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

The exocytic gene secA is required for Dictyostelium cell motility and osmoregulation

We investigated the link between cell movement and plasma membrane recycling using a fast-acting, temperature-sensitive mutant of the Dictyostelium SecA exocytic protein. Strikingly, most mutant cells become almost paralysed within minutes at the restrictive temperature. However, they can still sense cyclic-AMP (cAMP) gradients and polymerise actin up-gradient, but form only abortive pseudopodia, which cannot expand. They also relay a cAMP signal normally, suggesting that cAMP is released by a non-exocytic mechanism. To investigate why SecA is required for motility, we examined membrane trafficking in the mutant. Plasma membrane circulation is rapidly inhibited at the restrictive temperature and the cells acquire a prominent vesicle. Organelle-specific markers show that this is an undischarged contractile vacuole, and we found the cells are correspondingly osmo-sensitive. Electron microscopy shows that many smaller vesicles, probably originating from the plasma membrane, also accumulate at the restrictive temperature. Consistent with this, the surface area of mutant cells shrinks. We suggest that SecA mutant cells cannot move at the restrictive temperature because their block in exocytosis results in a net uptake of plasma membrane, reducing its area, and so restricting pseudopodial expansion. This demonstrates the importance of proper surface area regulation in cell movement.

Vacuole membrane protein 1 is an endoplasmic reticulum protein required for organelle biogenesis, protein secretion, and development

Vacuole membrane protein 1 (Vmp1) is membrane protein of unknown molecular function that has been associated with pancreatitis and cancer. The social amoeba Dictyostelium discoideum has a vmp1-related gene that we identified previously in a functional genomic study. Loss-of-function of this gene leads to a severe phenotype that compromises Dictyostelium growth and development. The expression of mammalian Vmp1 in a vmp1(-) Dictyostelium mutant complemented the phenotype, suggesting a functional conservation of the protein among evolutionarily distant species and highlights Dictyostelium as a valid experimental system to address the function of this gene. Dictyostelium Vmp1 is an endoplasmic reticulum protein necessary for the integrity of this organelle. Cells deficient in Vmp1 display pleiotropic defects in the secretory pathway and organelle biogenesis. The contractile vacuole, which is necessary to survive under hypoosmotic conditions, is not functional in the mutant. The structure of the Golgi apparatus, the function of the endocytic pathway and conventional protein secretion are also affected in these cells. Transmission electron microscopy of vmp1(-) cells showed the accumulation of autophagic features that suggests a role of Vmp1 in macroautophagy. In addition to these defects observed at the vegetative stage, the onset of multicellular development and early developmental gene expression are also compromised.

Morphology and dynamics of the endocytic pathway in Dictyostelium discoideum

Dictyostelium discoideum is a genetically and biochemically tractable social amoeba belonging to the crown group of eukaryotes. It performs some of the tasks characteristic of a leukocyte such as chemotactic motility, macropinocytosis, and phagocytosis that are not performed by other model organisms or are difficult to study. D. discoideum is becoming a popular system to study molecular mechanisms of endocytosis, but the morphological characterization of the organelles along this pathway and the comparison with equivalent and/or different organelles in animal cells and yeasts were lagging. Herein, we used a combination of evanescent wave microscopy and electron microscopy of rapidly frozen samples to visualize primary endocytic vesicles, vesicular-tubular structures of the early and late endo-lysosomal system, such as multivesicular bodies, and the specialized secretory lysosomes. In addition, we present biochemical and morphological evidence for the existence of a micropinocytic pathway, which contributes to the uptake of membrane along side macropinocytosis, which is the major fluid phase uptake process. This complex endosomal compartment underwent continuous cycles of tubulation/vesiculation as well as homo- and heterotypic fusions, in a way reminiscent of mechanisms and structures documented in leukocytes. Finally, egestion of fluid phase from the secretory lysosomes was directly observed.

Membrane sorting in the endocytic and phagocytic pathway of Dictyostelium discoideum

To study sorting in the endocytic pathway of a phagocytic and macropinocytic cell, monoclonal antibodies to membrane proteins of Dictyostelium discoideum were generated. Whereas the p25 protein was localized to the cell surface, p80 was mostly present in intracellular endocytic compartments as observed by immunofluorescence as well as immunoelectron microscopy analysis. The p80 gene was identified and encodes a membrane protein presumably involved in copper transport. Expression of chimeric proteins revealed that the cytoplasmic domain of p80 was sufficient to cause constitutive endocytosis and localization of the protein to endocytic compartments. Dileucine- and tyrosine-based endocytic signals described previously in mammalian systems were also capable of targeting chimera to endocytic compartments. In phagocytosing cells no membrane sorting was observed during formation of the phagosome. Both p25 and p80 were incorporated non-selectively in nascent phagosomes, and then retrieved shortly after phagosome closure. Our results emphasize the fact that very active membrane traffic takes place in phagocytic and macropinocytic cells. This is coupled with precise membrane sorting to maintain the specific composition of endocytic compartments.

