125I-glycoconjugate labels for identifying sites of protein catabolism in vivo: effect of structure and chemistry of coupling to protein on label entrapment in cells after protein degradation

Residualizing radioactive labels are designed to remain entrapped within cells following degradation of a carrier protein, and have been used for identification of the tissue and cellular sites of plasma protein catabolism. In this study we describe a convenient synthesis and purification of a series of 125I-labeled glycoconjugates, and an evaluation of their efficiency of retention in liver following degradation of a model carrier protein, asialofetuin. Glycoconjugates were prepared in 65-90% yield by reductive amination of reducing sugars with aromatic amines using NaBH3CN. The products were purified in a single ion-exchange chromatographic step, and then labeled with 125I. The derivatives prepared were mono-and disubstituted lactitol-,cellobiitol-and glucitol-[125I]tyramine and lactitol-[125I]tyrosine. 125I-Glycoconjugates were coupled to asialofetuin using either cyanuric chloride or, for lactose-containing labels, by treatment with galactose oxidase followed by reductive amination with NaBH3CN. Attachment of labels by either procedure did not affect the normal rapid clearance of asialofetuin from the rat circulation nor its uptake and degradation in liver lysosomes. Leakage of 125I-labeled degradation products from cells was measured by following the kinetics of loss of whole-body radioactivity. We observed that degradation products from larger, disubstituted glycoconjugates were retained more efficiently than those from smaller and monosubstituted derivatives, and that glycoconjugates coupled to protein via reductive amination were retained in the body more efficiently than those coupled by cyanuric chloride. Overall, dilactitol-[125I]tyramine coupled to protein by reductive amination was entrapped most efficiently in liver.     

Tritiation of glycoproteins

Human caeruloplasmin and α₁-acid glycoprotein and bovine fetuin were tritiated by reductive methylation of the ε-amino group of lysine residues. Tritiated caeruloplasmin retained its oxidase activity and molecular sieve chromatography of the labelled glycoproteins showed that reductive methylation did not significantly affect their molecular size. In experiments with rats, tritiated glycoproteins exhibited plasma half-lives similar to those obtained with the same glycoproteins labelled by other methods. Further, reductive methylation did not alter the property shared by all three glycoproteins to promptly disappear from the circulation after their desialylation and injection into rats and to appear in the liver parenchymal cells. Labelling of glycoproteins by reductive methylation may be useful in metabolic studies requiring the use of both glycoproteins and their asialo-derivatives.     

Leishmania donovani: identification of glycoproteins released by promastigotes during growth in vitro

Culture supernatants of metabolically labeled Leishmania donovani promastigotes were shown to contain approximately 40 electrophoretically distinct released protein compounds. Of these, approximately 20 were glycoproteins which contained terminal mannose residues, as judged by their specific binding to concanavalin A-agarose beads. Smaller subsets of the released glycoproteins were bound by agarose-conjugated Lens culinaris, Ricinus communis, and peanut lectins. Promastigote mannose-containing released glycoproteins were isolated by concanavalin A affinity chromatography and used to immunize a rabbit. This antiserum recognized the parasite-released mannose-containing glycoproteins, including the soluble acid phosphatase, both by immunoprecipitation from solution and in immunoblot analyses. In an antibody bridged enzyme assay this polyspecific serum was also capable of binding native acid phosphatase out of solution and bridging it to the denatured enzyme on SDS-PAGE transblots. Although this antiserum was raised against all 20 released glycoproteins, in agarose gels its major precipitin activity was against the secreted soluble acid phosphatase.     

An electron microscope autoradiographic study of the carbohydrate recognition systems in rat liver. I. Distribution of 125I-ligands among the liver cell types

