Anionic sites on the envelope ofSalmonella typhimurium mapped with cationized ferritin

Binding of either ferritin (F) or cationized ferritin (CF) was employed to indicate the surface charge of the envelope of mainly twoSalmonella typhimurium strains (395 MR10, a Rd-mutant, and LT2-M1, a UDP-galactose-4-epimerase-less mutant). Lowering the pH from 7 to 4 decreased binding of CF, but increased binding of F. At low concentrations, the distribution of CF onS. typhimurium 395 MR10 was in general random, with individual ferritin molecules often forming clusters of two or three particles. At ionic strengths of 0.25M NaCl, ferritin produced distinctive, larger clusters at relatively few sites (10–50/cell). Addition of galactose to cultures of growingS. typhimurium, LT2-M1 reduced the binding of CF in 1–10 min, and numerous ferritinfree areas became visible. Possibly this is caused by a pluri-focal reduction in the negative cell surface charge that was generated at the multiple sites of export of new, smooth-type lipopolysaccharide, which either exhibits lesser charge or masks a preexisting surface charge. Dividing cells may show unequal charges on the prospective daughter cells, and the difference in the capacity for ferritin adsorption of both daughter cells is sharply separated at the division site.     

Internalization of cationized ferritin receptors by rat hepatoma ascites cells.

Cationized ferritin (CF) was used to label the cell surface anionic sites of Chang rat hepatoma ascites cells. If the hepatoma cells were fixed with glutaraldehyde and treated with CF, the label was distributed evenly over the external surface of the plasma membrane. Treatment of unfixed ascites cells with CF yielded clusters of ferritin particles separated by label-free areas of the plasma membrane. Some unfixed ascites cells were treated firstly with CF, then incubated in veronal buffered saline at 37 °C for 10, 20, 30 and 45 min, subsequently fixed in glutaraldehyde and re-exposed to CF. After 10 min of incubation, the label was arranged into large clusters with the remaining areas of the plasma membrane lightly labelled with CF. At 20 min, only clusters of ferritin were present on the plasma membrane; the remaining area of the cell surface was totally free of label. The ability of the plasma membrane to bind additional CF was completely restored after 45 min of incubation. These results suggest that for some period of time after internalization of CF label on cell surface the plasma membrane is devoid of any detectable negative charge.     

Radiation-induced changes of negative charge on the cell surface of primary human fibroblasts

By binding cationized ferritin (CF) to the plasma membrane of primary human fibroblasts, the amount and topology of negatively charged sites on cell surfaces were studied after X-irradiation. The CF binding was tested both on fixed and unfixed cells. Using various enzymes, the chemical nature of sites carrying the negative charges on cell surfaces was investigated. The results suggest that in unirradiated fibroblasts the CF binding occurred in a polarized manner, i.e. the particles were localized mainly on the apical surface of cells and formed clusters. The thin cytoplasmic protrusions and cell-to-cell contact sites bound CF to a greater extent than the bleb-like formations. Enzymatic digestion of surface polysaccharides showed that the main carriers of negatively charged sites are the glycosaminoglycans associated with the cell surface. The fixation of cells with glutaraldehyde did not influence the topology of CF binding either before or after the enzymatic treatment. After X-irradiation with 2.5 Gy the topology of CF binding did not change but the CF coverage of cells as well as the amount of ferritin particles per unit of surface area decreased within 10 min. The changes proved to be reversible as the values reached the pre-irradiation level by 1 h after irradiation.     

Lateral mobility of negative charge sites at the surface of sheep erythrocytes

Neuraminidase-sensitive negative charge sites on sheep red blood cells (SRBCs) are uniformly distributed over the cell surface, as in other species. Unlike most other species in which charge sites are immobile, however, in intact RBCs interaction of SRBCs with cationized ferritin (CF) induces clustering (i.e. patching) of CF-binding sites. This clustering is both time- and temperature-dependent. The clustering of negative charge sites results in the formation of domains up to 1 000 Å across which are totally free of CF binding sites. The unusually high degree of lateral mobility of ionogenic groups at the SRBC surface may contribute to the species specificity of E rosetting.     

