Localization of acid phosphatase in Acanthamoeba castellanii with light and electron microscopy during growth and after phagocytosis

Quantification and Characterization of Phagocytosis in the Soil Amoeba Acanthamoeba castellanii by Flow Cytometry

Phagocytosis in the common grazing soil amoeba Acanthamoeba castellanii was characterized by flow cytometry. Uptake of fluorescently labelled latex microbeads by cells was quantified by appropriate setting of thresholds on light scatter channels and, subsequently, on fluorescence histograms. Confocal laser scanning microscopy was used to verify the effectiveness of sodium azide as a control for distinguishing between cell surface binding and internalization of beads. It was found that binding of beads at the cell surface was complete within 5 min and 80% of cells had beads associated with them after 10 min. However, the total number of phagocytosed beads continued to rise up to 2 h. The prolonged increase in numbers of beads phagocytosed was due to cell populations containing increasing numbers of beads peaking at increasing time intervals from the onset of phagocytosis. Fine adjustment of thresholds on light scatter channels was used to fractionate cells according to cell volume (cell cycle stage). Phagocytotic activity was approximately threefold higher in the largest (oldest) than in the smallest (newly divided) cells of A. castellanii and showed some evidence of periodicity. At no stage in the cell cycle did phagocytosis cease. Binding and phagocytosis of beads were also markedly influenced by culture age and rate of rotary agitation of cell suspensions. Saturation of phagocytosis (per cell) at increasing bead or decreasing cell concentrations occurred at bead/cell ratios exceeding 10:1. This was probably a result of a limitation of the vacuolar uptake system of A. castellanii, as no saturation of bead binding was evident. The advantages of flow cytometry for characterization of phagocytosis at the single-cell level in heterogeneous protozoal populations and the significance of the present results are discussed.

Dynamic localization of myosin-I to endocytic structures in Acanthamoeba

We used fluorescence microscopy of live Acanthamoeba to follow the time course of the concentration of myosin-I next to the plasma membrane at sites of macropinocytosis and phagocytosis. We marked myosin-I with a fluorescently labeled monoclonal antibody (Cy3-M1.7) introduced into the cytoplasm by syringe loading. M1.7 binds myosin-IA and -IC without affecting their activities, but does not bind myosin-IB. Cy3-M1.7 concentrates at two different macropinocytic structures: large circular membrane ruffles that fuse to create macropinosomes, and smaller endocytic structures that occur at the end of stalk-like pseudopodia. These dynamic structures enclose macropinosomes every 30-60 s. Cy3-M1.7 accumulates rapidly as these endocytic structures form and dissipate rapidly after they internalize. Double labeling fixed cells with Cy3-M1.7 and polyclonal antibodies specific for myosin-IA, -IB, or -IC revealed that all three myosin-I isoforms associate with macropinocytic structures, but individual structures vary in their myosin-I isoform composition. Myosin-I and actin also concentrate transiently at sites where amoebae ingest yeast or the pseudopodia of neighboring cells (heterophagy) by the process of phagocytosis. Within 3 min of yeast attachment to the amoeba, myosin-I concentrates around the phagocytic cup, yeast are internalized, and myosin-I de-localizes. Despite known differences in the regulation of macropinocytosis and phagocytosis, the morphology, protein composition, and dynamics of phagocytosis and macropinocytosis are similar, indicating that they share common structural properties and contractile mechanisms.

Hydrolase compartmentalization limits rate of digestion in Acanthamoeba

The kinetics of lysosomal enzyme acquisition by newly formed phagosomes was studied by following the rate of digestion of radiolabeled yeast fed to Acanthamoeba. The distribution of hydrolases among phagosomes was assessed by electron microscopic acid phosphatase cytochemistry and by measurement of three glycosidases in isolated early and late phagosomes. The results show that compartmentalization of hydrolases limit the digestion of large phagocytic loads. The hydrolases appear to be sequestered into the early phagosomes and not to be distributed either by small vesicle transport or phagosome-phagosome fusion to those formed later. We infer from these results that newly internalized surface membrane in phagosomes is not rapidly randomized with internal pools, but is recycled to the surface as a function of the digestive process.

Quantitative evaluation of intracellular degradation in Entamoeba invadens

A quantitative study on digestion of erythrocytes by Entamoeba invadens was attempted. Trophozoites of the IP-1 strain were fed red blood cells for 30 min, and subsequently phagocytosis was stopped by means of osmotic shock; post-phagocytosis incubations for up to 15 h were made in order to evaluate intracellular digestion, after staining the red blood cells with benzidine. Eighty-two per cent of trophozoites were capable of phagocytosing erythrocytes, containing an average of 5.5 erythrocytes per amoeba. Erythrocyte digestion within amoebae was shown by loss of benzidine-stainable material and proceeded with a first-order kinetics, with a t1/2 approximately 7 h. Within 15 h there were no amoebae containing erythrocytes. The procedure described may be useful for the evaluation of intracellular digestion in other Entamoeba species.