On the evolutionary conservation of the cell death pathway: mitochondrial release of an apoptosis-inducing factor during Dictyostelium discoideum cell death

Mitochondria play a pivotal role in apoptosis in multicellular organisms by releasing apoptogenic factors such as cytochrome c that activate the caspases effector pathway, and apoptosis-inducing factor (AIF) that is involved in a caspase-independent cell death pathway. Here we report that cell death in the single-celled organism Dictyostelium discoideum involves early disruption of mitochondrial transmembrane potential (DeltaPsim) that precedes the induction of several apoptosis-like features, including exposure of the phosphatidyl residues at the external surface of the plasma membrane, an intense vacuolization, a fragmentation of DNA into large fragments, an autophagy, and the release of apoptotic corpses that are engulfed by neighboring cells. We have cloned a Dictyostelium homolog of mammalian AIF that is localized into mitochondria and is translocated from the mitochondria to the cytoplasm and the nucleus after the onset of cell death. Cytoplasmic extracts from dying Dictyostelium cells trigger the breakdown of isolated mammalian and Dictyostelium nuclei in a cell-free system, and this process is inhibited by a polyclonal antibody specific for Dictyostelium discoideum apoptosis-inducing factor (DdAIF), suggesting that DdAIF is involved in DNA degradation during Dictyostelium cell death. Our findings indicate that the cell death pathway in Dictyostelium involves mitochondria and an AIF homolog, suggesting the evolutionary conservation of at least part of the cell death pathway in unicellular and multicellular organisms.

Inhibition of multicellular development switches cell death of Dictyostelium discoideum towards mammalian-like unicellular apoptosis

The multicellular development of the single celled eukaryote Dictyostelium discoideum is induced by starvation and consists of initial aggregation of the isolated amoebae, followed by their differentiation into viable spores and dead stalk cells. These stalk cells retain their structural integrity inside a stalk tube that support the spores in the fruiting body. Terminal differentiation into stalk cells has been shown to share several features with programmed cell death (Cornillon et al. (1994), J. Cell Sci. 107, 2691-2704). Here we report that, in the absence of aggregation and differentiation, D. discoideum can undergo another form of programmed cell death that closely resembles apoptosis of most mammalian cells, involves loss of mitochondrial transmembrane potential, phosphatidylserine surface exposure, and engulfment of dying cells by neighboring D. discoideum cells. This death has been studied by various techniques (light microscopy and scanning or transmission electron microscopy, flow cytometry, DNA electrophoresis), in two different conditions inhibiting D. discoideum multicellular development. The first one, corresponding to an induced unicellular cell death, was obtained by starving the cells in a "conditioned" cell-free buffer, prepared by previous starvation of another D. discoideum cell population in potassium phosphate buffer (pH 6.8). The second one, corresponding to death of D. discoideum after axenic growth in suspension, was obtained by keeping stationary cells in their culture medium. In both cases of these unicellular-specific cell deaths, microscopy revealed morphological features known as hallmarks of apoptosis for higher eukaryotic cells and apoptosis was further corroborated by flow cytometry. The occurrence in D. discoideum of programmed cell death with two different phenotypes, depending on its multicellular or unicellular status, is further discussed.

A new quantitative fluorimetric assay for phagocytosis of bacteria

We describe a new quantitative fluorimetric assay for phagocytosis of bacteria. A suspension of fluorescein-labelled bacteria (Micrococcus lysodeikticus) is mixed and incubated with phagocytes. After fixation with paraformaldehyde, the excess non-phagocytosed and adsorbed bacteria are lysed with a solution of lysozyme in phosphate-buffered saline. After washing of the phagocytes, the fluorescence of those that have ingested the labelled bacteria is measured with a spectrofluorimeter. We report results obtained with different types of phagocytes which show that this method allows sensitivity, saturation and kinetic studies and the calculation of a phagocytic index.

Dictyostelium myosin I double mutants exhibit conditional defects in pinocytosis

The functional relationship between three Dictyostelium myosin Is, myoA, myoB, and myoC, has been examined through the creation of double mutants. Two double mutants, myoA-/B- and myoB-/C-, exhibit similar conditional defects in fluid-phase pinocytosis. Double mutants grown in suspension culture are significantly impaired in their ability to take in nutrients from the medium, whereas they are almost indistinguishable from wild-type and single mutant strains when grown on a surface. The double mutants are also found to internalize gp126, a 116-kD membrane protein, at a slower rate than either the wild-type or single mutant cells. Ultrastructural analysis reveals that both double mutants possess numerous small vesicles, in contrast to the wild-type or myosin I single mutants that exhibit several large, clear vacuoles. The alterations in fluid and membrane internalization in the suspension-grown double mutants, coupled with the altered vesicular profile, suggest that these cells may be compromised during the early stages of pinocytosis, a process that has been proposed to occur via actin-based cytoskeletal rearrangements. Scanning electron microscopy and rhodamine-phalloidin staining indicates that the myosin I double mutants appear to extend a larger number of actin-filled structures, such as filopodia and crowns, than wild-type cells. Rhodamine-phalloidin staining of the F-actin cytoskeleton of these suspension-grown cells also reveals that the double mutant cells are delayed in the rearrangement of cortical actin-rich structures upon adhesion to a substrate. We propose that myoA, myoB, and myoC play roles in controlling F-actin filled membrane projections that are required for pinosome internalization in suspension.

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.

Developing Dictyostelium cells contain the lysosomal enzyme alpha-mannosidase in a secretory granule

The prespore vesicle (PSV) is an organelle which secretes spore coat proteins and gal/galNAc polysaccharides from prespore cells of Dictyostelium. By combining the techniques of protein A-gold immunocytochemistry and ricin-gold affinity cytochemistry we have demonstrated colocalization of the lysosomal enzyme alpha-mannosidase with gal/galNAc polysaccharides in prespore vesicles and the spore coat. To determine the origin of prespore vesicles a series of pulse-chase experiments were performed. Cells were labeled with [35S]methionine or [35S]sulfate at different times during development and allowed to differentiate in the presence of unlabeled methionine or sulfate for various periods of time. The cells were homogenized and intracellular organelles were separated using Percoll density gradient centrifugation. The distribution of [35S]methionine-labeled alpha-mannosidase and [35S]sulfate-labeled glycoproteins in the Percoll gradients was determined. It was found that prespore vesicles contained protein which was previously found in lysosomes. Newly labeled protein also entered these vesicles. The data suggest that developing Dictyostelium cells either restructure preexisting lysosomes into prespore vesicles or transport protein between these two organelles. We propose that secretory granules and lysosomes may have a common biosynthetic origin and may be evolutionarily related.