Redistribution of surface anionic sites on the luminal front of blood vessel endothelium after interaction with polycationic ligand

The ability of anionic groups on the luminal surface of blood vessels to redistribute by lateral migration under the influence of multivalent ligands was analyzed by electron microscopy, using cationized ferritin (CF). In vitro interaction of blood vessel segments with CF results in rapid aggregation of most anionic sites on the luminal fromt of the endothelium, followed by internalization or detachment of the CF patches, leaving most of the luminal surface devoid of anionic sites. Further incubation of such endothelial cells without CF results in regeneration of binding capacity for the polycationic label. Transport of CF, but not of native ferritin, across the endothelium by vesicle transport, followed by exocytosis of the interiorized CF clusters on the tissue front of the endothelium, was also observed. The possibility that such activities in the blood vessels in vivo may be associated with local changes in the normal distribution of the surface anionic sites as well as in accumulation of debris in the subendothelial layers of the vessels is suggested.     

Regeneration of plasmalemma and surface properties in macrophages

The regeneration of surface anionic groups in mouse peritoneal macrophages was investigated by electron microscopy, using cationized ferritin (CF) as a tool for the localization and evaluation of negative charge density on the cell surface. In vitro interaction of living macrophages with CF resulted in removal of most anionic groups, either by concentration of their receptor sites to a part of the membrane which is subsequently internalized, or by detachment of the aggregated label from the surface. After incubation of macrophages lacking surface anionic groups in tissue culture medium without the ligand, regeneration of the binding capacity for CF took place within 3 h. The first regenerated parts of the membrane can be visualized within 1 h on the upper part of the adherent cells; there is a discontinuous coating of ferritin, with the lateral regions of the plasmalemma free of label. The attached CF particles on the regenerated membrane are closer to the membrane and their density is considerably higher than on the normal control macrophages. The results indicate that the turnover of the plasmalemma is regional and not dispersed; the mechanism involved is insertion of membrane patches into the pre-existing plasma membrane.     

The binding of cationized ferritin at the surfaces of ehrlich ascites tumor cells: the effect of pH and glutaraldehyde fixation.

The densities of cationized ferritin (CF) particles binding to the surfaces of cultured Ehrlich ascites tumor cells were determined at pH 7.4, where the ferritin stain was applied either prior to or following glutaraldehyde fixation. The densities were also determined with CF adjusted to pH 1.9 and applied after fixation. For all fixed samples there was a higher density of particles bound to microvilli than to the spaces between them. Treatment with neuraminidase removed more particles from microvilli than from the inter-microvillus spaces, but did not reduce the levels of binding to the same value. When cationized ferritin is applied prior to fixation, an aggregation of the CF particles at the cell surface was observed, with the internalization of some clusters. This effect was independent of neuraminidase treatment.     

The use of cationized ferritin to measure cell surface charge of mouse bone marrow cells by flow cytometry

We have prepared fluorescein isothiocyanate (FITC) conjugates of cationised ferritin (CF) and have investigated the usefulness of this CF-FITC to measure the negative cell surface charge of mouse bone marrow cells by flow cytometry. CF-FITC conjugates of low fluorochrome to protein ratios (F/P ratio) gave insufficient fluorescence and/or formed large aggregates when stored. CF-FITC conjugates of high F/P ratios (above 25) bound specifically to bone marrow cells, giving sufficient fluorescence, the intensity of which differed for the different cell types. When stored at -20 degrees C the CF-FITC was stable and could be used over prolonged periods. CF-FITC could be used to selectively enrich for pluripotent stem cells (CFU-S) and granulocyte/macrophage progenitors (CFU-C) by fluorescence activated cell sorting (FACS), although the CF-FITC binding to CFU-S and CFU-C was unexpectedly low. No correlation between CF-FITC fluorescence, cell size and electrophoretic mobility (EPM) was observed of bone marrow cells fractionated by free flow electrophoresis. Neuraminidase treatment to remove negatively charged sialic acid groups from the cell surface resulted in an increased binding of CF-FITC, although the EPM was decreased. The biotin conjugate of CF bound to bone marrow cells and could be visualised by avidin-FITC. The relative fluorescence intensity for the individual cell types showed a good correlation with the cell surface charge as determined by the EPM of the different cell types. The mechanism of binding CF-FITC to the cell surface was not by electrostatic interaction of the negative cell surface and positively charged CF because CF-FITC of F/P ratios of above 20 was negatively charged.(ABSTRACT TRUNCATED AT 250 WORDS)     

