Disposition of glycoproteins in plasma membrane of cultured rat embryonic fibroblasts

Plasma membrane fractions were isolated from untreated and trypsin- or neuraminidase-treated rat embryo fibroblasts and their sialic acids contents per mg membrane protein were determined. The difference represented enzyme releasable sialic acid exposed on the medium side of the cell mambrane. It was 14 to 23% of the total membrane bound sialic acid. Isolated plasma membrane fraction from entreated and enzyme treated cells were then subjected to trypsin or neuraminidase treatment to obtain enzyme-releasable sialic acid from both faces and from the cytoplasmic face of the membrane respectively. Between 30 and 50% of the total membrane bound sialic was released from both the faces and 14 to 30% from the cytoplasmic face. An average of 59% was insusceptible to these enzymes. As an alternative to a cytoplasmic location of sialic acid containing membrane constituents, inaccessibility of enzymes to some of these constituents present on the surface of intact cells is considered.Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis of plasma membrane fractions isolated from untreated and trypsin treated cells and of trysinized plasma membrane fraction was carried out to know the number and gel migration of proteins and glycoproteins which are exposed on each of the two faces of the plasma membrane and are sensitive or insensitive to trypsin. The resilts obtained were confirmed by SDS-polyacrylamide gel electrophoresis of untreated and trypsin-treated cells and of isolated plasma membrane fraction after subjecting them to enzymatic radioiodination.     

Accessibility of sialo components in a murine tumor cell to extracellular N-acetylneuraminate glycohydrolase (sialidase).

Lipid-bound sialic acid in the murine melanoma cell is not totally inaccessible to an exogenous macromolecular probe, as formerly believed. Roughly 30% of the dialic acid bound to lipid, and an equal proportion of the sialic acid bound to protein is cleaved by the action of Clostridium perfringens N-acetylneuraminate glycohydrolase (neuraminidase, sialidase) when the purified enzyme is added to the suspenion medium of intact murine melanoma cells freshly derived from the tumor. Cleavage of lipid-bound sialic acid is indifferent to the presence of Ca (2+) in the medium. However, maximum release from protein requires a physiological concentration of this divalent cation. Variation in ionic strength has no effect on release of sialic acid. These findings show that restricted portion of the bound sialic acid may be released from the intact murine melanama cell by the extracellularly supplied enzyme acting topographically.     

Accessibility of sialo components in a murine tumor cell to extracellular N-acetylneuraminate glycohydrolase (sialidase)

Lipid-bound sialic acid in the murine melanoma cell is not totally inaccessible to an exogenous macromolecular probe, as formerly believed. Roughly 30% of the sialic acid bound to lipid, and an equal proportion of the sialic acid bound to protein is cleaved by the action of Clostridium perfringens$\text{N-}\text{acetylneuraminate}$ glycohydrolase (neuraminidase, sialidase) when the purified enzyme is added to the suspension medium of intact murine melanoma cells freshly derived from the tumor. Cleavage of lipid-bound sialic acid is indifferent to the presence of Ca²⁺ in the medium. However, maximum release from protein requires a physiological concentration of this divalent cation. Variation in ionic strength has no effect on release of sialic acid. These findings show that a restricted portion of the bound sialic acid may be released from the intact murine melanama cell by the extracellularly supplied enzyme acting topographically.     

Relative susceptibilities to neuraminidase of the glycoproteins of the human erythrorcyte

Release of sialic acid from the glycoproteins of the normal human erythrocyte surface by neuraminidase was investigated. The glycoproteins of the membrane were separated by electrophoresis in sodium dodecylsulfate polyacrylamide gels. Sialic acid was determined in the sliced gel by a modification of the 2-thiobarbituric acid method, revealing three sialic acid-containing glycoproteins. Treatment of intact erythrocytes with neuraminidase to remove varying amounts of sialic acid indicates that all the glycoproteins are essentially equally accessible to the neuraminidase when 20%–60% of the sialic acid is removed. Similar but not quite identical results were obtained with isolated erythrocyte membranes.Treatment of intact cells with the lectins concanavalin A or phytohemagglutinin-P resulted in shielding of about 25% and 50%, respectively, of the sialic acid from neuraminidase. Concanavalin A blocked sialic acid release over long time periods and with high concentrations of neuraminidase. In contrast, the sialic acid shielding by phytohemagglutinin-P can be overcome by high concentrations of neuraminidase. Both lectins were found to shield the various glycoproteins selectively, with different patterns of shielding. Wheat germ agglutinin exhibited no detectable effect on the susceptibility of the erythrocyte sialic acid to neuraminidase.     