Identification of Dictyostelium discoideum plasma membrane proteins by cell surface labeling and quantitative two-dimensional gel electrophoresis

Plasma membrane proteins of the cellular slime mold Dictyostelium discoideum were characterized by two-dimensional polyacrylamide gel electrophoresis using a variety of labeling techniques and a microcomputer-based videodensitometer. Algorithms for the determination of molecular weights and isoelectric points were developed to aid in the comparison of polypeptides from different autoradiographs, Coomassie blue-stained gels, and Western blots. Cell homogenates were compared to plasma membranes isolated by a silica density perturbation technique and to cytoskeletons obtained by nonionic detergent extraction. Plasma membrane proteins were distinguished from subcellular contaminants by lactoperoxidase-catalyzed radioiodination, by selective labeling with N-hydroxysuccinimidyl-2-iminobiotin, and by quantitatively determining the enrichments of individual polypeptides from gels of plasma membrane proteins relative to their counterparts in gels of total cell lysate proteins. In contrast to defining plasma membrane purity by measuring a representative marker enzyme activity, the quantitative two-dimensional gel analysis strategy presented allowed for a rigorous evaluation of the enrichments of all detectable polypeptides in the subcellular fraction. Quantitative two-dimensional gel analysis avoided problems encountered with marker enzyme activation or inhibition during subcellular fractionation as enrichments were based solely on polypeptide amounts. It was also capable of identifying a wider spectrum of plasma membrane proteins than any of the labeling techniques employed in this study. A high resolution two-dimensional gel catalog was generated containing information about plasma membrane protein orientation in the bilayer, association with the cytoskeleton, phosphorylation state, glycosylation state, copy number, isoelectric point, and molecular weight.

Prelysosomal acidic vacuoles in Dictyostelium discoideum

We have examined the ameba Dictyostelium discoideum for evidence of a discrete, prelysosomal, acidic receiving compartment in endocytosis. We observed in the cytoplasm abundant round vacuoles with diameters up to 2 microns that concentrated acridine orange by a process inhibited by 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl). They were therefore taken to be acidic. The vacuoles were observed to fuse nearly quantitatively with primary phagosomes over 30 min and thereby to confer upon them the ability to accumulate acridine orange. The entry into lysosomes of phagocytic cargo occurred later. In the absence of phagocytosis, almost all of the acidic vacuoles rapidly accumulated fluorescent markers that had either been covalently coupled to the cell surface or fed as the soluble dextran conjugate. Therefore, these vacuoles also lie on the pathway of pinocytosis. A prominent subcellular ATPase activity inhibited by 25 microM NBD-Cl co-distributed on sucrose equilibrium density gradients with vacuoles capable of concentrating acridine orange in vitro. The peak was broad and more buoyant than that bearing lysosomal acid hydrolases, which contained only a minor amount of this ATPase. Also migrating in the buoyant peak were internalized plasma membrane markers; e.g., 3H-galactose had been covalently coupled to the surface of intact cells and allowed to enter pinosomes. We conclude that in D. discoideum an extensive prelysosomal vacuolar compartment provides the proton pumps that acidify both phagosomes and pinosomes.

The axenic mutations and endocytosis in Dictyostelium

The axenic mutations of Dictyostelium offer a unique opportunity to explore the relationship between phagocytosis and pinocytosis and to examine the mechanism by which a cell shifts from one mode of feeding to the other. The axenic mutations also provide a means of exploring the relationships between endocytosis and other forms of cell motility. This chapter has described the known mutations that affect axenic growth, methods for culturing wild-type and axenic cells and measuring their growth, and methods for monitoring the effects of the axenic mutations on endocytosis and cell movement. The importance has been emphasized of distinguishing effects of the axenic genotype that are expressed constitutively (i.e., during growth on either bacteria or liquid medium) from those that are a function of axenic growth conditions. The methods described in this chapter, applied to wild-type cells and to cells carrying a full complement of the axenic mutations, have shown that the axenic mutations have constitutive effects on cell-substratum interactions, and inducible effects on cell locomotion and pinocytosis.

Intracellular pH control in Dictyostelium discoideum: a 31P-NMR analysis

Phosphorus metabolites and intracellular pH have been examined in the slime mold Dictyostelium discoideum by non-destructive 31P-NMR measurements. In a spectrum from a suspension of aerobic amoebae, the major peaks are inorganic phosphate, nucleotide di- and triphosphates. In the corresponding perchloric acid extract, resonances originating from purine and pyrimidine nucleotides are resolved. Adenine nucleotides are the most abundant components, but the other nucleotides are present in significant amounts. In a spectrum from intact spores in a dormant state, only inorganic phosphate and polyphosphates are detected and nucleotides are no longer present in large amounts. Of particular importance is the ability to observe separately in aerobic amoebae the resonance of inorganic phosphate localized in two different cell compartments: the cytosol and the mitochondria. The cytosolic pH and mitochondrial pH have been measured as 6.7 and 7.7, respectively, on the basis of intracellular inorganic phosphate chemical shifts. They are essentially unaffected over a large range of external pH and they are not modified transiently or permanently during the initiation of the developmental program of the organism. A weak acid, such as propionate, which modifies the progression of differentiation by favoring prestalk cells, perturbs intracellular pH gradients by selectively decreasing mitochondrial pH without any effect on cytosolic pH.