The distribution of cationized ferritin receptors on ciliated epithelial cells of rat trachea

The interaction of tracheal cilia with the biphasic mucus layer covering the surface of the mammalian respiratory tract may be influenced by many cell surface coat components including those having an overall negative charge. In order to assess the distribution of ciliary anionic sites, cationized ferritin (CF) was used to label the surface of rat tracheal epithelium. If pieces of trachea were fixed with 3% glutaraldehyde and treated with CF at low (L) (0.08 mg/ml), medium (M) (0.32 mg/ml PBS), or high (H) (0.64 mg/ml PBS) concentrations, the label was distributed evenly over the entire external surface of the ciliary membrane at all concentrations. Unfixed tracheal tissue was also treated with L, M, and H CF for 1 or 5 min at 4 degrees C in order to minimize lateral redistribution of CF receptors. To ensure accessibility of the cell surface to CF the samples were agitated thoroughly during exposure. Exposure for 1 min to L, M, and H CF resulted in a light binding of ferritin particles on all portions of the ciliary membrane with occasional areas of multilayered binding distributed randomly on the ciliary shaft. When unfixed trachea was treated with CF for 5 min at 4 degrees C, CF binding was similar except heavier and more uniform. In no instance was there any preferential binding of CF to the ciliary tips at any of the concentrations used. Moreover, as indicated by the CF binding pattern at L concentrations, high density negative charges are present over almost the entire surface of the cilium. These results suggest that, unlike the ciliary membrane of other organs such as oviduct, negatively charged cell surface coat molecules are present on all areas of the ciliary membrane of rat tracheal epithelia.     

Cationized ferritin as a platelet-stimulating surface probe. Binding to platelets and effects on platelet function

Polycationic derivatives of ferritin containing primary amino groups (CFah) or tertiary amino groups (CFdmp) were potent platelet agonists inducing shape change, aggregation and secretion, but also agglutination in the presence of EDTA. Pretreatment of platelets with neuraminidase, PGE1, indomethacin, or creatine kinase/creatine phosphate inhibited CF-induced activation. In contrast, neuraminidase and PGE1 increased the agglutination by CF, indicating an inverse relationship between activation and CF-induced agglutination. At pH 7.4, the cationic charges of CFdmp exceeded those of CFah by a factor of 1.5 and the platelets bound approximately 1.5 times more CFah than CFdmp, suggesting the same number of anionic surface sites for both CF preparations. The capacity of the platelets to bind CF was diminished by 55% at 0 degree C or by 62% after aldehyde fixation and by 13% with PGE1. This suggests that the binding capacity depends on the mobility of the binding sites in the plane of the membrane but is only slightly increased by platelet activation. Binding to fixed or cold platelets approached equilibrium within a few seconds whereas saturation required several minutes at 37 degrees C. Neuraminidase preferentially reduced the slow binding and much less the rapid binding. Since activation by CF developed during seconds, suppressible by a brief treatment with neuraminidase 25 mU/ml, a small portion of neuraminidase-sensitive sites appears to be necessary for CF-induced platelet activation. Full activation and agglutination occurred at CF concentrations far below saturating concentrations. The results show that neither CF-induced activation nor agglutination depend on a simple neutralization of the negative surface charge.     

