Ultrahistochemical study on the ruthenium red surface staining. II. Nature and affinity of the electron dense marker.

The electron-dense marker which is thought to produce the ruthenium red surface staining is studied. This stain is prepared under conditions which should give its rise in cell surface membrane, and its nature and charge are tested electrophoretically and by measuring the turbidity, respectively. It is a positive colloid resulting from the recharging of colloidal osmium dioxide by RR polycations. Controls on the affinity are carried out by applying positive sol to gelled agarose sections containing hyaluronic acid, polyvinyl sulfate or polylysine. Controls are also carried out on ascites Ehrlich carcinoma and Zajdela ascites hepatoma cells subjected to prior enzymatic and chemical treatments. It is found that the osmium-RR system visualizes all acidic groups in the outer hydrophilic leaflet, that is the greater part of compounds in this external cell layer. A model is presented for the mechanism underlying its rise in cell surface membrane.     

Ultrahistochemical study on the ruthenium red surface staining. I. Processes which give rise to electron-dense marker.

The cell coat picture effect which is usually obtained with the conventional RR method, that is with the RR/OsO4 coupled reaction, is investigated. In this first paper, each of conceivable events which might take place between RR, OSO4 and cell surface membrane is discussed or studied. Various tests are carried out on ascites Ehrlich carcinoma cells and Zajdela ascites hepatoma cells treated with numerous chemical reagents, as also on a few pure proteins. The set of data supports the concept that the staining pattern is due to the combination in surface membranes of RR with a "colloidal-like" form of OsO2. The latter might occur during the formation of stable cyclic osmic acid diesters between OsO4 and membrane unsaturated lipids. A possibility by which the resulting marker is though also to be in a "colloidal-like" state is put forward. A next report will deal with this problem.     

Experimentally induced modifications in surface morphology of Ehrlich ascites tumor cells

Observations with scanning electron microscopy /SEM/ were carried out on Ehrlich ascites tumor /EAT/ cells incubated 2 to 4 h at 37 degrees C in hyperosmotic media in the presence and in the absence of serum. It was found that the cells even if maintain spherical shape show significant differences in the architecture of their surface. A need for control observations with SEM of cell surface morphology in biochemical and biophysical research concerning plasma membrane functions and properties is pointed out.     

Negatively charged RNase-susceptible molecules on the surface of ascites tumor cells

RNase-susceptible ionogenic groups on the cell surface membranes of two leukemic and two nonleukemic strains of ascites tumor cells were studied by cell electrophoresis, DEAE-Sephadex A-25 column and paper chromatography, and indirect membrane immunofluorescence. RNase treatment of the nonleukemic ascites tumor cells (Ehrlich ascites tumor and Sarcoma 180) produced a significant reduction in their electrophoretic mobilities. When the cells were labeled with [3H]uridine then incubated with RNase, there was a marked increased in the radioactive nucleotides present in the incubation medium as compared to the results of the experiment with RNase-untreated controls. Indirect membrane immunofluorescence studies of nonleukemic ascites tumor cells suggest that the sites that react with anti-RNA antibody are distributed diffusely on their surfaces. RNase treatment of these cells markedly reduced their ability to react with the antibody. It thus appears that RNAs are present on the surface membrane of nonleukemic ascites tumor cells and that RNase digests these RNAs, removing negatively charged nucleotides from their electrophoretic surfaces. This results in a reduction in mobility. In contrast, leukemic ascites cells (L1210 and C1498) incubated with RNase showed no significant change in mobility or in the amount of nucleotides released into the incubation medium. Moreover, no fluorescence was found on the surface of cells examined by indirect membrane immunofluorescence. This suggests that leukemic ascites cells are devoid of RNAs on their surface.     

