Rapid and simple single nanogram detection of glycoproteins in polyacrylamide gels and on electroblots

The fluorescent hydrazide, Pro-Q Emerald 300 dye, may be conjugated to glycoproteins by a periodic acid Schiff's (PAS) mechanism. The glycols present in glycoproteins are initially oxidized to aldehydes using periodic acid. The dye then reacts with the aldehydes to generate a highly fluorescent conjugate. Reduction with sodium metabisulfite or sodium borohydride is not required to stabilize the conjugate. Though glycoprotein detection may be performed on transfer membranes, direct detection in gels avoids electroblotting and glycoproteins may be visualized within 2-4 h of electrophoresis. This is substantially more rapid than PAS labeling with digoxigenin hydrazide followed by detection with an antidigoxigenin antibody conjugate of alkaline phosphatase, or PAS labeling with biotin hydrazide followed by detection with horseradish peroxidase or alkaline phosphatase conjugates of streptavidin, which require more than eight hours to complete. Pro-Q Emerald 300 dye-labeled gels and blots may be poststained with SYPRO Ruby dye, allowing sequential two-color detection of glycosylated and nonglycosylated proteins. Both fluorophores are excited with mid-range UV illumination. Pro-Q Emerald 300 dye maximally emits at 530 nm (green) while SYPRO Ruby dye maximally emits at 610 nm (red). As little as 300 pg of alpha 1-acid glycoprotein (40% carbohydrate) and 1 ng of glucose oxidase (12% carbohydrate) or avidin (7% carbohydrate) are detectable in gels after staining with Pro-Q Emerald 300 dye. Besides glycoproteins, as little as 2-4 ng of lipopolysaccharide is detectable in gels using Pro-Q Emerald 300 dye while 250-1000 ng is required for detection with conventional silver staining. Detection of glycoproteins may be achieved in sodium dodecyl sulfate-polyacrylamide gels, two-dimensional gels and on polyvinylidene difluoride membranes.     

Fluorescent labeling of the carbohydrate moieties of human chorionic gonadotropin and alpha 1-acid glycoprotein

A method for covalent attachment of a fluorescent molecule to the carbohydrate moieties of glycoproteins is described. The glycoproteins were oxidized with periodate under mild conditions selective for sialic acid (Van Lenten, L. and Ashwell, G. (1971) J. Biol. Chem. 246, 1889--1894). The resulting aldehydes were condensed with either dansylhydrazine, dansylethylenediamine, or fluoresceinamine followed by reduction with NaCNBH3 and NaBH4. Conjugates prepared with dansylhydrazine were found to be insufficiently stable for spectroscopic analysis, whereas the primary amines produced stable conjugates whose fluorescence polarization (P) was constant for several hours at 37 degrees C. The degree of labeling correlated roughly with the sialic acid contents of the vaious glycoproteins. Very little covalent incorporation was observed with albumin (which is devoid of carbohydrate) or with asialo alpha 1-acid glycoprotein. Exclusion chromatography in the presence of a dissociating agent was sometimes required to remove significant amounts of noncovalently adsorbed dye. Fluorescent-labeled alpha subunits of human chorionic gonadotropin were shown to recombine normally with native beta subunits. However, the labeling procedure appeared to compromise the ability of the beta subunits to recombine. Electrophoretic analysis produced evidence of covalent cross-linking between subunits following periodate oxidation of the intact gonadotropin. The possibility that primary amine groups of the protein compete with added fluorescent amines for reaction with periodate-generated aldehydes is discussed.     

Prestaining of glycoproteins in sodium dodecyl sulfate polyacrylamide gels by dansylhydrazine

A new fluorescent prestaining method for gel‐separated glycoproteins in 1D and 2D SDS‐PAGE was developed by using dansylhydrazine in this study. The prestained gels could be easily imaged after electrophoresis without any time‐consuming steps needed for poststains. As low as 4–8 ng glycoproteins (transferrin, α1‐acid glycoprotein) could be selectively detected, which is comparable to that of Pro‐Q Emerald 488, one of the most commonly used glycoprotein stain. In addition, a subsequent study of deglycosylation, glycoprotein affinity isolation, and LC‐MS/MS analysis was performed to confirm the specificity of the newly developed method.     