Topographic Distribution of Enzymes Synthesizing Phosphatidylcholine and Phosphatidylethanolamine in Chicken Brain Microsomes

Abstract: The localization of phosphatidylethanolamine and phosphatidylcholine biosynthetic enzymes within the transverse plane of chicken brain microsomes was investigated by using proteases (trypsin and pronase) and neuraminidase. Treatment of intact microsomes with the proteases inactivated the phosphocholine transferase completely and the ethanolamine phosphotransferase only slightly. This latter enzyme was, however, completely inactivated when deoxycholate-treated microsomes were exposed to proteases. Treatment of intact microsomes with neuraminidase had no effect on both phosphotransferases, although 65% of the sialic acid of sialoglycoproteins and 37% of that of gangliosides were removed. With deoxycholate-disrupted microsomes nearly all sialic acid from the sialoglycoproteins and about 70% of that of gangliosides were released. In parallel, the phosphoethanolamine transferase was 90% inactivated. It is suggested that phosphocholine transferase is localized on the outer face of the microsomal vesicle, whereas the phosphoethanolamine transferase could be a sialoglycoprotein, possibly situated on the inner face of the vesicle, or perhaps a transmembrane protein.     

Effect of phagocytosis on guinea pig granulocyte membrane markers

The internalization of membrane markers during phagocytosis was followed in guinea pig granulocytes as a function of the extent of particle ingestion. The plasmalemma was carefully labeled with diazotized ³⁵S-sulfanilate, or by treatment with periodate and sodium ³H-borohydride. These treatments provided general membrane markers. More specific markers used were 5′-nucleotidase, neuraminidase-releasable membrane sialate, and concanavalin A binding sites. In all cases except the last, internalization of membrane was directly determined on isolated phagosomes; disappearance of binding sites from the cell surface was followed in the last instance. Both phagosomal levels and disappearance from the surface were measured in the case of 5′-nucleotidase, permitting balance studies. Phagocytosis was determined as uptake of paraffin emulsions labeled with Oil-Red 0. “Marker/particle” ratios were determined as the percent external marker internalized per mg paraffin ingested. The “marker/particle” ratios for cells with chemically labeled membranes were considered to reflect random internalization of membrane entities. Colchicine had no effect on those ratios. Internalization of 5′-nucleotidase and neuraminidase-releasable sialate gave “marker/particle” ratios similar to those of the random markers, and these increased in the presence of colchicine. Concanavalin A binding sites did not appear to be removed from the cell surface in the absence of colchicine, but disappearance was observed in its presence. Control experiments indicated that these changes due to colchicine must be very cautiously interpreted. Our results differ from those obtained by others, and the reasons due to species, cell type, experimental design, etc. are discussed. Maximal particle uptake was computed to require internalization of one-fifth to one-third of the total external membrane of the cells—based on the assumption of random internalization of markers.     

Localization of glycoconjugates on the surfaces of pronephric tumor cells in vitro