Electron microscope autoradiography was used to study the cellular localization of seven glycoproteins rapidly cleared from the circulating plasma of rats and taken up by the liver. 1 and 15 min after intravenous administration of the 125I-glycoproteins, livers were fixed in situ by perfusion and processed for autoradiography. Autoradiographic grains in the developed sections were found to represent the intact 125I-ligand. A quantitative analysis of the distribution and concentration (density) of autoradiographic grains over the three major cell types of the liver was then performed. Three molecules, asialo-fetuin, asialo-orosomucoid, and lactosaminated RNase A dimer, the oligosaccharide chains of which terminate in galactose residues, were bound and internalized almost exclusively (greater than 90%) by hepatocytes. Conversely, four molecules, the oligosaccharide chains of which terminate in either N-acetyl-glucosamine (agalacto-orosomucoid) or mannose (ahexosamino-orosomucoid, preputial beta-glucuronidase, and mannobiosaminated RNase A dimer), were specifically bound and internalized by cells lining the blood sinusoids--that is, by Kupffer cells and endothelial cells. Endothelial cells were two to six times more active (on a cell volume basis) than were Kupffer cells in the internalization of these four 125I-ligands. Mannose and N-acetylglucosamine-terminated glycoproteins competed with each other for uptake into either endothelial cells or Kupffer cells, indicating that a single system recognized mannose or N-acetyl-glucosamine residues. Finally, agalacto-orosomucoid and ahexosamino-orosomucoid were also associated with hepatocytes, but competition experiments utilizing excess asialo-orosomucoid demonstrated that residual galactosyl residues were responsible for this association.     

Modification of the carbohydrate in ricin with metaperiodate and cyanoborohydride mixtures: effect on binding, uptake and toxicity to parenchymal and non-parenchymal cells of rat liver

The carbohydrate in the toxic glycoprotein ricin was chemically modified by simultaneous treatment with sodium metaperiodate and sodium cyanoborohydride. This treatment causes oxidative cleavage of the sugar residues and reduction of the aldehyde groups which are formed to primary alcohols. The modification markedly decreased the rapid removal of ricin from the blood by hepatic non-parenchymal cells with only a relatively small increase in accumulation of the toxin by parenchymal cells. Binding, uptake and toxicity of the modified ricin in primary monolayer cultures of hepatic non-parenchymal cells were all decreased to a much greater extent than in parenchymal cells. The results indicate that native ricin binds to non-parenchymal cells by a dual recognition process which involves both interaction of cell receptors with the mannose-containing oligosaccharides of the toxin and binding of ricin to galactose-containing glycoproteins and glycolipids on the cells. However, uptake and toxicity of native ricin in non-parenchymal cells appears to result principally from entry of the toxin through the mannose recognition pathway. By contrast, uptake and toxicity of the expressed essentially through the galactose-recognition route.     

Characterization of mucin isolated from rat tracheal transplants

Subcutaneous rat tracheal grafts yield several milligrams of secretions from which a homogeneous mucin fraction was isolated and purified. Histological evidence demonstrated that a normal mucociliary epithelium and mucous secretion were maintained for the 4-6 weeks of the experiment. The collected secretions were initially characterized by column chromatography on Sepharose CL-6B which separated the excluded high molecular weight mucins (unpurified mucin fraction) from most of the serum-type glycoproteins and proteins, including albumin. A reductive alkylation treatment of the unpurified mucin fraction followed by Sepharose CL-4B chromatography removed contaminating protein and most of the mannose-containing material from the mucin fraction. The void volume material from this column produced a single high molecular weight band upon sodium dodecyl sulfate agarose/acrylamide gel electrophoresis. The purified mucin fraction contained 16.5% protein and primarily galactose, N-acetylglucosamine, N-acetylgalactosamine, and sialic acid. This fraction also underwent beta-elimination in the presence of alkaline borohydride, demonstrating the presence of O-glycosidic linkages.     

Characterization of a novel alpha-D-mannosidase from rat brain microsomes

A new alpha-D-mannosidase has been identified in rat brain microsomes. The enzyme was purified 70-100-fold over the microsomal fraction by solubilization with Triton X-100, followed by ion exchange, concanavalin A-Sepharose, and hydroxylapatite chromatography. The purified enzyme is very active towards mannose-containing oligosaccharides and has a pH optimum of 6.0. Unlike rat liver endoplasmic reticulum alpha-D-mannosidase and both Golgi mannosidases IA and IB, which have substantial activity only towards alpha 1,2-linked mannosyl residues, the brain enzyme readily cleaves alpha 1,2-, alpha 1,3-, and alpha 1,6-linked mannosyl residues present in high mannose oligosaccharides. The brain enzyme is also different from liver Golgi mannosidase II in that it hydrolyzes (Man)5GlcNAc and (Man)4GlcNAc without their prior N-acetylglucosaminylation. Moreover, the facts that the ability of the enzyme to cleave GlcNAc(Man)5GlcNAc, the biological substrate for Golgi mannosidase II, is not inhibited by swainsonine, and that p-nitrophenyl alpha-D-mannoside is a poor substrate provide further evidence for major differences between the brain enzyme and mannosidase II. Inactivation studies and the co-purification of activities towards various substrates suggest that a single enzyme is responsible for all the activities found. In view of these results, it seems possible that, in rat brain, a single mannosidase cleaves asparagine-linked high mannose oligosaccharide to form the core Man3GlcNAc2 moiety, which would then be modified by various glycosyl transferases to form complex type glycoproteins.     