Demonstration of glucuronic acid on brain glycoproteins which react with HNK-1 antibody

Ependymins, a family of extracellular glycoproteins of goldfish and mammalian brain, were shown to contain N-linked complex glycan chains. These glycoproteins reacted with a monoclonal antibody, HNK-1 which recognizes a membrane antigen on a subset of human lymphocytes, myelin-associated glycoprotein glycoprotein epitope reacting with HNK-1 antibody was previously shown to include a terminal 3-sulfoglucuronosyl residue present in certain glycolipids of the nervous tissue (Chou et al., Biochem. Biophys. Res. Commun. 1985, 128, 383-388). In this report, the presence of glucuronic acid in ependymins was demonstrated by gas-liquid chromatography and mass spectrometry. We suggest that a 3-sulfoglucuronosyl residue may be the common epitope on HNK-1-reactive glycoproteins.     

Isolation and characterization of gastric microsomal glycoproteins. Evidence for a glycosylated beta-subunit of the H+/K(+)-ATPase.

Detergent-solubilization of hog gastric microsomal membrane proteins followed by affinity chromatography using wheat germ agglutinin or Ricinus communis I agglutinin resulted in the isolation of five glycoproteins with the apparent molecular masses on sodium dodecyl sulfate polyacrylamide gels of (in kDa): 60-80 (two glycoproteins sharing this molecular mass); 125-150; and 190-210. In the nonionic detergent Nonidet P-40 (NP-40), the 94 kDa H+/K(+)-ATPase was recovered exclusively in the lectin-binding fraction; however, in the cationic detergent dodecyltrimethylammonium bromide, most of the ATPase was recovered in the nonbinding fraction. Detection of glycoproteins either by periodic acid-dansyl hydrazine staining of carbohydrate in polyacrylamide gels or by Western blots probed with lectins indicated that the majority of the ATPase molecules are not glycosylated. In addition, in the absence of microsomal glycoproteins, the NP-40-solubilized ATPase does not bind to a lectin column. Taken together, these results suggest that the recovery of NP-40-solubilized ATPase in the lectin-binding fraction is due to its noncovalent interaction with a gastric microsomal glycoprotein. Immunoprecipitation of the ATPase from NP-40-solubilized microsomal membrane proteins resulted in the co-precipitation of a single 60-80 kDa glycoprotein. Characterization of the 60-80 kDa glycoprotein associated with the ATPase revealed that: it is a transmembrane protein; it has an apparent core molecular mass of 32 kDa; and, it has five asparagine-linked oligosaccharide chains. Given its similarity to the glycosylated beta-subunit of the Na+/K(+)-ATPase, this 60-80 kDa gastric microsomal glycoprotein is suggested to be a beta-subunit of the H+/K(+)-ATPase.     

Topography of glycoproteins in the chick synaptosomal plasma membrane

Chick brain synaptosomes or synaptic subfractions were treated with neuraminidase (EC 3.2.1.18) and/or galactose oxidase (EC 1.1.3.9) preparations in which proteolytic activity was inhibited with phenylmethanesulfonyl fluoride followed, after washing, by reductive incorporation of sodium boro[³H]hydride to identify galactose residues exposed on the synaptosomal external surface. Control experiments to demonstrate restriction of labeling to the external surface involved comparing the radioactivity in synaptoplasmic, soluble polypeptides isolated after labeling with labeled, isolated synaptoplasm and examining incorporation into fractions incubated without enzymes. Intactness of the synaptic plasma membrane after labeling was shown by trypsin digestion studies. Polypeptides were separated on sodium dodecyl sulfate polyacrylamide gels and were detected by a liquid scintillation counting procedure. Eleven major radioactive peaks were found after galactose oxidase treatment and reduction of isolated synaptic membranes. When intact synaptosomes were labeled, the same components were detected. When isolated synaptic membranes or intact synaptosomes were treated with neuraminidase before galactose oxidase treatment, three additional components were labeled. These results suggest that (a) chick synaptic membranes have a complex mixture of glycoproteins, (b) all major chick synaptic membrane glycoproteins labeled by galactose oxidase have most or all carbohydrate groups exposed at the exterior surface of the synaptosome, (c) all major, externally-disposed polypeptides of these synaptic membranes are glycoproteins.     

Surface-membrane biogenesis in rat intestinal epithelial cells at different stages of maturation.

