Destruction of Leishmania mexicana amazonensis amastigotes within macrophages in culture by phenazine methosulfate and other electron carriers.

Exposure of macrophages infected with Leishmania mexicana amazonensis to phenazine methosulfate (PMS) resulted in rapid damage and disappearance of the intracellular amastigotes without obvious ill effects to the host cells. The reduction of the percent infection was related to the concentration of PMS and to the duration of the pulse. Most Leishmania disappeared within 2 h of a 2-h pulse with 10 muM of the drug. In contrast, pretreatment of the macrophages with PMS followed by removal of the drug before infection did not result in disappearance of the parasites. The pH of the PMS medium markedly influenced the disappearance of Leishmania: maximum effect was observed at pH 8.0, while the effect was negligible at pH 6.3. The pH effect may be related to pseudobase formation by the PMS cation. Dose-response curves for PMS were similar for resident, elicited, or activated macrophages. Observations by time-lapse cinemicrography documented the explosion-like fragmentation of the amastigotes within 1-2 h of exposure of infected macrophages to the drug. Parasite-derived granules and vacuoles were seen to scatter within the parasitophorous vacuoles. This early damage to the parasites was confirmed by transmission electron microscopic observations. Infected macrophages incubated with PMS displayed detectable vacuolar fluorescence, indicating that PMS or a metabolite of PMS had access to the vacuoles. A series of other electron carriers, including phenyl methanes, phenazines, oxazines, a xanthene, and a naphthoquinone, given continuously for 18 h, also induced the disappearance of the Leishmania. The most potent was crystal violet, active at 70 nM. The presence of apolar substituents enhanced activity and this is probably related to increased permeation of the dyes. Finally, PMS, as well as other electron carriers examined, also reduced the growth of Leishmania promastigotes in culture. The results are compatible with a direct effect of the drugs on the intracellular amastigotes, involving only a permissive participation of the macrophages. We propose that the diverse agents destroy the amastigotes by redox-cycling generation of active oxygen metabolites at or near the parasites. Alternatively, the effect of the drugs could be mediated by toxic free radical reduction species of the drugs or by interference with electron flow or with the intermediary metabolism of Leishmania.

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.

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.

Quantitative studies on the localization of the cholinergic receptor protein in the normal and denervated electroplaque from Electrophorus electricus.

Electroplaques dissected from the electric organ of Electrophorus electricus are labeled by tritiated alpha1-isotoxin from Naja nigricollis, a highly selective reagent of the cholinergic (nicotinic) receptor site. Preincubation of the cell with an excess of unlabeled alpha-toxin and with a covalent affinity reagent or labeling in the presence of 10(-4) M decamethonium reduces the binding of [3H]alpha-toxin by at least 75%. Absolute surface densities of alpha-toxin sites are estimated by high-resolution autoradiography on the basis of silver grain distribution and taking into account the complex geopmetry of the cell surface. Binding of [3H]alpha-toxin on the noninnervated face does not differ from background. Labeled sites are observed on the innervated membrane both between the synapses and under the nerve terminals but the density of sites is approx. 100 times higher at the level of the synapses than in between. Analysis of the distance of silver grains from the innervated membrane shows a symmetrical distribution centered on the postsynaptic plasma membrane under the nerve terminal. In extrasynaptic areas, the barycenter of the distribution lies approximately 0.5 micrometer inside the cell, indicating that alpha-toxin sites are present on the membrane of microinvaginations, or caveolae, abundant in the extrajunctional areas. An absolute density of 49,600 +/- 16,000 sites/micrometer2 of postsynaptic membrane is calculated; it is in the range of that found at the crest of the folds at the neuromuscular junction and expected from a close packing of receptor molecules. Electric organs were denervated for periods up to 142 days. Nerve transmission fails after 2 days, and within a week all the nerve terminals disappear and are subsequently replaced by Schwann cell processes, whereas the morphology of the electroplaque remains unaffected. The denervated electroplaque develops some of the electrophysiological changes found with denervated muscles (increases of membrane resting resistance, decrease of electrical excitability) but does not become hypersensitive to cholinergic agonists. Autoradiography of electroplaques dissected from denervated electric organs reveals, after labeling with [3H]alpha-toxin, patches of silver grains with a surface density close to that found in the normal electroplaque. The density of alpha-toxin binding sites in extrasynaptic areas remains close to that observed on innervated cells, confirming that denervation does not cause an increase in the number of cholinergic receptor sites. The patches have the same distribution, shape,and dimensions as in subneural areas of the normal electroplaque, and remnants of nerve terminal or Schwann cells are often found at the level of the patches. They most likely correspond to subsynaptic areas which persist with the same density of [3H]alpha-toxin sites up to 52 days after denervation. In the adult synapse, therefore, the receptor protein exhibits little if any tendency for lateral diffusion.

A deletion that includes the segment coding for the signal peptidase cleavage site delays release of Saccharomyces cerevisiae acid phosphatase from the endoplasmic reticulum.