Kinetics of fluid-phase pinocytosis in Dictyostelium discoideum amoebae

Kinetics of pinocytosis in Dictyostelium discoideum were investigated over an extended period of time (up to 6 hours) using fluorescein isothiocyanate (FITC)-dextran as a fluid-phase marker. FITC-dextran added to the medium accumulated rapidly inside the cells with a rate of influx equivalent to 9 microns3 of fluid/cell x min. After a period of about 90 min of uptake, the intracellular FITC-dextran level reached a plateau which corresponded to a strict balance between pinocytosis and exocytosis as shown both by efflux measurements and pulse experiments with (3H) dextran. At equilibrium, the amount of internalized marker reached a value equivalent to 790 microns3 of fluid taken up per amoeba, i.e. a volume paradoxically higher than the total aqueous space of the cell (520 microns3 ). FITC-dextran was thus markedly concentrated intracellularly. The endocytic compartment in which the intracellular FITC-dextran was concentrated could be completely washed out when FITC-dextran was removed from the external medium.

Effect of the amino acid analog hadacidin on intracellular membrane flow and the cell surface in Dictyostelium discoideum. A transmission- and scanning-electron-microscope study

We examined the effect of the amino acid analog hadacidin (N-formyl-N-hydroxy glycine) on the process of endocytosis in the slime mold Dictyostelium discoideum. Endocytosis was followed using iron-dextran and transmission electron microscopy. In cells taken from the mid-log growth stage, iron-dextran was found to be distributed in small, medium, and large vesicles at a density lower than that present in the incubation medium, thus suggesting the fusion of small, iron-dextran-containing pinosomal vesicles with intracellular vesicles not containing iron-dextran. In cells treated with hadacidin, more small vesicles were present than in untreated cells, there being a reduction in the number of larger-sized vesicles; in these vesicles, iron-dextran was present at a density similar to that of the medium. This result is consistent with the conclusion that, while pinocytosis had continued, the fusion of vesicles and dilution of the vesicle contents had been inhibited. Also, the large number of small pinosomal vesicles in the drug-treated cells suggested that the recycling of vesicles to the surface had been inhibited. The observation that pinocytosis but not recycling continued after drug treatment raised the question of the origin of the membrane needed for the formation of pinosomes. Measurements of the cell surface revealed no difference between drug-treated and untreated cells, indicating that, when the membrane was internalized for pinosomes, the cell size remained constant.(ABSTRACT TRUNCATED AT 250 WORDS)

31P-nuclear magnetic resonance analysis of the intracellular pH in the slime mold Dictyostelium discoideum

Amoebae of the slime mold D. discoideum were studied by phosphorus nuclear magnetic resonance. Under aerobic conditions, major intracellular phosphate compounds included phosphomonoesters, inorganic phosphate (Pi), ADP and ATP. Nucleotides were essentially as magnesium complexes. Two intracellular Pi resonances were clearly resolved and the corresponding pHs determined by the chemical shifts characteristics were 7.7 and 6.7. These intracellular pHs were strictly constant over an extracellular pH range between 5.0 and 7.5. The two cellular compartments defined by the Pi resonances were assigned to mitochondria (pH 7.7) and cytosol (pH 6.7) on the basis of their response to anaerobiosis or to carbonylcyanide-m-chloro phenylhydrazone (CCCP), an uncoupler of oxidative phosphorylation, which equilibrate the two intracellular pHs.

Quantification of endocytosis-derived membrane traffic

The main data covered by this article have been summarized in Table I. A fairly uniform picture is obtained for endocytosis-derived membrane transfer and compartmentation. This may be due to the limited amount of information and the resulting low resolution. Data on mainly three cell types are presented: macrophages, fibroblasts and amoebae. The data vary as much for one cell type as between different cells. Therefore, no possible differences related to cell function emerge. More detailed data, for more cell types, may change the picture. The values for cell surface area, although significantly different in absolute terms (column S in Table I), are rather similar when related to cell diameter, all being about 3-fold in excess of the surface area of the smooth sphere of comparable volume (column xi in Table I). The rate of plasma membrane internalization for macrophages and amoebae both professional phagocytes, is about 2 cell surface area equivalents per h or more. This may be somewhat higher than for fibroblasts (column PM/h in Table I). The average residence time for membrane on the cell surface, therefore, is about 30 min. A most interesting finding seems to be the rather uniform values obtained for the average size (volume weighted) of primary pinosomes, being about 0.3 micron in diameter (column phi-Internalization in Table I). Due to their rapid increase in size as a result of fusion (cf. Fig. 2), it has not been feasible to directly measure the size of primary pinosomes by morphometric means. The values in Table I, give no information on the size distributions of primary pinosomes and on whether these consist of one or more size classes. The steady-state average diameter of pinosomes is noticeably larger than that of primary pinosomes (column phi-pinosomes in Table I; cf. Table II for Acanthamoebae). The corresponding decrease in surface-to-volume ratio can make about 50% of pinosomal membrane available for recycling directly from this membrane compartment. Membrane recycling from the pinosomal compartment occurs after an average residence time of about 3 min for macrophages and 4-6 min for fibroblasts (column tau-pinosomes in Table I). The relative pool size of intracellular membranes participating in shuttling to and from the cell surface is significantly different for animal cells and amoebae (column rho in Table I). For macrophages, fibroblasts, CHO cells, and mast cells, this intracellular membrane pool amounts to about 10-20% the plasma membrane area, compared to 150-200% in the case of amoebae.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Concurrent disappearance of N-acylethanolamine glycerophospholipids and phagolysosomes enriched in N-acylethanolamine glycerophospholipids as Dictyostelium discoideum cells aggregate

