days. Ultrastructural studies show little or no ferritin in control macrophages not fed erythrocytes. In contrast, after red cell ingestion, ferritin is widely distributed in the cytoplasmic matrix and in some cytoplasmic granules by 48 h. The Golgi complex, pinocytic vacuoles, endoplasmic reticulum, nuclei, and mitochondria do not contain ferritin. Between 2 and 4 days, ferritin in cytoplasmic granules increases, concomitant with decrease in the ferritin in the cytoplasmic matrix. Evidence is presented suggesting that ferritin in the cytoplasmic matrix is translocated into cytoplasmic granules by autophagy. Polyacrylamide gel studies on macrophages after uptake of red blood cells labeled with radioiron confirm that macrophages produce radiolabeled ferritin by 4 days.     

Uptake and transport of intact macromolecules in the intestinal epithelium of carp (Cyprinus carpio L.) and the possible immunological implications

Summary Two protein antigens, horseradish peroxidase (HRP) and ferritin, have been administered to the digestive tract of carp. Electron-microscopical observations reveal considerable absorption of both antigens in the second segment of the gut (from 70 to 95% of the total length) and also, although to a lesser extent, in the first segment (from 0 to 70% of the total length). Even when administered physiologically with food, a large amount of ferritin is absorbed by enterocytes in the second gut segment.HRP and ferritin are processed by enterocytes in different ways. HRP seems to adhere to the apical cell membrane, probably by binding to receptors, and is transported in vesicles to branched endings of lamellar infoldings of the lateral and basal cell membrane. Consequently, most of the HRP is released in the intercellular space where it contacts intra-epithelial lymphoid cells. Only small amounts of HRP become localized in secondary lysosomes of enterocytes. Ferritin does not bind to the apical cell membrane; after uptake by pinocytosis, it is present in small vesicles or vacuoles that appear to fuse with lysosome-like-bodies. In the second segment, intact ferritin ends up in the large supranuclear vacuoles (after 8 h), where it is digested slowly. Although no ferritin is found in the intercellular space, ferritin-containing macrophages are present between the epithelial cells, in the lamina propria and also to a small extent in the spleen. The transport of antigens from the intestinal lumen, through enterocytes, to intra-epithelial lymphoid cells or macrophages may have immunological implications, such as induction of a local immune response and prospectives for oral vaccination.     

Survival and replication of Piscirickettsia salmonis in rainbow trout head kidney macrophages

Piscirickettsia salmonis is pathogenic for a variety of cultured marine fish species worldwide. The organism has been observed within host macrophages in natural disease outbreaks among coho salmon and European sea bass. In vitro studies, incorporating transmission electron microscopy (TEM) and ferritin loading of lysosomes, have confirmed that P. salmonis is capable of surviving and replicating in rainbow trout macrophages. Certain features of this intracellular survival underline its difference to other intracellular pathogens and suggest that a novel combination of defence mechanisms may be involved. Escape into the macrophage cytoplasm is not used as a means to avoid phago-lysosomal fusion and the organism remains at least partly enclosed within a vacuole membrane. While the piscirickettsial vacuole is often incomplete, survival and replication appear to require occupation of a complete, tightly-apposed, vacuolar membrane which does not fuse with lysosomes. Unlike some mammalian rickettsiae, actin-based motility (ABM) is not used as a means of intercellular spread. It is postulated that the presence of numerous small vesicles within vacuoles, and at gaps in the vacuolar membrane, may result from the blebbing of the piscirickettsial outer membrane seen early in the infection.     

Toxoplasma gondii resides in a vacuole that avoids fusion with host cell endocytic and exocytic vesicular trafficking pathways.

Toxoplasma gondii actively penetrates its vertebrate host cell to establish a nonfusigenic compartment called the parasitophorous vacuole (PV) that has previously been characterized primarily in phagocytic cells. To determine the fate of this unique compartment in nonphagocytic cells, we examined the trafficking of host cell proteins and lipids in Toxoplasma-infected fibroblasts using quantitative immunofluorescence and immunoelectron microscopy. Toxoplasma-containing vacuoles remained segregated from all levels of the endocytic pathway, as shown by the absence of delivery of transferrin receptors, mannose phosphate receptors, and the lysosomal-associated protein LAMP1 to the vacuole. The PV was also inaccessible to lipids (DiIC16, and GM1) that were internalized from the plasma membrane via the endocytic system. In contrast, vacuoles containing dead parasites or zymosan sequentially acquired both endosomal and lysosomal protein markers and host lipids, reflecting the competency of fibroblasts to process phagocytic vacuoles. The mature PV often lies adjacent to the host cell Golgi, suggesting that it may intersect with vesicles from the exocytic pathway. Despite this proximity, the PV was inaccessible to nitrobenzadiazole-labeled sphingolipids exported from the Golgi and did not contain the host protein markers AP1 or beta-COP. Our results demonstrate that Toxoplasma resides in a compartment that excludes delivery of protein and lipid components from the host cell endocytic and exocytic pathways.     

Ultrastructural localization of cytoplasmic phosphatases in preimplantation mouse embryos.

The appearance and localization of the cytoplasmic phosphatases [acid phosphatase (AcPase) as a marker of lysosomes, TPPase as a marker of the Golgi apparatus, and NDPase (IDPase) as enzymatic marker of the endoplasmic reticulum (ER)] were cytochemically studied on the ultrastructural level in secondary oocytes and in preimplantation mouse embryos. The detectable AcPase activity, located on the inner surface of the membrane delimiting some cytoplasmic vacuoles (lysosomes and autophagic vacuoles), appears at the eight-cell stage and grows pregressively stronger up to the blastocyst stage. Golgi-associated reaction for TPPase was detectable in oocytes, dropped in one-cell embryos and became negative in the two-cell embryos. The reaction for TPPase and IDPase was present in plasma membranes of oocytes and early embryos and appeared in the delimiting membrane of some cytoplasmic vesicles in eight-cell embryos. Some activity of IDPase was found in small segments of the ER at the morula and blastocyst stage. The observed results suggest that the lysosomes are the first organelles in early embryos showing activity of the marker enzymes of the phosphatase type, while the activity of other marker enzymes is mainly concentrated in the plasma membrane of blastomeres. It cannot be excluded, however, that positive reaction for TPPase and IDPase in the plasma membrane results from nonspecific action of other phosphatases.     

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.