We studied ultrastructural localization of acid phosphatase in derepressed Saccharomyces cerevisiae cells transformed with a multicopy plasmid carrying either the wild-type PHO5 gene or a PHO5 gene deleted in the region overlapping the signal peptidase cleavage site. Wild-type enzyme was located in the cell wall, as was 50% of the modified protein, which carried high-mannose-sugar chains. The remaining 50% of the protein was active and core glycosylated, and it accumulated in the endoplasmic reticulum cisternae. The signal peptide remained uncleaved in both forms. Cells expressing the modified protein exhibited an exaggerated endoplasmic reticulum with dilated lumen.

Membrane shuttle between plasma membrane, phagosomes, and pinosomes in Dictyostelium discoideum amoeboid cells.

The intracellular redistribution of membrane internalized during endocytosis was studied quantitatively by a biochemical approach and by a morphometric analysis of autoradiographs in electron microscopy. Plasma membrane glycoconjugates, enzymatically labelled with radioactive galactose, were used as a membrane marker. In cells labelled at their surface either before or after the phagocytotic uptake of latex beads, subsequent endocytosis led to a redistribution of label between the plasma membrane and endosomal membranes until a steady-state was reached after about 1 h with 43% of the label on the plasma membrane. The steady-state resulted when all participating membranes carried the same surface density of label. During phagocytosis or pinocytosis the equivalent of the plasma membrane was internalized and recycled once every 20 min or 40 min, respectively. Compared to this rate a very rapid and complete mixing of membranes was observed between newly formed phagosomes and preexisting digestive vacuoles or between newly formed pinosomes and preexisting phagosomes. Due to this rapid mixing, the membranes enclosing undigestible latex beads remained fully linked to the shuttle of membrane to and from the cell surface.

Exchange kinetics and composition of endocytic membranes in terms of plasma membrane constituents: a morphometric study in macrophages.

Intracellular membrane traffic, during endocytosis in mouse bone marrow-derived macrophages, was studied quantitatively by morphometric and kinetic analysis. Three functionally different markers were used: Horseradish peroxidase (HRP) served as a fluid-phase (FP) marker (1000 micrograms HRP/ml in the presence of mannan) or as a receptor-mediated (RM) membrane marker (25 micrograms HRP/ml) and, third, plasma membrane (PM) glycoconjugates, enzymatically labeled with [3H]galactose at the cell surface, served as a covalent membrane marker. The cell surface was labeled with [3H]galactose, followed by either FP or by RM uptake of HRP. The kinetics of the intracellular appearance of the markers were measured as the membrane area stained by HRP-reaction product and as the number of autoradiographic grains associated with these membranes. The following compartments were distinguished: PM, coated vesicles (VI), pinosomes or endosomes (VII), secondary lysosomes (VIII), and HRP-negative vesicles (EV). Tubular structures of VII became labeled with HRP only during RM uptake. The markers flowed first into VI and VII, and after 5 min into VIII. EV became labeled with the covalent membrane marker starting from 5 min. The ratio of autoradiographic grain number to HRP-stained membrane area remained constant with time although substantially different for the various compartments, viz. 100% (VI), 50% (VII and EV) and 30% (VIII) as compared to the PM (100%). This indicated that endosomes were only partially derived from internalized PM and that secondary lysosomes contained a substantial pool of PM constituents. The observed kinetics suggested that once every 30 to 40 min the entire PM was internalized, the bulk of which was recycled after 4 min from a prelysosomal compartment(s) leaving only 12 to 20% for recycling via membranes of secondary lysosomes after a residence time of 24 to 33 min.

Endocytic membrane traffic with respect to phagosomes in macrophages infected with non-pathogenic bacteria: phagosomal membrane acquires the same composition as lysosomal membrane.

A morphometric analysis was made to study membrane traffic in bone marrow-derived macrophages, containing phagosomes with partially degraded Bacillus subtilis. Cell surface glycoproteins, labeled with radioactive galactose by terminal glycosylation, provided a covalent autoradiographic membrane marker. Membrane compartments were characterized in terms of cytochemical staining for horseradish peroxidase taken up by receptor-mediated endocytosis. The area, composition, and exchange rates of endocytic membrane compartments were measured as in a previous analysis for non-infected macrophages, devoid of phagosomes. In direct comparison with this earlier study, the present data allowed an assessment of the involvement of phagosomes in the interactions between endocytic membrane compartments. The presence of phagosomes led to a 30% reduction of lysosomal membrane area. The rate at which cell surface-derived label flowed into the lysosomal membrane pool was reduced by the same fractional amount. This suggested a linear relationship between flow rate and membrane area. The initial flow rate of label into phagosomes was higher than expected, based on their membrane area being only about 60% that of lysosomes. This rate could only be measured during the early phase of the experiments when phagosomes were younger, therefore displaying a fast exchange rate, reminiscent of the endosome compartment. However, steady-state conditions, at late times, strongly suggested that phagosomes with degraded contents finally acquire membrane of lysosomal origin. First, the composition of phagosome membrane became the same as that of lysosomes, remaining unchanged as compared to non-infected cells. Second, the membrane area of phagosomes amounted to the loss of lysosomal membrane area in infected cells.