Differential localization of glycoconjugates was detected on microvilli and microridges of the intact cell surface of frog pronephric tumor cells in tissue culture. Alcian blue and Alcian blue/PAS staining showed a heavy concentration of dye limited to the unique short microvilli and extensive microridges of the tumor cells as previously seen with SEM (Tweedell and Williams 1976). Staining was absent or greatly reduced on microvilli of the normal pronephric cell surface. Previous exposure of each kind of cells to neuraminidase or extraction by mild hydrolysis removed the active staining sites but Alcian blue uptake was unaffected by prior digestion with testicular hyaluronidase. Fluorescein isothiocyanate (FITC) bound wheat germ agglutinin (WGA) produced a similar pattern of fluorescence on the microvilli of the tumor cells and a limited distribution on the normal cells. Digestion with neuraminidase preferentially removed but did not completely eliminate the surface binding of WGA on both the normal and tumor cells. Exposure of tumor cell monolayers to FITC bound limulin, a lectin specific for sialic acid, also produced an intense surface fluorescence on the microvilli and ridges of tumor cells. Prior treatment with neuraminidase prevented the surface fluorescence but not internal binding. Normal pronephric cells gave sparse surface fluorescence but extensive internal binding. Each procedure indicates a preferential localization of complex carbohydrates, including sialic acid, on the unique microvilli of the tumor cells. Concurrent assays for sialic acid recovered from the tumor cells indicated that lectin bound surface sialic acid was removable with neuraminidase.     

Localization of glycoconjugates on the surfaces of pronephric tumor cells in vitro

Summary Differential localization of glycoconjugates was detected on microvilli and microridges of the intact cell surface of frog pronephric tumor cells in tissue culture. Alcian blue and Alcian blue/PAS staining showed a heavy concentration of dye limited to the unique short microvilli and extensive microridges of the tumor cells as previously seen with SEM (Tweedell and Williams 1976). Staining was absent or greatly reduced on microvilli of the normal pronephric cell surface. Previous exposure of each kind of cells to neuraminidase or extraction by mild hydrolysis removed the active staining sites but Alcian blue uptake was unaffected by prior digestion with testicular hyaluronidase. Fluorescein isothyocyanate (FITC) bound wheat germ agglutinin (WGA) produced a similar pattern of fluorescence on the microvilli of the tumor cells and a limited distribution on the normal cells. Digestion with neuraminidase preferentially removed but did not completely eliminate the surface binding of WGA on both the normal and tumor cells. Exposure of tumor cell monolayers to FITC bound limulin, a lectin specific for sialic acid, also produced an intense surface fluorescence on the microvilli and ridges of tumor cells. Prior treatment with neuraminidase prevented the surface fluorescence but not internal binding. Normal pronephric cells gave sparse surface fluorescence but extensive internal binding. Each procedure indicates a preferential localization of complex carbohydrates, including sialic acid, on the unique microvilli of the tumor cells. Concurrent assays for sialic acid recovered from the tumor cells indicated that lectin bound surface sialic acid was removable with neuraminidase.This study was supported by a grant from the Cancer Society of Saint Joseph County, Indiana and from the Phi Beta Psi Sorority     

Sialic acid, electrophoretic mobility and transmembrane potentials of the Amphiuma red cell.

Red cells from the giant salamander Amphiuma means are shown to contain sialic acid. The amount removed by the action of neuraminidase is equal to that released by acid hydrolysis, indicating that all of the sialic acid is present on the outer surface of the plasma membrane. These cells have a negative electrophoretic mobility and 100% enzymatic removal of sialic acid results in a 40% reduction in the mobility, suggesting that either a fraction of the sialic acid carboxyl groups are unavailable to the action of external electric fields, or other negatively charged groups contribute to the surface charge. A further reduction in mobility of normal and sialic acid-free cells is caused by an increased extracellular calcium concentration. The negative groups affected by calcium are most likely to be phosphate groups, since the isoelectric point of the cells is found to lie between the pK values for H2PO-4 groups and the carboxyl groups of sialic acid. Membrane potentials of single cells, from which 80% or more of the total sialic acid had been removed, were identical to those measured in normal cells, confirming that sialic acid plays little, if any, direct role in the maintenance of membrane potentials and ionic permeabilities.     