Changes in physico-chemical properties of human large intestine tumour cells membrane

Tumour cells produce and excrete to blood many substances which are present in the cell itself in trace amounts only. Our work has been aimed at the determination of changes in electric charge and in phospholipid composition of large intestine normal mucosa and colorectal cancer cells.Surface charge density of tumour unaffected mucosa and of tissue sections from tumours, was measured by electrophoresis. The measurements were carried out at various pH of solution. Membrane isoelectric point was determined by measuring its electric charge in function of pH as well as total positive charge at low pH and total negative charge at high pH. Qualitative and quantitative composition of phospholipids in the membrane was determined by HPLC. Four phospholipid classes were identified: PI, PS, PE and PC and their surface concentrations were determined.The electric charge calculated from phospholipid concentrations is by three orders of magnitude higher than that determined electrophoretically. It indicates that the groups present in the membrane surface are involved in equilibria in which the charge is neutralized.The electric charge calculated from phospholipid concentrations is by three orders of magnitude higher than that determined electrophoretically. It indicates that the groups present in the membrane surface are involved in equilibria in which the charge is neutralized.Tumour changes provoke an increase in surface charge density of large intestine membrane, whereas the content of individual phospholipids increased or decreased depending on a patient.     

Colloidal alpha-stannic acid and negative iron colloid as differential electron stains for surface proteins.

Colloidal alpha-stannic acid and a negative iron colloid obtained from ferric hydroxide and potassium ferrocyanide, both negative sols being stable within a wide pH range, were refined as surface protein electron markers. Because of the relatively small size of its particles, colloidal alpha-stannic acid was used for staining all surface proteins. According to the pH at which the negative iron colloid was applied, it revealed either all surface proteins, or because of its large colloidal particles, stained basic proteins. This differential staining capability of the iron colloidal has been demonstrated previously on various control preparations (Puvion E, Blanquet PR: J Microsc 12:171, 1971). Controls on the affinity of the two colloids to surface amino groups were carried out on rat liver, mouse fibroblasts, HeLa and KB cells, Ehrlich and Zajdela ascites cells subjected to prior enzymatic and chemical treatments (incubation with neuraminidase or phospholipase C, esterification, acetylation or lipid extraction). At any pH below 9, the two sols stained proteins in the outer hydrophilic leaflet of esterified cells with relative selectivity, but the alpha-stannic acid showed them more accurately. The iron sol did reveal at high pH protein components of high isoionic point on the surfaces of rat hepatocytes and ascites cells which had only been treated with neuraminidase.     

The effect of polycations on cell membrane stability and transport processes

Summary The interaction of poly-l-lysines of different molecular weights (PL) with Ehrlich ascites tumor cells was studied experimentally with respect to cell surface binding, cell electrophoresis, cytotoxicity and membrane permeability. Although they decrease the net negative charge of Ehrlich ascites cells similarly at low PL concentrations, low molecular weight PL was less cytotoxic and less damaging to the potassium transport mechanism than was high molecular weight PL. At certain PL concentrations, membrane damage was reversible on reincubation in PL-free media. The amount of bound polylysine as determined with fluorescent labeled polylysine was compared by electrophoresis to the amount of polylysine expressed on the electrokinetic surface. The results indicated that only a small fraction of polylysine bound to Ehrlich ascites tumor cells was electrokinetically detectable. The adsorption of polylysine to Ehrlich ascites tumor cells was not describable by the usual adsorption isotherms. It is suggested that the same number of monomeric lysine units of high and low molecular weight PL are adsorbed at the cell electrokinetic surface, but cytotoxicity is dependent on molecular weight. Although the negative charge of human red blood cells could be reversed at low PL concentrations, no such effect could be observed for ELD (a subline of Ehrlich ascites carcinoma) cells even at high PL concentrations. The relationship of PL binding to the stimulation of macromolecular uptake is discussed.     

Splicing and transport of eukaryotic mRNAs: a theoretical model

Several years have already elapsed since the first discovery of splicing in eukaryotic mRNAs. In this process sections of the precursor mRNAs are spliced out (these are named introns) and the two remaining excised sites, 5′ and 3′ are ligated to form the mature mRNA chains.Very little is known about the splicing and ligation mechanism or about its location inside the cell. It is known to take place in the nucleus, but it is unknown whether it occurs inside the nuclear matter or on the surface of its membrane. Since nearly all eukaryotic messengers undergo splicing, this is a central question.From the theoretical point of view this is an intriguing problem. A lot of data have recently accumulated which have a bearing on this question. Based on current knowledge, this paper proposes a model in which splicing is carried out on the surface of the nuclear membrane and in concert with transport across it. It is suggested that the enzymes that take part in this process are loosely associated with the membrane pore complex. Evidence and results which are relevant to this question are given and discussed.     