Response of the resident macrophage to concanavalin A : Alterations of surface morphology and anionic site distribution

We have characterized certain resident guinea-pig peritoneal macrophage surface alterations following treatment with concanavalin A (ConA) and succinyl-ConA (S-ConA). Studies employing scanning electron microscopy (SEM) have demonstrated that ConA, a tetrameric lectin, decreases dramatically the number of macrophage surface folds and ruffles although S-ConA, a dimeric derivative, is apparently not active. However, incubation of S-ConA-treated cells with rabbit anti-ConA (anti-ConA) restored this effect. The decrease in surface folds could not be observed in the presence of α-methyl- -mannoside (αMM), a hapten sugar of ConA. We have performed several receptor-labeling transmission electron microscopy (TEM) studies employing ferritin-conjugated ConA (FT-ConA) and cationized ferritin (CF). These experiments indicate that the ConA receptor-FT-ConA complexes form (1) clusters on the plasmalemma and (2) adsorptive pinocytic vesicles lined with the ferritin label. At the same time scale, we have observed a redistribution of macrophage surface anionic sites following treatment with ConA or S-ConA plus anti-ConA but not S-ConA alone. The redistribution of anionic sites is abolished in the presence of αMM. The specificity of the CF label was checked by pre-incubating cells with poly- -lysine (PLL) or neuraminidase and by employing normal ferritin. These studies provide evidence which support the concept of a directed movement of surface charges during adsorptive pinocytosis. We discuss the possible relevance of this concept with regard to regional alterations of pH at the plasmalemma and the contribution of these anions to the trans-pinosomal pH gradient through the Donnan potential.     

Isolation of a hybrid F' factor-carrying Escherichia coli lactose region and Salmonella typhimurium histidine region, F42-400 (F' ts114 lac+, his+): its partial characterization and behavior in Salmonella typhimurium.

Episome F' ts114 lac+ (F42-114) was transferred into Salmonella typhimurium carrying an F'his+ (FS400) episome, and fused episome F' ts114 lac+, his+ (F42-400) was obtained. Episome F42-400 could be transferred to S. typhimurium, Escherichia coli and Klebsiella pneumoniae. Identification of the episome was based on: (i) temperature sensitivity of the Lac+ and His+ phenotypes; (ii) the fact that F- segregants, obtained after temperature curing or acridine orange curing, were simultaneously Lac- and His-; and (iii) linkage of lac+ with his+ in episomal transfers to E. coli and S. typhimurium. The frequency of episome transfer was influenced by the genotype of the donor. Plasmid LT2, prevalent in S. typhimurium LT2 strains, was suggested to be responsible for the low fertility of S. typhimurium donors. Episome F42-400 was capable of chromosome mobilization, and the extent of chromosome mobilization was not influenced by the presence or absence of the histidine region on the donor chromosome. Growth in a defined medium with acridine orange was able to cure F42-400. The frequency of curing was increased (the frequency of His+ cells was 0.0001%) if the cells were grown at 40 C in the presence of acridine orange. Selection for temperature-resistant Lac+, His+ derivatives in a strain without histidine deletion yielded Hfr strains. However, similar and stronger selections in strains without the chromosomal histidine region failed to yield Hfr strains. Our inability to obtain Hfr's in strains without the chromosomal histidine region was explained by assuming that the episome F42-400 has lost the F sites involved in integration into the S. typhimurium chromosome.     

Cationic ferritin binding sites and surface charge densities of transformed cells

Bioelectric surface properties of the high and low tumor-producing cell lines, NCTC 2472 and NCTC 2555, respectively, were determined by cationic ferritin binding and the electrophoretic mobility of intact cells. Measurements of anionic sites were bases on the number of cationic ferritin particles per 0.01 mu 2 that were electronically tagged and counted by an image analyzer. The average particle count was 45 for the control "high" cells and 34 for the control "low" cells. The surface charge densities, expressed as electrostatic units per cm-2 x 10(-13) were 2.34 and 1.18 at 50 V (2 mA) for the "high" and "low" control cells, respectively. Enzymic cleavage of sialic acid and other carbohydrate moieties resulted in up to an 81% reduction in the charge densities and a 57% reduction of the anionic sites of the "high" cells. The electrophoretic mobility of cells with bound cationic ferritin showed that up to 50% of the exposed anionic sites fail to bind cationic ferritin. Preliminary findings on the particle size/distribution by image analysis showed wide ranges in both particle size and interparticle distances that may limit cationic ferritin binding.     