The biosynthesis of membrane proteins and glycoproteins has been studied in rat intestinal crypt and villus cells by measuring the incorporation of L-[5,6-3H] fucose, D-[2-3H] mannose and L-[3,4,5-3H] leucine, given intraperitoneally, into Golgi, lateral-basal and luminal membranes. Incorporation of leucine and mannose was approximately equal in crypt and villus cells, whereas fucose incorporation was markedly higher (3-4 times) in the differentiated villus cells. As previously reported [Quaroni, Kirsch & Weiser (1979) Biochem J. 182. 203-212] most of the fucosylated glyco-proteins synthesized in the villus cells and initially present in the Golgi and lateral-basal membranes were found re-distributed, within 3-4h of label administration, in the luminal membrane. A similar process appeared to occur in the crypt cells, where, however, only few fucose-labelled glycoproteins were identified. In contrast, most of the leucine-labelled and many mannose-labelled membrane components found in the lateral-basal membrane of both crypt and villus cells did not seen to undergo a similar re-distribution process. The fucosylated glycoproteins of the intestinal epithelial cells represent, therefore, a special class of membrane components, most of which appear with differentiation, that are selectively localized in the luminal portion of the plasmalemma. In contrast with the marked differences in protein and glycoprotein patterns between the luminal membrane of villus and crypt cells, only minor differences were found between their lateral-basal membrane components: their protein patterns on sodium dodecyl sulphate/polyacrylamide slab gels, and the patterns of fucose-, mannose- and leucine-labelled components (analysed 3-4h after label administration) were very similar. Although the minor differences detected may be of importance, it appears that most of the surface-membrane changes accompanying cell differentiation in the intestinal epithelial cells are localized in the luminal portion of their surface membrane.     

Lectin-binding proteins in central-nervous-system myelin. Binding of glycoproteins in purified myelin to immobilized lectins

The capacities of immature and mature rat brain myelin, bovine myelin and human myelin to be agglutinated by soya-bean agglutinin, Ricinus communis agglutinin, wheatgerm agglutinin, and Lotus tetragonolobus agglutinin were examined. The first two lectins, which are specific for galactose and N-acetylgalactosamine, strongly agglutinated immature and mature rat myelin, weakly agglutinated bovine myelin, but did not affect human myelin. The other myelin and lectin combinations resulted in very weak or no agglutination. [(3)H]Fucose-labelled glycoproteins of purified adult rat brain myelin were solubilized with sodium dodecyl sulphate and allowed to bind to concanavalin A-Sepharose and each of the other lectins mentioned above, which had been immobilized on agarose. About 60% of the radioactive fucose was in glycoproteins that bound to concanavalin A-Sepharose and these glycoproteins could be eluted with solutions containing methyl alpha-d-mannoside and sodium dodecyl sulphate. Periodate/Schiff staining or radioactive counting of analytical gels showed that most of the major myelin-associated glycoprotein (apparent mol.wt. approx. 100000) bound to the concanavalin A, whereas the glycoproteins that did not bind were mostly of lower molecular weight. Preparative polyacrylamide-gel electrophoresis of the glycoprotein fraction that was eluted with methyl alpha-d-mannoside yielded a relatively pure preparation of the myelin-associated glycoprotein. Similar results were obtained with each of the other lectins, i.e. the myelin-associated glycoprotein was in the fraction that bound to the immobilized lectin. Double-labelling experiments utilizing [(3)H]fucose-labelled glycoproteins from adult myelin and [(14)C]fucose-labelled glycoproteins from 14-day-old rat brain myelin did not reveal any difference in the binding of the mature and immature glycoproteins to any of the immobilized lectins. The results in this and the preceding paper [McIntyre, Quarles & Brady (1979) Biochem. J.183, 205-212] suggest that the myelin-associated glycoprotein is one of the principal receptors for concanavalin A and other lectins in myelin, and that this property can be utilized for the purification of this glycoprotein.     

Glycoproteins from human colonic adenocarcinoma. Isolation and characterization of cell surface carcinoembryonic antigen from a cultured tumor cell line.