As the cellular slime mold, Dictyostelium discoideum, undergoes development, a phospholipid fraction containing 80% N-acylethanolamine glycerophospholipids (NAEGPs) and 20% acylphosphatidylglycerol (APG) disappears during the aggregation stage. In this study, the subcellular distribution of that NAEGP phospholipid fraction and the precise time period of disappearance of the fraction were determined. The content of the NAEGP fraction was determined in aggregating cells at 2-h intervals from the beginning of the developmental phase through 14 h, when the cells were completely aggregated. The NAEGP fraction comprised about 8% of the phospholipids in amoebae just starting the development cycle and about 12% in cells between 2 and 6 h of development; then its level decreased until it could not be detected at 12 and 14 h of development. The mole percentage of the total lipid phosphate in the NAEGP fraction was determined in isolated subcellular organelles. The phagolysosomes were enriched in the NAEGP fraction 1.7-2-fold over the level found in the amoebae and about 8-fold over the level in fractions highly enriched in the plasma membrane, mitochondria or peroxisomes. The content of phagolysosomes was determined by electron microscopy of aggregating cells. The amoebae contained large amounts of phagolysosomes up to 6 h of development, and then they gradually disappeared between 6 and 12 h of development. This combination of quantitative phospholipid analysis, subcellular organelle isolation and electron microscopy has revealed that in D. discoideum amoebae, the phagolysosomes were selectively enriched in the NAEGP fraction and both the NAEGP-enriched phagolysosomes and the NAEGPs disappeared concurrently between 6 and 12 h of development.

Relationship between ultrastructure and specific functions of macrophages

The main function of the macrophages, which is to ingest and degrade any foreign molecules or particles penetrating the organism, appears in the development of the different structures implicated in endocytic activity. The macrophage's high endocytic property first appears in its irregular shape and the large number of extensions of the cell membrane, allowing the rapid capture of extra-cellular material. Adhesion between macrophage cell surface and molecules or particles is greatly enhanced by the presence of varied kinds of receptors: lectin-like receptors which bind specific sugars or highly specific receptors such as Fc and C3b receptors, which increase phagocytosis of opsonized microbes. The microbicidal properties reside in part in the production of superoxide anions which result from the activity of a NAD(P)H oxidase. This enzyme is located in the plasma membrane. Its activity could be demonstrated with a cytochemical method, on the cell surface and along the phagosome membrane. It is, however, very weak in resident macrophages and increases after stimulation or activation. The second kind of bactericidal property corresponds to cationic proteins located in lysosomes. After fusion between lysosomes and phagosomes, they contribute to microbe killing by permeabilizing microbe envelopes. Lysosomes, which contain diverse acid hydrolases and are responsible for the degradation of ingested material, play a crucial role in macrophage endocytic activity. Their number increases in parallel with endocytic activity during macrophage differentiation and is particularly high after ingestion of degradable material. Contrary to polymorphonuclear leukocytes, macrophage is very poor in granules containing peroxidase. The latter, which are rather abundant in monocytes, disappear during macrophage maturation. They do not seem thus to be implicated in macrophage microbicidal activity. Endocytosis is accompanied by rapid and intense exchanges between the different membrane compartments of the cell (plasma membrane, pinosomes or phagosomes, endosomes, lysosomes, Golgi apparatus, etc.). These exchanges seem to occur by transitory fusions between vesicles coming from different compartments, rapidly followed by their recycling to their original compartment. This system of membrane shuttle has been clearly observed after formation of phagosomes or pinosomes in which the internalized plasma membrane is recycled back to the cell surface within a few minutes after their formation. This membrane traffic is especially intense in macrophages, the endocytic activity of which is very high, but it also exists in all cell types.(ABSTRACT TRUNCATED AT 400 WORDS)

Biochemical surface components of Brugia pahangi microfilariae

The sheath and cuticle of microfilariae of Brugia pahangi were examined by electron microscopy and the presence of various proteins, carbohydrate and enzymes sought. The epicuticle of microfilariae consists of a pentalaminate structure (24.0 +/- 1.4 nm), a cortex (13.7 +/- 3.6 nm) and a basal zone (27.8 +/- 4.8 nm) which is often banded in appearance. The pentalaminate layers are not continuous at the base of the interannular grooves. The sheath and the epicuticle of B. pahangi stained positively with concanavalin A and saccharated iron oxide. The sheath of approximately 50% of microfilariae showed activity for acid phosphatase, 5' nucleotidase and peroxidase, but not for ATPases, alkaline phosphatase or esterase. No enzymes were detected in the epicuticle although the cortex and basal layers of the cuticle did show enzymic activity. Structures beneath the cuticle in the main body of the worms contained considerable enzymic activity. Microfilariae directly isolated from the blood of infected cats were found by immunochemical means to carry serum proteins on their sheaths but not on their cuticles. These studies extend the definition of the outer structures of microfilariae and confirm that they significantly differ in morphology and enzyme content from typical mammalian cell membranes.