Ultrastructural study of the interaction of the fungi Sporothrix schenckii and Ceratocystis stenoceras with bone-marrow-derived murine macrophages

Bone-marrow-derived macrophages of C57BL/6 mice cultivated in vitro were infected with the yeast form of Sporothrix schenckii or Ceratocystis stenoceras. Observations made in light and electron microscopy showed that part of the S. schenckii-containing phagosomes rapidly fused with lysosomes and fungal cells were digested. Surviving fungal cells elongated very rapidly and were liberated into the culture medium after 48 h upon macrophage lysis. The cells of the non-pathogenic isolate C. stenoceras did not elongate and were almost all digested after 8 days, while macrophages were unaltered. Staining for acid phosphatase showed that this enzymatic activity increased soon after ingestion with both isolates. However, this increase was less pronounced with S. schenckii than with the non-pathogenic isolate. The search for a toxic substance produced by S. schenckii and responsible for the low content in acid phosphatase and subsequent macrophage lysis remained negative. It is thus probable that both phenomena essentially resulted from fungus filamentation which led to a dramatic distortion of phagosomes and host cells.

Localization of a Mg2+-activated ATPase in the plasma membrane of Trypanosoma cruzi

The Wachstein and Meisel incubation medium was used to detect ATPase activity in epimastigote, spheromastigote (amastigote), and bloodstream trypomastigote forms of Trypanosoma cruzi. Reaction product, indicative of enzyme activity, was associated with the plasma membrane covering the cell body and the flagellum of the parasite. No reaction product was found in the portion of the plasma membrane lining the flagellar pocket. The plasma membrane-associated ATPase activity was not inhibited by ouabain or oligomycin, was detected in incubation medium without K+, was inhibited by prolonged glutaraldehyde fixation, and its activity was diminished when Mg2+ was omitted from the incubation medium. The Ernst medium was used to detect Na+-K+-ATPase activity in T. cruzi. No reaction product indicative of the presence of this enzyme was detected. Reaction product indicative of 5'-nucleotidase was not detected in T. cruzi. Acid phosphatase activity was detected in lysosomes. Those results indicate that a Mg2+-activated ATPase is present in the plasma membrane of T. cruzi and that it can be used as an enzyme marker, provided that the mitochondrial and flagellar ATPases are inhibited, to assess the purity of plasma membrane fractions isolated from this parasite.

Hydrolase secretion is a consequence of membrane recycling

Acanthamoeba releases lysosomal hydrolases continuously into the culture medium. This release is specific for lysosomal hydrolases, but not other cellular proteins, and is energy dependent. The secreted hydrolases can be separated into two groups on the basis of their secretion kinetics: one is secreted at approximately 15% of the cellular activity per hour and the other at approximately 5%. Intracellularly the lysosomal hydrolases are restricted almost exclusively to secondary lysosomes where the hydrolases demonstrate a differential pH-dependent binding to membrane. Hydrolase secretion is not the result of secondary lysosomes' fusing with the plasma membrane since soluble and particulate lysosomal contents are not released at the same rate. Together the data suggest that the secreted hydrolases are trapped in shuttle vesicles that cycle membrane from secondary lysosomes to the cell surface. The inner membrane and content of these vesicles undergo a marked pH shift when, following fragmentation from lysosomes, these vesicles fuse with plasma membrane. This rapid pH shift and the differential pH-dependent membrane binding of hydrolases appear to account for the heterogeneous hydrolase secretion kinetics.

Acanthamoeba discriminates internally between digestible and indigestible particles

The capacity of Acanthamoeba to distinguish nutritive yeast particles from non-nutritive plastic beads during phagocytosis was investigated. When cells were allowed to phagocytose yeast to capacity, endocytosis stopped and subsequent presentation of particles (either yeast or beads) did not result in further uptake. By contrast, when cells were allowed to phagocytose plastic beads to capacity and a second dose of particles was presented (either yeast or beads), the cells exocytosed the internal particles and took up new ones. Yeast rendered indigestible by extensive chemical cross-linking were taken up at rates similar to those of untreated yeast, but, like beads, they were exocytosed when a second dose of particles was presented. The results show that an internal distinction is made between vacuoles containing yeast and vacuoles containing plastic beads, and they are consistent with the hypothesis that the presence within the vacuoles of material capable of being digested prevents exocytosis.

Growth phase dependent alterations in the surface coat of Acanthamoeba castellanii

Application of ruthenium red, cationized ferritin and concanavalin A to exponentially growing trophozoites reveals on their plasma membrane negatively charged surface coat bearing sugar residues. In the coat of trophozoites from advanced stationary growth phase no sugar residues can be visualized. In mature cysts the external layer of their wall is negatively charged, however, on their protoplast surface no terminals reacting with the 2 polycations, or with concanavalin A can be revealed, even though the penetration of the reagents has been ensured by enzymatic impairing of the cyst wall. The results are confronted with the known facts concerning alterations of physiological properties of plasma membrane occurring during the life cycle of Acanthamoeba.