Electrokinetic determinations of enzymatic susceptibilities of cell surface-associated RNA

Earlier investigations suggested, using electrokinetic evidence, that RNA is present at the surfaces of some types of cultured and freshly isolated cells. In this report, further investigations of the nature of cell surface RNA of cultured Ehrlich ascites (EAT) cells are reported. These experiments were carried out by determining the changes in electrophoretic mobility of EAT cells after treatment with several highly purified nucleases, neuraminidase, and hyaluronidase. The results suggested that cell surface RNA is located at surface sites separate from those susceptible to neuraminidase and hyaluronidase, that alpha and omega termini of RNA are absent from the electrokinetic surface, and that the RNA present at the cell surface might exist predominantly in a double-stranded form. A model is proposed in which cell surface RNA strand termini are buried out of the electrokinetic surface, but where RNA extends from these buried termini into the electrokinetic surface in loops.     

Changes in the morphology of Ehrlich ascites tumour cells caused by hyperosmotic media

It was found that Ehrlich ascites tumour cells undergo significant morphology changes in media in which osmolarity is increased by NaCl or Hanks' balanced salt solution. The morphology changes include formation of filopodia- and lamellipodia-like cell surface protrusions. Their formation is enhanced by an addition of cytochalasin B. The data obtained suggest that both changes in plasma membrane properties and changes in activity of contractile apparatus participate in the formation of cell surface protrusions.     

Electrokinetic determinations of enzymatic susceptibilities of cell surface-associated RNA

Earlier investigations suggested, using electrokinetic evidence, that RNA is present at the surfaces of some types of cultured and freshly isolated cells. In this report, further investigations of the nature of cell surface RNA of cultured Ehrlich ascites (EAT) cells are reported. These experiments were carried out by determining the changes in electrophoretic mobility of EAT cells after treatment with several highly purified nucleases, neuraminidase, and hyaluronidase. The results suggested that cell surface RNA is located at surface sites separate from those susceptible to neuraminidase and hyaluronidase, that α and ω termini of RNA are absent from the electrokinetic surface, and that the RNA present at the cell surface might exist predominantly in a double-stranded form. A model is proposed in which cell surface RNA strand termini are buried out of the electrokinetic surface, but where RNA extends from these buried termini into the electrokinetic surface in loops.     

Studies on cell surface conformation following injury. II. Scanning and transmission electron microscopy of cell surface changes following anoxic injury in Ehrlich ascites tumor cells.

Exposure of Ehrlich ascites tumor cells to anoxia resulted in rapid and characteristic conformational changes of cell surface topography. Combined scanning and transmission E/M studies revealed rapid alterations including simplification of the cell surface configuration with disappearance of microvilli which were replaced with formation of blebs and recesses at the cell periphery. These surface changes were accompanied by characteristic organelle alterations inside the cells which in this and other cellular systems have been shown to be reversible. Later, the cell surface topography became smoother and monotonic with small blebs and cribriform invaginations in addition to larger eruptions of the cell periphery. Combined transmission E/M studies revealed fragmentation of cellular membrane systems and lysis of organelles indicating the irreversible phase of anoxic injury. The rapid conformational surface changes encountered in Ehrlich ascites tumor cells following anoxia suggest the important role of the plasma membrane and its unfolding as a virtually instantaneous response of the cells to this injury.     

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.     

Ultrahistochemical study on the ruthenium red surface staining

Summary The cell coat picture effect which is usually obtained with the conventional RR method, that is with the RR/OsO₄ coupled reaction, is investigated. In this first paper, each of conceivable events which might take place between RR, OsO₄ and cell surface membrane is discussed or studied. Various tests are carried out on ascites Ehrlich carcinoma cells and Zajdela ascites hepatoma cells treated with numerous chemical reagents, as also on a few pure proteins. The set of data supports the concept that the staining pattern is due to the combination in surface membranes of RR with a colloidal-like form of OsO₂. The latter might occur during the formation of stable cyclic osmic acid diesters between OsO₄ and membrane unsaturated lipids. A possibility by which the resulting marker is though also to be in a colloidal-like state is put forward. A next report will deal with this problem.     