Morphological changes and depressed phagocytic efficiency in Dictyostelium amoebae treated with toxic concentrations of cadmium

The morphology and phagocytic efficiency of Dictyostelium discoideum amoebae exposed to cadmium was investigated at two Cd concentrations: a low toxic concentration--7 X 10(-5) M, and a high toxic concentration--2 X 10(-4) M. Both concentrations inhibited growth completely; however, only in the culture containing a high toxic concentration of cadmium were severe ultrastructural anomalies observed, notably, nucleolar changes and autophagic vacuolar formation. Using biological indices we conclude that the high concentration of cadmium was lethal and that morphological changes associated with this dose of cadmium may be secondary to cell death. In contrast, amoebae treated with a low toxic but nonlethal concentration of Cd showed an altered size distribution of cytoplasmic vacuoles and a decreased phagocytic efficiency. Cultures whose growth was completely inhibited with cobalt were also examined, as were untreated control cultures. By 24 hr Cd-treated amoebae showed a 20% decrease in the cytoplasmic mean-vacuolar diameter and a 69% decrease in phagocytic efficiency whereas Co and untreated controls showed no significant decrease in the cytoplasmic mean-vacuolar diameter. Phagocytic efficiency was only slightly diminished by Co. Changes in vacuolar profiles had been shown earlier to be related to membrane utilization in Dictyostelium amoebae. Cd at low toxic concentrations affects membrane function in Dictyostelium amoebae.

Cytochemical study of the nucleolus of the slime mold Dictyostelium discoideum

The nucleus of the slime mold Dictyostelium discoideum is characterized by the presence of several large dense masses which are all in tight contact with the nuclear membrane. These dense masses, considered as nucleoli, present a rather homogeneous texture, in which dense chromatin, fibrillar, and granular material are not easily detected. The autoradiographic study of [3H]uridine pulse-labeled cells showed that the majority of the silver grains were located inside these masses. The use of EDTA regressive-staining, acetylation and enzymatic digestion indicated that they are mostly composed of RNP and are totally devoid of dense chromatin as the rest of the nucleus is. After treatment with actinomycin D, fibrillar and granular material segregated but no chromatin could be found. All these observations confirmed that the dense masses correspond to nucleoli despite their peculiar ultrastructure. It can also be concluded that this type of nucleoli cannot be considered as a taxonomic character of the slime molds because it does not exist in all slime molds and was observed in some dinoflagellates, and ascomycetes.

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.

Internalization and recycling of plasma membrane glycoconjugates during pinocytosis in the macrophage cell line, P388D1. Kinetic evidence for compartmentation of internalized membranes

An analysis was made of the pinocytosis-derived internalization and recycling of membrane in the macrophage cell line, P388D1. Plasma membrane glycoconjugates, reversibly labelled with [3H]galactose, were used as a membrane marker. Label internalized with the plasma membrane was no longer accessible to release by externally added beta-galactosidase and could therefore be distinguished quantitatively from label remaining on the cell surface. Direct experimental evidence for membrane recycling was obtained by demonstrating that previously internalized label reappeared at the cell surface. The composition of labelled membrane glycoconjugates, as analysed by SDS-polyacrylamide gel electrophoresis, remained unaltered before and after internalization. The label remained membrane-bound in an unmodified way during the entire period of 8 h investigated, corresponding to about twenty-four cycles of membrane flow. Membrane flow led to a steady-state distribution of label between the plasma membrane and intracellular membranes. The redistribution of label occurred with biphasic kinetics, which could be described as the sum of two exponential functions. This behavior is explained by presenting a model of membrane flow between the plasma membrane and two consecutive intracellular membrane compartments, which we assume to consist of pinosomal membranes and of pinosome-derived membrane of secondary lysosomes. The relative membrane surface areas turn out to be in the ratio of 100:12.5:7.3, respectively. At the observed rate of pinocytosis, the equivalent of the plasma membrane is internalized once every 21 min, in the form of primary pinosomes of the size 0.24 micrometer. The residence time of membranes in the pinosome compartment is about 3 min. The rate at which membranes enter the lysosomal compartment is 31 times lower than the rate of membrane internalization. We conclude that only 3% of the amount of membrane internalized at any one time subsequently enters the secondary lysosome compartment. After a residence time of 49 min this membrane fraction is finally recycled to the cell surface. The results are discussed in terms of mixing and sorting-out of pinosomal and lysosomal membranes.

Direct transfer of coliphage lambda DNA from Escherichia coli to cellular slime mold Dictyostelium discoideum

Dictyostelium discoideum myxamoebae were cultured with Escherichia coli cells infected with lambda phage in the presence of chloramphenicol. After eliminating the uningested bacteria by repeated centrifugation in a Percoll gradient, we examined the myxamoeba cytoplasm (not the food vacuole) for the presence of phage DNA. A significant amount of DNA extracted from the myxamoebae was hybridizable with purified phage lambda DNA, and capable of forming phage particles when packaged in vitro with phage lambda proteins. The EcoRI restriction maps of the phages recovered from the plaques were identical to that of the infecting phage. These results strongly suggest that phage DNA molecules were taken up by the cellular slime mold cells and that at least some fraction existed in intact form.

Inhibition of a nutrient-dependent pinocytosis in Dictyostelium discoideum by the amino acid analogue hadacidin

In the present study we examine the effects of the drug hadacidin (N-formyl-N- hydroxyglycine) on pinocytosis in the eukaryotic microorganism dictyostelium discoideum. At concentrations of up to approximately 8 mg/ml, hadacidin inhibited the rate of pinocytosis of fluorescein isothiocyanate (FITC) dextran in cells in growth medium in a concentration-dependent manner but had no effect on cells in starvation medium. Because hadacidin also inhibits cellular proliferation at this concentration, the relationship between growth rate and pinocytosis was studied further using another drug, cerulenin, to produce growth-arrest. These experiments showed no changes in the rate pinocytosis even after complete cessation of cellular proliferation. Other studies showed that the transfer of cells from growth to starvation medium reduced the rate of pinocytosis by approximately 50 percent. A reduction of similar magnitude occurred if cells were transferred from growth to starvation medium containing hadacidin. Also, no additional reduction in pinocytosis occurred when cells that had been treated with hadacidin were transferred to starvation medium containing hadacidin. These cells were able to take up [(14)C]hadacidin in the starvation medium. In contrast to the results with hadacidin-treated cells, cells in a cerulenin-induced state of growth-arrest when transferred to starvation medium exhibited the same 50 percent reduction in pinocytosis observed in cells not previously exposed to either drug. Cells treated with azide, in either growth or starvation medium, exhibited an immediate inhibition of all pinocytotic activity. After the transfer of log-phase cells to starvation medium supplemented with glucose, the reduction in rate was only approximately 10-15 percent. In contrast, a 50 percent reduction was observed after supplementation of starvation medium with sucrose, KCl, or concanavalin A. Maintaining the cells in growth medium containing hadacidin for as long as 16 h had no effect on the rate at which cells aggregated. These results are consistent with the conclusion that D. discoideum exhibits two types of pinocytotic activity: one that is nutrient dependent and the other independent of nutrients. This latter activity persists in starvation medium and is unaffected by hadacidin, whereas the nutrient-dependent activity is present in growth medium and is inhibited by hadacidin.