Developmental Changes in the Biosynthesis of Sialoglycoprotein Substrates for Intrinsic Synaptic Sialidase

Abstract: N′-Acetyl-d -[6-³H]mannosamine was administered to 13- and 28-day-old rats by intraventricular injection. At various time intervals following the injection, synaptic membranes were prepared and the incorporation of radiolabel into sialic acid residues released from endogenous glycoproteins and gangliosides by intrinsic sialidase determined. Radiolabel was incorporated into synaptic membrane gangliosides and glycoproteins, and at all times tested, >90% of the label was associated with sialic acid. Sialic acid released from endogenous glycoproteins by intrinsic sialidase present in 28-day membranes incorporated only 20–25% as much radiolabel per nmole as sialic acid released by mild acid hydrolysis or by exogenous neuraminidase. In contrast, sialic acid released from glycoproteins present in 13-day-old membranes by intrinsic sialidase, mild acid hydrolysis, or exogenous neuraminidase all were similarly labelled. At both ages the specific radioactivity (cpm/nmol) of sialic acid released from gangliosides by the intrinsic enzyme was similar to the total ganglioside sialic acid released by mild acid hydrolysis. The results identify glycoprotein substrates for intrinsic synaptic membrane sialidase as a distinct metabolic class in the mature brain and suggest the occurrence of a developmentally related change in the metabolism of these glycoproteins.     

Localization of protein-bound carbohydrate residues on the cytoplasmic surface of rough and smooth microsomes and golgi vesicles from rat liver

Rough and smooth microsomes and Golgi membranes isolated from rat liver were treated with proteolytic enzymes under conditions which removed 30–40% of the surface proteins without seriously disrupting the membrane structure. This treatment also removed 40–60% of protein-bound mannose, galactose and glucosamine. When protease treatment was combined with neuraminidase treatment, 80% of the sialic acid was removed from intact rough microsomal and Golgi vesicles and about half of the sialic acid of smooth microsomes was solubilized. It appears that half, or probably more, of the membrane glycoproteins are associated with the cytoplasmic surface of these membranes.     

The influence of lysosomes on glycogen metabolism.

Treatment of rabbit spermatozoa with 50mM-MgCl2 removes the plasma and the outer acrosomal membranes. Subsequent treatment with the detergents Hyamine 2389 and Triton X-100 solubilizes spermatozoal neuraminidase bound to the inner acrosomal membrane. The enzyme was further purified by DEAE-cellulose, Sephadex G-150 and Bio-Gel P-300 column chromato. The enzyme showed a single major band, with the possibility of some minor contaminants, on disc-gel electrophoresis. It had a specific activity of 0.37 micronmal of sialic acid released/min per mg with purified boar Cowper's-gland mucin as the substrate. The enzyme had marked specificity for 2 leads to 6'-linked sialic acid in glycoproteins. The Km of spermatozoal neuraminidase was 1.72 X 10(-6)M with Cowper's-gland mucin, 1.17 X 10(-5)M with fetuin and 8.8 X 10(-4)M with sialyl-lactose as a substrates. The Vmax. was 0.112 micronmol/min per mg with the Cowper's-gland mucin, 0.071 micronmol/min per mg with fetuin and 0.033 micronmol/min per mg with sialyl-lactose as substrate. The enzyme hydrolysed sheep submaxillary-gland mucin as readily as the Cowper's-gland mucin. The optimum of enzyme activity was at pH 5.0 on the Cowper's-gland mucin and at pH4.3 on sialyl-lactose. The enzyme activity was unaffected by 20mM-Na+ and-K+, but was inhibited by 20mM-Ca2+,-Mn2+,-Co2+ and -Cu2+. The enzyme was unstable in dilute solutions, but could be stored indefinitely freeze-dried at --20 degrees C.     

The effects of cell membrane alteration on glucocorticoid uptake by the AtT-20/D-1 target cell