Alterations in cell surface glycoproteins have been implicated in malignancy. We examined surface membrane proteins of a cultured cell line, SKCO-1, which had been derived from a human colonic adenocarcinoma. Cell surface labeling of SKCO-1 cells with galactose oxidase, followed by reduction with sodium borotritide, revealed five major labeled glycoproteins upon sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. At least three additional labeled glycoproteins could be detected if galactose oxidase treatment was preceded by neuraminidase treatment. Some, but not all, of the glycoproteins could be iodinated by lactoperoxidase. The predominantly labeled glycoprotein (GPI) had a molecular weight of 200,000 and co-migrated in SDS gel with carcinoembryonic antigen (CEA). GPI was not removed from the cell surface by EDTA, hypertonic saline, or sonication but was released from the membrane by detergents. This glycoprotein was subsequently purified using lectin-agarose columns and gel filtration. GPI was judged homogenous by protein- and carbohydrate-stained SDS-polyacrylamide gels and had an amino acid composition similar to that of CEA. The carbohydrate composition of GPI was qualitatively similar to CEA but quantitatively distinct. GPI had a greater proportion of sialic acid and galactosamine and less fucose and glucosamine than CEA. Immunological studies, however, demonstrated identity between GPI and CEA. A study of the turnover rate of GPI showed it to have a half-life of 5 days.     

125I-wheat germ agglutinin blotting: increased sensitivity with polyvinylpyrrolidone quenching and periodate oxidation/reductive phenylamination

Two substantial improvements in sensitivity in the identification of 125I-wheat germ agglutinin-binding glycoproteins on nitrocellulose blots of sodium dodecyl sulfate-polyacrylamide gels are reported. The major improvement in sensitivity (about 30-fold) derives from the use of 2% (w/v) polyvinylpyrrolidone (average Mr 40,000) instead of bovine serum albumin or denatured hemoglobin as the quenching agent (or carrier) during incubation with 125I-wheat germ agglutinin in detergent-free, phosphate-buffered saline. Under these conditions, specific labeling with 125I-wheat germ agglutinin is observed for orosomucoid derivatives that display N-acetylglucosamine or sialic acid residues at the nonreducing termini of their oligosaccharides, as well as for a number of glycoprotein components of a rat hepatocyte plasma membrane fraction. An additional improvement in sensitivity (up to 10-fold) results from an increase in the binding of 125I-wheat germ agglutinin to sialic acid-containing glycoproteins after treatment of the blots with 5 mM sodium metaperiodate followed by 5 mM aniline in the presence of 30 mM sodium cyanoborohydride. This treatment appears to cause the sequential oxidation and reductive phenylamination of the side chain of glycoprotein sialic acid residues.     

Solubilization of human erythrocyte membrane glycoproteins by triton X-100.

1. The enzymic removal of sialic acid residues from the glycoproteins of the human erythrocyte decreases the solubilization of membrane glycoprotein by Triton X-100. 2. The solubilization of asialoglycoprotein by Triton X-100 may be restored by the addition of borate. 3. Use of this non-ionic detergent in the presence of borate, as a general procedure for the mild solubilization of membrane glycoproteins deficient in sialic acid residues, is discussed.     

The visualization of human erythrocyte membrane proteins and glycoproteins in SDS polyacrylamide gels employing a single staining procedure.

Human erythrocyte membrane proteins and glycoproteins were visualized after separation by sodium dodecyl sulfate polyacrylamide gels into molecular weight classes using a single staining procedure with a cationic carbocyanine dye (“Stains-all”). The sialoglycoproteins stained blue; the proteins, red; and the lipids, yellow-orange. This method is useful in detecting simultaneously the position of proteins and sialoglycoproteins in the commonly used SDS polyacrylamide gel electrophoresis.     

Chemical characterization of the proteins and glycoproteins of mouse liver plasma membranes solubilized by sequential extraction with aqueous and organic solvents

1. A procedure for the stepwise fractionation of the proteins of mouse liver plasma membranes is described. 2. Of the membrane protein 20-25% was soluble in 50mm-sodium carbonate-bicarbonate buffer (pH9.7). This fraction contained a large number of proteins but only 1 major glycoprotein. It was low in sialic acid, amino sugars and phospholipid. 3. Extraction of the alkali-insoluble residue with aq. 33% pyridine solubilized an additional 30-35% of the membrane protein. The pyridine-soluble membrane components were enriched in sialic acid and glucosamine and it was shown that this procedure resulted in the selective extraction of glycoproteins. 4. Gel filtration in sodium dodecyl sulphate resolved the pyridine-soluble proteins into five fractions of decreasing molecular weight and an inverse relationship between molecular weight and sialic acid content was indicated.     

Selective radioactive labeling of cell surface sialoglycoproteins by periodate-tritiated borohydride.