Morphometric analysis of volumes and surface areas in membrane compartments during endocytosis in Acanthamoeba

Stereologic analysis was made of cell surface membrane (PM) and two interrelated cytoplasmic membrane systems, the vacuole membranes (VM) and small vesicle membranes (SVM). Volumes and surface areas of the three membrane compartments were measured during steady-state pinocytosis, when membrane recycling is rapid, and during phagocytosis, when a shift to a lower rate of membrane uptake by endocytosis occurs (B. Bowers, 1977, Exp. Cell Res. 110:409). Total membrane area in the three compartments was 3.2 micrometers 2/micrometers 3 of protoplasmic volume and was constant throughout the experiments. In pinocytosing cells, 32% of the membrane was in the PM, 25% in the vM, and 43% in the SVM. The vacuole compartment occupies approximately 20% of the total cell volume, and the small vesicle, approximately 3%. As the endocytic uptake of membrane from the surface decreased, there was an increase in PM area and a marked decrease in SVM area. The VM area remained constant even though "empty" vacuoles were almost completely replaced by newly formed phagosomes within 45 min. This demonstrates directly a rapid flux of membrane though this compartment. A model, taking into consideration these and other data on Acanthamoeba, is proposed to account for the observed membrane shifts. The data suggest that the vacuolar (digestive) system of Acanthamoeba is central to cellular control of endocytosis and membrane recycling.

In vitro fusion of Acanthamoeba phagolysosomes. III. Evidence that cyclic nucleotides and vacuole subpopulations respectively control the rate and the extent of vacuole fusion in Acanthamoeba homogenates

Fusion of phagolysosomes has been previously demonstrated to occur during the incubation of phagolysosome-containing homogenates of Acanthamoeba (Oates and Touster, 1978, J. Cell Biol. 79:217-234). Further studies on this system have shown that methylxanthines (0.2 mM) and/or cAMP (0.5-1 mM) markedly accelerate the average rate, but not the extent, of the in vitro phagolysosome fusion process. Adenosine, 5'-AMP, and ADP (0.5-1 mM) were without effect. ATP (0.5-1 mM) caused variable stimulation, whereas beta, gamma-methylene-ATP (1 mM) caused pronounced inhibition, as did GTP (1 mM) and cGMP (1 mM). Stimulation by 3-isobutyl-1-methylxanthine was blocked by GTP, but not by ATP or cAMP. These results indicate that the rate of phagolysosome fusion in Acanthamoeba homogenates may be regulated by cyclic nucleotides, with enhancement of the fusion rate by cAMP and inhibition of the rate by cGMP. The extent of the reaction increased spontaneously and markedly during the first few hours after preparation of the homogenates. This activation appears to be because of a slow conversion of a significant fraction of the vacuole population from a fusion-incompetent to a fusion-competent, cyclic nucleotide-sensitive state.

A morphological study of plasma and phagosome membranes during endocytosis in Acanthamoeba

Particle ingestion by Acanthamoeba is rapid. Within 40 s bound particles can be surrounded by pseudopods, brought into the cytoplasm, and released as phagosomes into the cytoplasmic stream. In electron micrographs the phagosome appears as a flasklike invagination of the surface. Separation from the surface occurs by fragmentation of the attenuated "neck+ of the invagination. The separated phagosome membrane has a three- to fourfold greater density of intramembrane particles than the plasma membrane from which it derives. This change is evident within 15 min of ingestion and is detectable while the membrane is still tightly apposed to the particle. There is no direct evidence for the mechanism of this increase; no increase in particle density was seen in the membrane at an early stage in the forming phagosomes still connected to the surface. These morphological observations are consistent with chemical analyses, to be reported in a separate communication, that show that the phagosome membrane has a higher protein to phospholipid ratio and a higher glycosphingolipid content than the plasma membrane. Enlarged phagosomes (presumptive phagolysosomes) show multiple small vesiculations of characteristic morphology. The small vesicles are postulated to be the major route of membrane return to the cell surface.

Morphometric and cytochemical studies of Dictyostelium discoideum in vegetative phase. Digestive system and membrane turnover

The morphometric analysis of growing cells shows that the membranes of the digestive apparatus have a surface area equal to the cell surface area. After yeast phagocytosis, the surface area of the membrane surrounding the ingested yeast is equal to 40% of the surface area of the cell membrane. In spite of this internalization, the cell surface remains constant. Its renewal is insured by the translocation of the membrane of the digestive system, the surface area that concomitantly decreases by 40%. This means that the influx of plasma membrane is continually compensated for by the same outflow of internal membranes. During this turnover, the characteristic polysaccharide stainability (two different stains were used) of the plasma membrane is maintained after internalization, at the level of the digestive system, despite the presence of hydrolases in the digestive vacuoles. The cytochemical demonstration of acid phosphatase shows that this enzyme penetrates into phagosomes by fusion between phagosomes and vacloles of various sizes. The debris of digested yeast are released into the culture medium after 2 h. This process of defecation is accompanied by the appearance of new pinocytotic vacuoles, which indicates that the uptake of axenic medium has resumed. A model of membrane turnover is proposed to explain these observations.