The glucocorticoid-sensitive AtT-20/D-1 cell line was used to study cellular uptake of glucocorticoids. A previous observation that glucocorticoid uptake by these cells was temperature dependent had prompted us to postulate that glucocorticoids entered the cell by a temperature-sensitive transport process located in the cell membrane. Attempts were then made to perturb the membrane mechanism. In some of these experiments, intact cells were treated with neuraminidase or pronase. The release of sialic acid in the case of neuraminidase treatmentand of sialic acid and cell surface peptides in the case of pronase treatment demonstrated that the enzymes were effective. Approx. 60% of total cellular sialic acid was released by a 15 min incubation with 20 μg/ml neuraminidase at 25°C. The treated cells appeared to be viable, in that they continued to produce corticotropin at a normal rate, yet intact cell glucocorticoid binding at both 4 and 25°C was only 20–30% of that of untreated cells. Treatment with pronase also caused steroid uptake at 4 and 25°C to be reduced, although the extent of reduction was less than that seen following neuraminidase treatment.In other experiments, the effect of exposure of AtT-20/D-1 cells to ethanol or dimethyl sulfoxide was determined. The solvent concentrations used (0.5–10%) did not alter cell viability significantly, and the ability of the cytosol receptor to bind steroid in a cell-free preparation was unimpaired. However, incubation of intact cells with 10% (v/v) dimethyl sulfoxide or ethanol resulted in an 80–90% decrease in steroid uptake at 25°C.We conclude that steroid uptake by the intact cell can be perturbed by treatments which do not affect the cytosol receptor or alter cell viability. These results support the postulate that glucocorticoids enter the AtT-20/D-1 cell by a specific membrane-associated mechanism.     

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.     

Effect of removing sialic acids from endothelium on the adherence of circulating platelets in arteries in vivo

The contribution of the net negative charge excess due to sialic acids on endothelium in preventing adhesion of circulating platelets in vivo was investigated in anaesthetized rabbits. Platelets in the rabbit's circulation were selectively labelled with radioactive 5-hydroxytryptamine in vivo. Segments of carotid arteries temporarily isolated from the circulation were perfused with one or other of two commercial preparations of neuraminidase; the opposite carotid artery was perfused similarly without the enzyme, as control. A neuraminidase preparation from Behringwerke free of proteolytic activity released sialic acid into the perfusate with a peak concentration after 10-15 min which decreased gradually later. A neuraminidase preparation from Sigma that contained demonstrable proteolytic activity released sialic acid similarly during the first hour and thereafter more sialic acid in a second peak. After blood flow through the carotids had been restored the adhesion of labelled platelets in the artery perfused with neuraminidase was compared with that in the artery perfused without the enzyme. The radioactivities were significantly higher in carotids that had been perfused with neuraminidase than in those that had been perfused without the enzyme. Neuraminidase perfusion had no effect on the production of prostacyclin by the carotids. Perfusion with acetylsalicylic acid before neuraminidase increased the adhesion of platelets significantly. It is concluded that diminution in electrostatic repulsion between circulating platelets and vascular endothelium from which the net negative charge excess due to sialic acids has been removed increases the adhesion of circulating platelets, irrespective of the production of prostacyclin by the arterial walls, and that inhibition of prostacyclin production augments this adhesion of platelets.     

Release of sialic acid alters the stability of the membrane potential in cardiac muscle

Intracellular recording techniques and neuraminidase, an enzyme that specifically catalyzes the hydrolysis of sialic acid's glycosidic linkage in glycoproteins and glycolipids, were employed to investigate the role of sialic acid residues in maintaining a stabilized resting potential or rhythmic electrical activity in embryonic chick cardiac muscle. Free sialic acid was quantified by a fluorometric assay. Release of more than 25% of the sarcolemma-bound sialic acid from spheroidal aggregates of cultured heart cells resulted in a) depolarizing fluctuations in the membrane potential, b) initiation of spontaneous firing in the presence of tetrodotoxin, c) arrhythmic spontaneous activity, d) depolarization of the maximum diastolic potential, and e) a significant reduction in the plateau and duration of the action potential. Control experiments demonstrated that these effects were not caused by phospholipase contamination of the enzyme or by the sialic acid released during hydrolysis.     

Sialic acid, electrophoretic mobility and transmembrane potentials of the Amphiuma red cell

Red cells from the giant salamander Amphiuma means are shown to contain sialic acid. The amount removed by the action of neuraminidase is equal to that released by acid hydrolysis, indicating that all of the sialic acid is present on the outer surface of the plasma membrane. These cells have a negative electrophoretic mobility and 100% enzymatic removal of sialic acid results in a 40% reduction in the mobility, suggesting that either a fraction of the sialic acid carboxyl groups are unavailable to the action of external electric fields, or other negatively charged groups contribute to the surface charge. A further reduction in mobility of normal and sialic acid-free cells is caused by an increased extracellular calcium concentration. The negative groups affected by calcium are most likely to be phosphate groups, since the isoelectric point of the cells is found to lie between the pK values for H₂PO₄⁻ groups and the carboxyl groups of sialic acid. Membrane potentials of single cells, from which 80% or more of the total sialic acid had been removed, were identical to those measured in normal cells, confirming that sialic acid plays little, if any, direct role in the maintenance of membrane potentials and ionic permeabilities.     