The mechanism of action of cholera toxin in pigeon erythrocyte lysates.

The adenylate cyclase activity of intact pigeon erythrocytes begins to rise after about 20 min of exposure to cholera toxin. The maximum rate at which the cyclase activity increases appears to be limited by the number of toxin molecules which can reach an intracellular target. If the erythrocytes are made permeable to the toxin by a bacterial hemolysin, no such limit exists, and adenylate cyclase activity starts to rise immediately upon the addition of toxin, and continues to rise to a maximum at an initially constant rate which is dependent upon the concentration of toxin. On lysed erythrocytes, the addition of cholera antitoxin immediately prevents any further rise in adenylate cyclase activity, but does not reverse any activation already achieved. Erythrocyte lysates may also be activated by isolated peptide A1 of cholera toxin, although activation of adenylate cyclase of intact erythrocytes requires the complete toxin molecule. In the intact cells, toxin first attaches by its Component B to surface receptors of which there are about 30 per erythrocyte. Subsequently, peptide A1 but not Component B is inserted into the erythrocyte. It takes only about 1 min at 37 degrees for peptide A1 to be sufficiently deep within the cell membrane to be inaccessible to extracellular antitoxin, but its complete transit through the membrane appears to take longer. The surface receptors are used only once, for they remain blocked by Component B. The number of receptors available on the surface may be increased by soaking cells in ganglioside GM1. Cholera toxin also decreases the rate of apparently spontaneous loss of adenylate cyclase activity and increases the response to epinephrine. Theophylline inhibits the action of cholera toxin.     

Receptor-mediated endocytosis: the intracellular journey of transferrin and its receptor

A variety of ligands and macromolecules enter cells by receptor-mediated endocytosis. Ligands bind to their receptors on the cell surface and ligand-receptor complexes are localized in specialized regions of the plasma membrane called coated pits. Coated pits invaginate and give rise to intracellular coated vesicles containing ligand-receptor complexes which are thus internalized. Transferrin, a major serum glycoprotein which transports iron into cells, enters cells by this pathway. It binds to its receptor on the cell surface, transferrin-receptor complexes cluster in coated pits and are internalized in coated vesicles. Coated vesicles then lose their clathrin coat and fuse with endosomes, an organelle with an internal pH of about 5-5.5. Most ligands dissociate from their receptors in endosomes and they finally end up in lysosomes where they are degraded, while their receptors remain bound to membrane structures and recycle to the cell surface. Transferrin has a different fate: in endosomes iron dissociates from transferrin but apotransferrin remains bound to its receptor because of its high affinity for the receptor at acid pH. Apotransferrin thus recycles back to the plasma membrane still bound to its receptor. When the ligand-receptor complex reaches the plasma membrane or a compartment at neutral pH, apotransferrin dissociates from its receptor with a half-life of 18 s because of its low affinity for its receptor at neutral pH. The receptor is then ready for a new cycle of internalization, while apotransferrin enters the circulation, reloads iron in the appropriate organs and is ready for a new cycle of iron transport.     

Possible role of hyaluronectin on cell adhesion in rat histiocytoma.

Distribution of hyaluronectin, a 68-kDa cell surface glycoprotein, has been demonstrated in normal peritoneal, alveolar macrophages as well as in macrophages of the AK-5 tumor cell line. AK-5, a transplantable histiocytic tumor cell line, is a mixture of four different populations and can be grown in both ascites and solid tumors. We are able to demonstrate a differential expression of hyaluronectin on the cell surface of these subpopulations of AK-5 when studied by immunocytochemical staining followed by cytofluorometric analysis. Cell fractions responsible for developing both ascites and solid tumors contain higher amounts of hyaluronectin than fractions which are capable of producing only ascites, suggesting its involvement in solid tumor formation. Furthermore, we established a secretory nature of hyaluronectin as it can be detected in the serum-free medium of AK-5 cells. Since it is localized on the cell surface and secreted into the medium, the cell adhesiveness of hyaluronectin has been examined. Hyaluronectin coating on the plates allowed more cells to attach, which could be specifically blocked by the antibody raised against hyaluronectin, indicating its possible role in cell attachment. The adhesive property of hyaluronectin and its role in tumor formation was further confirmed. The pretreatment of AK-5 cells with hyaluronectin antibody abolished their capacity to grow as solid tumors; however, the cells retained their capacity to grow as ascites tumor. We discuss our observations of hyaluronectin as a cell attachment protein and its specific role on tumor formation.     