Purification of a high-affinity discoidin I-binding proteoglycan from axenic Dictyostelium discoideum growth medium

The axenic Dictyostelium discoideum growth medium HL-5, prepared using Difco proteose peptone No. 2, contains an extremely potent inhibitor of the binding of 125I-labeled discoidin I to glutaraldehyde-fixed, cohesive D. discoideum cells. Axenic strain A3 D. discoideum cells bind or internalize the inhibitor during growth in HL-5 medium and subsequently shed or excrete it while differentiating in suspension. The inhibitor has been purified from Difco proteose peptone No. 2 by sequential gel filtration on Sepharose 4B and affinity adsorption using discoidin I-Sepharose. The inhibitor is heterogeneous in molecular weight (4 . 10(5)--2 . 10(6)), but is relatively homogeneous in density on CsCl density gradients. The size and activity of the inhibitor are resistant to periodate, reduction and maleylation, proteases, nucleases and heating in the absence or presence of sodium dodecyl sulfate. Mild alkali causes a partial reduction in activity and converts the higher molecular weight fraction of the inhibitor to a lower molecular weight. The purified inhibitor contains neutral hexose, hexosamine and amino acid in an approximate molar ratio of 4 : 3 : 2. These and other properties suggest that the inhibitor is an unusual proteoglycan. Certain well-characterized glycosaminoglycans are relatively potent inhibitors of discoidin I binding. The proteoglycan reported here is the most potent discoidin I-binding inhibitor ever identified.

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.

Non-specific binding by macrophages: existence of different adhesive mechanisms and modulation by metabolic inhibitors

Rat peritoneal cells were made to bind test particles of five different species: immunoglobulin-coated sheep red cells (IGSRC), glutaraldehyde-treated sheep red cells (GSRC), leishmania, latex beads and tumour cells. The dependence of binding on various physicochemical parameters was studied: the binding of latex or leishmania resisted cold (4 degrees), azide, cytochalasin B, ethyleneglycol and dimethylsulphoxide (DMSO). The binding of IGSRC resisted cold and azide, but it was inhibited by cytochalasin B, ethyleneglycol and DMSO. The binding of GSRC was inhibited by cold, azide and ethyleneglycol, but not by cytochalasin B and DMSO. The binding of tumour cells was inhibited by azide, cytochalasin B, ethyleneglycol and DMSO. An attempt was made to saturate selectively some adhesive sites of macrophage membranes: glutaraldehyde-treated bovine albumin (GBSA) inhibited the ingestion of latex and GSRC, not leishmania and IGSRC, whereas a crude leishmania extract (CLE) inhibited the ingestion of all tested particles except latex. Antigen-antibody complexes inhibited the ingestion of IGSRC and leishmania, not latex and GSRC. Rat macrophages were made to bind radio-iodinated GBSA (GIBSA). The uptake of glutaraldehyde-treated albumin was proportional to the amount of substrate the cells were incubated with over a wide concentration range. This uptake was not a result of endocytosis, and it was far more efficient than that of peroxidase. Macrophage-particle interaction was studied with electron microscopy. The binding of IGSRC and leishmania to macrophages involved large areas where the interacting membranes were separated by a low density gap of constant width. The interaction of GSRC and latex with macrophages was much more patchy and irregular. Further, no redistribution of the macrophage surface polysaccharides seemed associated with the binding of GSRC. It was concluded that several different mechanisms and different membrane adhesive structures are involved in non-specific recognition by macrophages. Further, non-specific binding sometimes requires an active cell participation. Several testable hypotheses are described, which suggest further experiments in order to obtain a fuller insight into the mechanism of rosette formation.

Surface labeling of membrane glycoproteins and their drastic changes during development of Dictyostelium discoideum

Surface glycoproteins on plasma membranes from Dictyostelium discoideum were labeled by sodium metaperiodate oxidation and sodium boro[3H]hydride reduction. The amount of incorporation of tritium from NaB3H4 reached a plateau after 10 min at a periodate concentration of 20 mM. The density analysis carried out by sucrose density-gradient centrifugation showed that the plasma membranes were selectively labeled by this technique. About 84% of the radioactivity incorporated was released by hydrolysis with 0.25 M H2SO4 for 3 h at 100 degrees C. The released materials were eluted at a bed volume after chromatography using a Sephadex G-50 column. From the paper chromatographic analysis of the eluate, four radioactive spots were detected. Two of them were glycerol and glyceraldehyde and the other two spots seemed to be oligosaccharides. Using the above method, the plasma membranes from aggregation-phase cells were labeled four times more than those from growth-phase cells. The labeled plasma membrane fraction during the aggregation phase was separated into at least 39 distinct glycoprotein bands on a one-dimensional dodecylsulfate/polyacrylamide gel. Six of the 39 bands increased markedly in density and two new bands appeared. In contrast, four bands decreased in density in the aggregation phase. Using this method, the surface glycoproteins can be analyzed directly be gel electrophoresis of the lysate of labeled whole cells without preparing the plasma membranes. Changes during development of glycoproteins on outer cell surfaces were also confirmed by O'Farrell's method of two-dimensional polyacrylamide gel electrophoresis. Utilizing this technique, glycoproteins on plasma membranes of D. discoideum were separated into 63 individual spots; 45 of these 63 spots changed during the early developmental course of D. discoideum. This is in contrast to the slight change in the soluble and membrane proteins during this phase. This fact also suggests that the glycoproteins have important roles in the process of aggregation.