Low concentrations of sodium metaperiodate induce specific oxidative cleavage of sialic acids between carbon 7 and carbon 8 or carbon 8 and carbon 9. The aldehydes formed can easily be reduced with NaB3H4 to tritiated 5-acetamido-3,5-dideoxy-L-arabino-2-heptulosonic acid or 5-acetamido-3,5-dideoxy-L-arabino-2-octulosonic acid. At 0 degrees, the periodate anion penetrates the cell plasma membrane very slowly and only externally exposed sialic acids are oxidized. This was shown by (a) limited labeling of the sialoglycoproteins in a preparation of inside-out erythrocyte vesicles; (b) trapping 14C-labeled fetuin within resealed erythrocyte ghosts; fetuin was then poorly labeled, whereas the erythrocyte sialoglycoproteins were highly labeled; (c) comparison of labeled glycoproteins of mouse lymphoid cells before and after treatment with neuraminidase. This simple method of specifically introducing a radioactive label into cell surface sialic acids is useful in the study of cell surface sialic acid-containing glycoproteins.     

Purification of glycoproteins IIb and III from human platelet plasma membranes and characterization of a calcium-dependent glycoprotein IIb-III complex

Human platelet membrane glycoproteins IIb and III are two major integral membrane components that have been identified as sites mediating thrombin-induced aggregation. For purposes of our study, glycoproteins IIb and III were solubilized by extracting platelet plasma membranes with a buffer containing 0.1% Triton X-100 and were separated by gel filtration chromatography on Sephacryl S-300, employing Triton X-100-containing column buffers with or without urea or guanidine hydrochloride. The physical properties of the purified glycoproteins were: for glycoprotein IIb, Rs = 61 A, s20.w = 4.7, f/f0 = 1.7, Mr = 125,000 (hydrodynamic values), Mr = 136,000 (sodium dodecyl sulfate gels); for glycoprotein III, Rs = 67 A, s20,w = 3.2 f/f0 = 2.1, Mr = 93,000 (hydrodynamic values), Mr = 95,000 (sodium dodecyl sulfate gels). Although the amino acid compositions of the two glycoproteins were similar, antibodies raised against glycoprotein IIb did not crossreact with glycoprotein III. If divalent cations were not chelated in the Triton extract, glycoproteins IIb and III coeluted during gel filtration chromatography (apparent Stokes radius of 71 A) and co-sedimented on sucrose gradients (apparent s20.w of 8.6), from which Mr = 265,000 was calculated. Glycoproteins IIb and III were coprecipitated by an antibody monospecific for glycoprotein IIb. The two glycoproteins dissociated into monomers when EDTA was added to Triton lysates. Readdition of Ca2+ caused them to reassociate into a complex with physical properties similar to those of the complex in the original Triton lysate. The data show that glycoproteins IIb and III are a heterodimer complex, that complex formation depends upon the presence of Ca2+, and that chelation of Ca2+ causes dissociation into monomeric glycoproteins.     

Isolation of human platelet glycoproteins.

Human platelet glycoproteins were isolated from whole platelets by two methods. The first method, that of affinity chromatography on wheat germ agglutinin, is based on the known affinity of lectins for cell surface glycoproteins. When solubilized whole platelets are used as starting material for this procedure, elution with N-acetylglucosamine yields primarily a glycoprotein of Mr approximately 150 000 as estimated by sodium dodecyl sulfate-acrylamide gel electrophoresis. The second method is based on the ability of the chaotropic salt lithium diiodosalicylate to extract glycoprotein from particulate cell fractions in water-soluble form. This method yields three major glycopeptides with apparent molecular weights after sulfhydryl reduction of 145 000, 125 000, and 95 000 as estimated on 5.6% sodium dodecyl sulfate-acrylamide gels. Carboxymethylation of these preparations in the presence of sulfhydryl-reducing agent further resolves a glycoprotein of Mr approximately 165 000. Treatment of whole platelets by periodate oxidation and sodium[3H]-borohydride reduction labels the three major glycoproteins extracted by lithium diiodosalicylate and the glycoprotein of Mr approximately 150 000 isolated on wheat germ agglutinin confirming their surface orientation. However, glycoprotein with Mr approximately 165 000 resolved by carboxymethylation of the lithium diiodosalicylate extracted glycoprotein mixture was not labelled by this method, suggesting that it represents the granule protein with similar electrophoretic characteristics described by others. Phosphorylation of intact platelets with 32Pi also results in labelling of glycoproteins isolated by both methods, suggesting that these molecules traverse the bilipid layer of the platelet membrane, bearing reactive groups on both outer and cytoplasmic surfaces.     