Measurement of anionic sites on the surfaces of baby hamster kidney cells using radiolabeled polycationic ferritin

A method is described to determine relative numbers of anionic sites on the surfaces of cells under physiological conditions by binding studies with radiolabeled polycationic ferritin. Labeling of cells by polycationic ferritin occurred very rapidly even at 2°C and was essentially complete within 1 min. At 22°C, a rapid initial phase of labeling was followed by a second, slower binding phase. The interaction of rapidly labeled cell surface anionic sites with polycationic ferritin had a binding constant of 3.6 × 10⁶m^?1 (measured at 2°C) and there were about 4 × 10⁶ of these sites per cell.     

The charge distribution in the rough endoplasmic reticulum/golgi complex transitional area investigated by microinjection of charged tracers

The distribution of microinjected ferritin, ranging in charge from anionic to highly cationic, has been used to indicate differences in surface charge on the rough endoplasmic reticulum and the Golgi complex of intact cells. Highly cationic ferritins (HCF)(HCF1, pI 7.9-9.1; HCF2, pI 8.5-9.4; and HCF3.pI 9.5-10.1) were mostly bound and caused swelling of the rough endoplasmic reticulum. Cationic ferritin (CF) (pI 7.0-8.0) and anionic ferritin (AF) (pI 4.0-4.4) caused no changes in morphology. The distribution of these ferritins in the cytoplasmic space varied with their charge. Significantly more CF was bound to surfaces than was found in the free cytoplasmic space. Conversely, there was significantly more AF in the free cytoplasmic space than close to surfaces. Therefore, the intracellular surfaces are negatively charged. Comparison of the structures in the secretory pathway showed no differences in ferritin binding to transition vesicles, rough endoplasmic reticulum, Golgi saccules or secretory vesicles. The Golgi complex beads are not distinguished by their charge. It is therefore unlikely that charge differences play a role in regulating membrane-membrane interactions in this region of the secretory pathway.     

Analysis of murine coronavirus surface glycoprotein functions by using monoclonal antibodies.

The murine coronavirus surface glycoprotein gene was expressed as a fusion protein in bacteria, and the expressed protein was used to generate S protein-specific monoclonal antibodies (MAbs). Three of the MAbs, 11F, 30B, and 10G, were able to neutralize virus infectivity, and two of them, 11F and 10G, were able to block virus-induced, cell-to-cell fusion. The binding sites of the 11F, 30B, and 10G MAbs were determined by Western immunoblotting and epitope mapping. The 11F and 30B MAbs bound to sites located, respectively, between amino acids 33 to 40 and 395 to 406 in the amino-terminal (S1) subunit of the S protein, and the 10G MAb bound to a site located between amino acids 1123 and 1137 in the carboxy-terminal (S2) subunit. These data define more precisely the interactions between the S1 and S2 subunits of the murine coronavirus S protein and provide further insights into its structure and function.     

The use of cationized ferritin to measure cell surface charge of mouse bone marrow cells by flow cytometry