Kinetics of membrane internalization and recycling during pinocytosis in Dictyostelium discoideum

Internalization and recycling of plasma membrane during pinocytosis in Dictyostelium discoideum was analyzed quantitatively. A labeling technique was used by which [3H]galactose could be enzymatically bound to and released from the plasma membrane. Label internalized with the plasma membrane was no longer accessible to enzymatic release and could therefore be distinguished quantitatively from label remaining on the cell surface. Internalization of labeled membrane components was measured as a function of pinocytotic uptake. Direct experimental evidence for membrane recycling was obtained by demonstrating that previously internalized label reappeared at the plasma membrane. The experimental data agree with a kinetic model requiring that a shuttle of membrane between two membrane compartments leads to the same surface concentration of label in both. The two compartments consist of the plasma membrane and of cytoplasmic vacuolar membranes; their relative membrane surface areas are 1 and 0.5, respectively. One surface area equivalent of the plasma membrane is internalized during a pinocytotic uptake amounting to 15% of the cell volume. At the observed rate of pinocytosis, this occurred once every 45 min. The average size of the primary pinosomes, as weighted according to their contribution to pinocytotic uptake, was calculated to be about 0.6 microns.

Putrescine uptake by the cellular slime mould dictyostelium discoideum

1. Rapid labelling occurs when myxamoebae of Dictyostelium discoideum strain AX2 are incubated with [1,4-14C]putrescine. Labelling is energy-dependent. 2. The label enters a pool from which rapid exchange with extracellular putrescine does not occur, and labelling is believed to represent uptake into the cells. 3. The concentration-dependence of putrescine uptake indicates that a number of systems are involved, at least one of which is saturable, with a Km of 9.1 micro M-putrescine. At high putrescine concentrations the overall uptake process is non-saturable. 4. Significant metabolism of putrescine and loss of intracellular putrescine to the medium only occurred when cells were incubated with millimolar concentrations of extracellular putrescine. 5. Putrescine uptake was inhibited by diamines, polyamines, bivalent metal ions and omega-aminocarboxylic acids. 6. The ability to take up putrescine at low concentrations decreased during starvation of myxamoebae. 7. The results are interpreted in terms of a model for putrescine uptake involving adsorptive pinocytosis at low concentrations and fluid-phase pinocytosis at high concentrations.

Peptidoglycan turnover during growth of a Bacillus megaterium Dap- Lys- mutant

The aim of this study was to ascertain whether or not the absence of cell wall growth zones, deduced from the analysis of autoradiographs of DL-[3H]mesodiaminopimelic acid pulse-labeled cells of a Dap- Lys- mutant of Bacillus megaterium, was due to a high peptidoglycan turnover. Turnover was determined in very precise experimental conditions because two kinds of turnover occurred: a low, acid-soluble turnover and a high, acid-insoluble one. The latter was detected during a chase in the culture medium when bacteria were centrifuged before treatment with trichloroacetic acid. Otherwise the acid-insoluble released material precipitated with the bacteria. In the electron microscope this material presented a globular structure and contained both peptidoglycan and teichoic acid. The acid-insoluble turnover was mainly produced by a lytic acitivity that was released into the culture medium. This thermolabile activity was not due to cell lysis. It was implicated in septum cleavage and in the detachment of wall fragments from the cell surface, but did not seem indispensable for cell elongation. The acid-soluble turnover was much weaker and seemed to be indispensable for cell elongation.

Changes of the cell surface and of the digestive apparatus of Dictyostelium discoideum during the staruation period triggering aggregation

The effects of starvation on the cell morphology of Dictyostelium discoideum were studied with different cytochemical techniques, and with a morphometric method by which the surface areas of the cell membrane and of the digestive system can be determined. During the first 2 h, the cell membrane becomes very wrinkled and many phagocytic cups and filopods are formed. These changes are in accord with the 40 percent increase in the cell surface area to cytoplasmic volume ratio observed, which is mainly due to a strong decrease in the cytoplasmic volume. At this time of starvation, cells are able to ingest twice as many yeast as during growth. Afterwards, while the phagocytic ability decreases, the phagocytic cups disappear, and all the cells become bristled with many thin filopods. In spite of these morphological changes, no quantitative or topological differences have been observed concerning the polysaccharide content of the plasma membrane, whether it was stained with phosphotungstic acid, silver proteinate, or ruthenium red. During this time, the digestive vacuoles imbricate one into the other. Part of the vacuoles are degraded by this process, thus leading to an atrophy of the digestive apparatus. The digestive apparatus is progressively replaced by an autophagic system. Polysaccharide stainings and morphological observations show that the cytosegresomes seem to originate from the food vacuoles which flatten and sequester portions of cytoplasm. After 5 h of starvation, the digestive system is entirely transformed into an autophagic apparatus. The cell population appears to be homogeneous with respect to these changes. Therefore, potential precursors of prestalk and prespore cells were not observed.