MEMBRANE LESIONS IN IMMUNE LYSIS : Surface Rings, Globule Aggregates, and Transient Openings

It is known that there are 100 Å-wide circular structures associated with the erythrocyte membrane in immune lysis. To determine whether these structures were functional holes extending through the membrane, freeze-etch electron microscopy was carried out. Sheep erythrocytes incubated with either rabbit complement or rabbit antibody (anti-sheep erythrocyte antibody) did not hemolyze and did not reveal any abnormalities in freeze-etch or negative-stain electron microscopy. Erythrocytes incubated with both complement and antibody revealed rings on the extracellular surface (etch face) of the cell membrane. Allowing for the 30 Å-thick Pt/C replica, the dimensions of the surface rings were similar to those seen by negative staining. The ring's central depression was level with the plane of the membrane; some rings were closed circles, others were crescent shaped. The cleavage face of the extracellular leaflet revealed globule aggregates, each aggregate appearing to be composed of about four fused globules. The cleavage face of the cytoplasmic leaflet was normal. When immune lysis was carried out in the presence of ferritin, ferritin was subsequently detected in all lysed erythrocytes. If ferritin was added after immune lysis was complete, only 15% of the cells were permeated by ferritin, indicating that transient openings exist in the cell membrane during immune lysis. No abnormal structures were detected when C6-deficient rabbit serum was used as a source of complement. It is concluded that antibody and complement produce surface rings, prelytic leakage of K⁺, colloid osmotic swelling, membrane disruption, and membrane resealing; the surface rings persist after these events.     

Structural and functional aspects of tumor cell sialomucins

Sialomucins are abundant on the surfaces of certain ascites tumor cells and have been implicated in the escape of tumors from immune destruction and metastasis. They are large, highly glycosylated glycoproteins which are rich in serine and threonine and have a variety of 0-linked oligosaccharides. The sialomucin (ASGP-1) or 13762 rat mammary adenocarcinoma ascites cells represents more than 0.5% of the total cell protein and can be isolated from cell membranes by centrifugation in 4 M guanidine hydrochloride-cesium chloride. ASGP-1 can also be isolated from membranes or cells by nonionic detergent extraction as a 1:1 complex with a second glycoprotein ASGP-2. Studies with the fluorescent lectins peanut agglutinin, which binds ASGP-1, and Concanavalin A, which binds ASGP-2, indicate that the glycoproteins are present at the cell surface as a complex. ASGP-1 is shed into cell culture medium or ascites fluid, apparently by a proteolytic cleavage mechanism. 13762 ascites cells grown in culture or as solid tumors lose their ASGP-1. The sialomucin reappears with extensive passage of the tumor cells in ascites form. Studies on the biosynthesis of ASGP-1 indicate that carbohydrate is being added over nearly the entire period of transit of ASGP-1 from the site of polypeptide synthesis to the plasma membrane. The negatively charged, rod-like structure of the sialomucins suggests that they may play a role in inhibiting recognition or binding processes necessary for the immune destruction of these tumor cells.     

Quantification of nuclear DNA and intracellular glycogen in a single cell by fluorescent double-staining.

It was found that intracellular glycogen is stabilized against acid treatment when it is stored under dry conditions for three months after methanol fixation. This stabilization allowed quantitative double fluorescence staining for nuclear DNA and intracellular glycogen, in a single cell. A Feulgen nucleal reaction, with acriflavine-Schiff's reagent following 5 N HCl hydrolysis at 25 degrees C for 4 min, was followed by a pararosanilin-Schiff PAS reaction for glycogen. This short term hydrolysis was found to be sufficient for the performance of a acriflavine-Schiff's Feulgen nucleal reaction and to provide good preservation of intracellular glycogen. Quantification of nuclear DNA and intracellular glycogen were consecutively carried out with a digital microfluorometer on a single ascites cancer cell of the AH-13 line stained by this method. It was found that there is a positive linear correlation between the amount of DNA and glycogen in this cell line.