Modified lysosomal compartment as carrier of slowly and non-degradable tracers in macrophages.

A previous immunocytochemical study of macrophages infected with Bacillus subtilis showed that a cell wall antigen could be detected for several days in a population of small vesicles randomly distributed within the cells and apparently distinct from perinuclear lysosomes. These observations suggested the possibility that these vesicles might constitute a "storage" compartment for non-degradable compounds. In the present report we compared in pulse-chase experiments the location and fate of a series of degradable and non-degradable pinocytic tracers within the macrophages. The tracers, detected by fluorescent microscopy, were bovine serum albumin (BSA), hen egg ovalbumin (OVA), horseradish peroxidase (HRP). Lucifer Yellow, fluorescent dextran, and levan. BSA and OVA remained located in perinuclear lysosomes during the chase period until their disappearance occurring within 3 h. In contrast, the other tracers, although initially located in perinuclear lysosomes, were found after a 3 to 5-h chase in small vesicles homogeneously distributed in the macrophage cytoplasm where they remained visible for 2 to 3 days. The use of markers for different cell organelles indicated that these dispersed vesicles exhibited several of the lysosomal features. They were acidic, they contained the 100 kDa and the 120 kDa lysosomal proteins as well as some acid proteases albeit these markers were in lesser concentrations than in the perinuclear lysosomal compartment. The addition of bacteria to the macrophages previously loaded with fluorescent dextran showed that all dispersed vesicles have the same fusion property as lysosomes and that slowly degraded or non-degradable tracers turn over through the perinuclear lysosomal compartment by using the endocytic pathway. Measurement of the release of some of the tracers into the culture medium suggested that the "dispersed vesicles" were probably not implicated in exocytosis of the tracers.

Heterologous protein export in Escherichia coli: influence of bacterial signal peptides on the export of human interleukin 1 beta.

Expression plasmids carrying the coding sequence of mature human interleukin 1 beta (IL 1 beta) linked either to a Met start codon, or fused to different efficient Escherichia coli secretion signal sequences, have been constructed. In the latter case, we used signal peptides derived either from an outer membrane protein (OmpA) or from a periplasmic protein (PhoA). The synthesis of IL1 beta from these fusions was investigated in an otherwise strictly isogenic context using identical conditions of derepression and culture media. The Met-IL1 beta fusion produced a soluble cytoplasmic protein which could be released from the cells by osmotic shock whereas the OmpA and PhoA fusions were always insoluble. The extent of sOmpA-IL1 beta maturation was found to vary from 50 to 100%, mainly depending on the medium used, whereas no significant maturation of the signal peptide could be detected in the case of the sPhoA-IL1 beta fusion. Immuno-electron microscopy revealed that the sOmpA-IL1 beta fusion was targeted to the inner membrane, whereas the sPhoA-IL1 beta fusion remained within the cytoplasm and thus did not appear to enter the secretion pathway. Amplifying the E. coli signal peptidase lep gene on a multicopy plasmid did not improve signal peptide removal from sOmpA-IL1 beta. Moreover, these E. coli secretion vectors allowed us to produce, in high levels, IL1 beta fragments which otherwise could not be stably accumulated within the cytoplasmic compartment.

HIV-1 infection of lung alveolar fibroblasts and macrophages in humans.

We have studied the infected cell populations in the lungs of four human immunodeficiency virus type 1 (HIV-1) seropositive patients suffering from lymphocytic alveolitis or lymphocytic interstitial pneumonitis. Adherent cells were obtained by bronchoalveolar lavage (BAL) and were analyzed by various technical approaches. The cells considered here were alveolar macrophages and fibroblasts, and could be clearly identified morphologically and by the expression of specific cell-surface markers using monoclonal antibodies. The presence of HIV-1 in both of these cell types was established by serological, virological, and molecular procedures. Our results show that alveolar macrophages and fibroblasts are naturally infected in the lungs of HIV+ patients. Both cell types express the CD4 receptor molecule, in contrast to skin fibroblasts which are negative. Alveolar macrophages and fibroblasts thus may act as eventual HIV-1 reservoirs in vivo, and are probably involved in the induction of inflammatory reactions because they are targets for CD8 cytotoxic T lymphocytes (CTL).

Immunolabelling of Shiga toxin in macrophages infected with Shigella dysenteriae 1.

Immunolabelling of Shiga toxin in macrophages infected with a non-invasive Shigella dysenteriae 1 isolate showed that bacteria remained alive for 3 h after ingestion within the phagocytic vacuole and synthesized Shiga toxin. The normal process of toxin secretion was, however, impaired by the phagosomal environment and toxin molecules accumulated within the bacterial cytoplasm.

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)