Physiological ageing of red blood cells and changes in membrane carbohydrates

Evidence is presented to indicate a generalized role for the terminal sialic acid residues of circulating erythrocytes. After reinjection into their donors, neuraminidase-treated human, rabbit, rat and dog erythrocytes were promptly removed from the circulation : intect erythrocytes, previously incubated under the same conditions but without neuraminidase, were removed after a significantly longer period. The neuraminidase-treated erythrocytes were cleared by the liver and in a little part by the spleen. Old and young human, rabbit, rat erythrocytes contained different quantities of stromal sialic acid, significantly lowered on the old cells. But the half-life of old intact rabbit erythrocytes is sigificantly shorter than that of neuraminidase-treated young erythrocytes with a similar minidase-treated young erythrocytes with a similar sialic acid content. Indeed sialic acid is not the only carbohydrate component of the membrane that is decreased during erythrocyte ageing, the others membranous sugars are decreased too. Theses changes in the carbohydrate moity could have a role in the clearance of the erythrocytes.     

Adherence of Brucella to human epithelial cells and macrophages is mediated by sialic acid residues

The basis for the interaction of Brucella species with the surface of epithelial cells before migration in the host within polymorphonuclear leucocytes is largely unknown. Here, we studied the ability of Brucella abortus and Brucella melitensis to adhere to cultured epithelial (HeLa and HEp-2) cells and THP-1-derived macrophages, and to bind extracellular matrix proteins (ECM). The brucellae adhered to epithelial cells forming localized bacterial microcolonies on the cell surface, and this process was inhibited significantly by pretreatment of epithelial cells with neuraminidase and sodium periodate and by preincubation of the bacteria with heparan sulphate and N-acetylneuraminic acid. Trypsinization of epithelial cells yielded increased adherence, suggesting unmasking of target sites on host cells. Notably, the brucellae also adhered to cultured THP-1 cells, and this event was greatly reduced upon removal of sialic acid residues from these cells with neuraminidase. B. abortus bound in a dose-dependent manner to immobilized fibronectin and vitronectin and, to a lesser extent, to chondroitin sulphate, collagen and laminin. In sum, our data strongly suggest that the adherence mechanism of brucellae to epithelial cells and macrophages is mediated by cellular receptors containing sialic acid and sulphated residues. The recognition of ECM (fibronectin and vitronectin) by the brucellae may represent a mechanism for spread within the host tissues. These are novel findings that offer new insights into understanding the interplay between Brucella and host cells.     

Cytochalasin B and the sialic acids of Ehrlich ascites cells

The effect of cytochalasin B (CB) on the electrophoretic mobility and density of ionized sialic acid groups at the surface of Ehrlich ascites cells was examined together with a biochemical assay of the total sialic acid content of treated and control cells. Sialic acid assays indicated that CB-treated cells had a greater amount of total sialic acid and sialic acid sensitive to neuraminidase than control cells/cell. Equal amounts of sialic acid were removable by neuraminidase treatment from control cells and cells pretreated with neuraminidase and subsequently cultured with CB. The electrophoresis results showed a decrease in electrophoretic mobility in the presence of CB which could be reversed by growth in CB-free medium. Neuraminidase treatment did not make a significant additional reduction in the mobility of CB-treated cells. CB also prevented the recovery of electrophoretic mobility of neuraminidase treated cells. The results suggest that while CB does not inhibit sialic acid synthesis, it does alter the expression of ionized sialic acid groups at the electrokinetic surface. CB-containing culture media could be re-utilized several times suggesting that CB is not significantly bound or metabolized by Ehrlich ascites cells.