Membrane-microfilament interactions in ascites tumor cell microvilli. Identification and isolation of a large microfilament-associated membrane glycoprotein complex

[14C]Glucosamine metabolic labeling and concanavalin A blots were used to identify four major glycoprotein species associated with ascites tumor cell microvillar microfilament cores and with a transmembrane complex containing actin. Phalloidin shift analysis of glucosamine-labeled microvilli showed that glycoproteins of 110-120, 80, 65, and 55 kDa are stably associated with the microfilament cores. Analysis of large (greater than 10(6) kDa) transmembrane complexes from microvillar membranes made under microfilament-depolymerizing conditions (Carraway, C. A. C., Jung, G., and Carraway, K. L. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 430-434) revealed glycoproteins of the same Mr values, showing the same relative staining or labeling patterns as those observed with the microfilament cores. Gel filtration of high salt, high pH extracts of intact microvilli, microfilament cores, or transmembrane complexes showed that in all of these fractions the glycoproteins are associated in a very large, stable complex. The glycoprotein multimer was isolated essentially free of actin and other components by Sephacryl S-1000 chromatography of microvilli, microvillar membranes prepared at pH 11, microfilament cores, or transmembrane complex fractions in Triton X-100, 1 M KCl, glycine, pH 9.5. Purified glycoprotein complex bound actin when incubated under polymerizing conditions. The presence of the glycoprotein heteromultimer in both microfilament cores and transmembrane complex from isolated membranes and the association of the purified glycoprotein complex with actin are consistent with our hypothesis that the glycoprotein-containing transmembrane complex is an association site for microfilaments at the plasma membrane.     

Selective labeling of functional groups on membrane proteins or glycoproteins using reactive biotin derivatives and 125I-streptavidin

Amino groups, sulfhydryl groups or oxidation-induced aldehydes on erythrocyte membrane proteins and/or glycoproteins, were reacted with biotinyl N-hydroxysuccinimide ester (BNHS), 3-(N-maleimido-propionyl) biocytin (MPB) or biocytin hydrazide (BCHZ), respectively. The detergent-lysed biotinylated samples were subjected to SDS-polyacrylamide gel electrophoresis, and the proteins were transferred onto nitrocellulose membranes. The blot was then incubated with a solution containing 125I-streptavidin, and processed for autoradiography. The advantages of this approach over previously reported procedures for labeling the three functional groups include the following: extremely high sensitivity; short exposure times of autoradiograms and relatively low levels of radioactivity; single-step radiolabeling procedures subsequent to processing and handling of gels and no background labeling in control samples.     

Fluorescent labeling of the surface proteins of erythrocyte membranes using cycloheptaamylose-fluorescamine complex.

Fluorescamine was incorporated in cycloheptaamylose and the resulting complex was utilized as a new probe for fluorescent labeling of the surface proteins of erythrocytes. The complex reacted with erythrocyte membrane at 37°, pH 7 to 8 without using organic solvents. The major membrane proteins of ghosts were labeled, whereas the complex did not penetrate in the intact erythrocytes and labeled only surface proteins. Particular advantages are that the complex itself and its hydrolysis product were nonfluorescent when electrophoresed in sodium dodecyl sulfate polyacrylamide gels.     

Effects of pH and temperature on the interaction of an impermeant probe with surface proteins of the human red blood cell.

The conformation of the outer surface of the human red cell membrane has been studied under various conditions using the impermeant probe [125I]diazodiiodosulfanilic acid. At least seven polypeptides were labeled by the reagent, including the three extractable glycoproteins separable by the electrophoretic method employed. The Mr = 43,000 protein band was shown to contain two labeled species, one a glycoprotein, in addition to its major constituent, red cell actin. The extent and pattern of labeling were very sensitive to changes in pH and temperature. Total labeling increased with increasing pH and was greater at 4 degrees C than 37 degrees C. Binding of the probe to the Mr = 90,000 polypeptide and the major glycoprotein were relatively increased with increasing pH and temperature while opposite effects were observed for the Mr = 43,000 peptide(s). The pH effects on external membrane labeling were rapidly reversible. Results were similar in cells of different densities, suggesting that the pH and temperature effects were not related to cell age. The data presented emphasize the lability of membrane conformation and reactivity and thus the necessity to consider carefully the conditions of labeling in interpretation of studies using impermeant probes.