Summary We have prepared fluorescein isothiocyanate (FITC) conjugates of cationised ferritin (CF) and have investigated the usefulness of this CF-FITC to measure the negative cell surface charge of mouse bone marrow cells by flow cytometry. CF-FITC conjugates of low fluorochrome to protein ratios (F/P ratio) gave insufficient fluorescence and/or formed large aggregates when stored. CF-FITC conjugates of high F/P ratios (above 25) bound specifically to bone marrow cells, giving sufficient fluorescence, the intensity of which differed for the different cell types. When stored at –20° C the CF-FITC was stable and could be used over prolonged periods. CF-FITC could be used to selectively enrich for pluripotent stem cells (CFU-S) and granulocyte/macrophage progenitors (CFU-C) by fluorescence activated cell sorting (FACS), although the CF-FITC binding to CFU-S and CFU-C was unexpectedly low. No correlation between CF-FITC fluorescence, cell size and electrophoretic mobility (EMP) was observed of bone marrow cells fractionated by free flow electrophoresis. Neuraminidase treatment to remove negatively charged sialic acid groups from the cell surface resulted in an increased binding of CF-FITC, although the EPM was decreased. The biotin conjugate of CF bound to bone marrow cells and could be visualised by avidin-FITC. The relative fluorescence intensity for the individual cell types showed a good correlation with the cell surface charge as determined by the EPM of the different cell types.The mechanism of binding CF-FITC to the cell surface was not by electrostatic interaction of the negative cell surface and positively charged CF because CF-FITC of F/P ratios of above 20 was negatively charged. This has been shown by theoretical calculations and determination of the pI of CF-FITC by iso-electric focussing. Binding of CF-FITC to the cell surfaces was probably caused by hydrophobic interaction between bound fluorescein molecules and lipid domains in the cell surface membrane aided by some ionic interaction. CF-biotin is still positively charged and is probably bound through electrostatic interactions with negatively charged cell surface groups. The indirect detection of bound CF-biotin with avidin-FITC of high F/P ratio results in a high fluorescence signal, which is a measure of the negative cell surface charge density, in the FACS.In honour of Prof. P. van Duijn     

A simple two-step labeling procedure for ultrastructural localization of cell surface anionic sites

We propose a new method for ultrastructural localization of cell surface anionic sites. The method consists of sequential interaction of aldehyde-fixed cells with a polycationic reagent, poly-L-lysine (PL), followed by secondary interaction with a negatively charged marker, ferritin. By use of PL of low molecular weight (4000) on aldehyde-pre-fixed red blood cells and macrophages, the reaction resulted in binding of ferritin particles to cell surface anionic sites with a density distribution resembling that of cationized ferritin (CF). The density of the attached ferritin molecules increased in direct correlation with the MW of PL used. The primary PL interaction can be carried out at low pH (less than 2), thus restricting the labeling mainly to membrane-bound sialyl residues.     

Prevention by retinoic acid of anionic site redistribution on the surface of cultured human sarcoma cells

The distribution of cell surface negatively-charged macromolecules was determined electron microscopically on untreated and on retinoic acid (RA)-treated cultured human osteosarcoma Hs791 and chondrosarcoma Hs705 cells using cationized ferritin (CF), an electron-dense marker of anionic sites. Labeling on the surface of prefixed cells was continuous and uniform whether they were grown in the absence or presence of RA. In contrast, CF distribution on unfixed cells was markedly affected by RA; CF labeling of untreated cells occurred in patches and clusters whereas the label on RA-treated cells was continuous, as on prefixed cells. CF labeling of unfixed cells decreased considerably after incubation of the cells either with hyaluronidase or neuraminidase. There was also a reduction in patching and clustering. Changes induced by RA in the apparent membrane microviscosity, in neuraminidase-releasable sialic acid, or in transglutaminase activity could not be related to the effect of RA on CF-induced anionic site redistribution since these characteristics were modulated differently in the two cell lines. In contrast, RA increased the sialylation of specific cell surface membrane glycoproteins on both cell types. These results suggest that RA prevents redistribution of cell surface sialoglycoconjugates and glycosaminoglycans by CF. This effect may be the result of increased sialylation of specific surface components and may be related causally to the suppression of the transformed phenotype in the sarcoma cells.     

Cell membrane polarity in primary human fibroblasts

The topologies of bindings of cationized CF and native ferritin (NF) on plasma membranes of primary human fibroblasts were examined by transmission electronmicroscopy. Both ligands bound mainly to apical surfaces and less abundantly to lateral regions. At basal localization they were observed only at cell-to-cell connections. The polarity of negatively charged binding sites was not altered by glutaraldehyde fixation. The definite polarity of plasma membranes of cultured cells express alternating surface areas charged negatively or positively.