Effect of size and charge on endocytosis of lysozyme derivatives by sinusoidal rat liver cells in vivo

Hen egg-white lysozyme has been modified by intermolecular cross-linking with dimethyl suberimidate or by acylation with acetic or succinic anhydride. Retention of the native conformation of the modified enzyme was checked by measuring enzyme activity, resistance of disulfide bridges to reduction by thiols, and susceptibility to proteases.Unmodified lysozyme and its derivatives (labelled with ¹²⁵I) were intravenously injected into nephrectomized rats, and plasma clearance and uptake by liver cells were determined. Under these conditions, about 6% of the unmodified lysozyme was taken up by liver 15 min after injection. Cross-linking led to a greatly increased uptake (up to 89% of the dose in 15 min), whereas acylation reduced the uptake to 3–4%. Cell isolations showed that the unmodified enzyme and the cross-linked derivatives were taken up by sinusoidal cells. Differential fractionation of liver homogenates indicated that the unmodified enzyme was taken up in lysosomes. The cross-linked derivatives were concentrated in the nuclear and microsomal fractions as well as in the lysosomal fraction, suggesting adsorption on plasma membranes besides uptake in lysosomes.The experiments described in this paper, together with previous results on ribonuclease and lactate dehydrogenase, indicate that endocytosis of some proteins by sinusoidal liver cells is positively correlated with size and positive charge of the molecules.     

Glycoprotein biosynthesis in animal cells grown in suspension culture. Assembly of lipid-linked saccharides and formation of protein-bound ''high-mannose'' oligosaccharides.

Glycoprotein biosynthesis was studied with mouse L-cells grown in suspension culture. Glucose-deprived cells incorporated [3H]mannose into 'high-mannose' protein-bound oligosaccharides and a few relatively high-molecular-weight lipid-linked oligosaccharides. The latter were retained by DEAE-cellulose and turned over quite slowly during pulse--chase experiments. Increased heterogeneity in size of lipid-linked oligosaccharides developed during prolonged glucose deprivation. Sequential elongation of lipid-linked oligosaccharides was also observed, and conditions that prevented the assembly of the higher lipid-linked oligosaccharides also prevented the formation of the larger protein-bound 'high-mannose' oligosaccharides. In parallel experiments, [3H]mannose was incorporated into a total polyribosome fraction, suggesting that mannose residues were transferred co-translationally to nascent protein. Membrane preparations from these cells catalysed the assembly from UDP-N-acetyl-D-[6-3H]glucosamine and GDP-D-[U-14C]mannose of polyisoprenyl diphosphate derivatives whose oligosaccharide moieties were heterogeneous in size. Elongation of the N-acetyl-D-[6-3H]glucosamine-initiated glycolipids with mannose residues produced several higher lipid-linked oligosaccharides similar to those seen during glucose deprivation in vivo. Glucosylation of these mannose-containing oligosaccharides from UDP-D-[6-3H]glucose was restricted to those of a relatively high molecular weight. Protein-bound saccharides formed in vitro were mainly smaller in size than those assembled on the lipid acceptors. These results support the involvement of lipid-linked saccharides in the synthesis of asparagine-linked glycoproteins, but show both in vivo and in vitro that protein-bound 'high-mannose' oligosaccharide formation can occur independently of higher lipid-linked oligosaccharide synthesis.     

Concanavalin A induces interactions between surface glycoproteins and the platelet cytoskeleton

We have measured the association of platelet surface membrane proteins with Triton X-100 (Triton)-insoluble residues in platelets surface labeled with 125I. In both concanavalin A (Con A)-stimulated and resting platelets, this fraction is composed largely of polypeptides with apparent molecular weights of 45,000, 200,000, and 250,000 which comigrate with authentic actin, myosin heavy chain, and actin binding protein, respectively, as judged by PAGE in SDS. Less than 10% of the two major 125I-labeled surface glycoproteins, GPiib and GPIII, were associated with the Triton residue in resting platelets. Within 45 s after Con A addition, 80-95% of these two glycoproteins became associated with the Triton residue and the amount of sedimentable actin doubled. No cosedimentation of GPIIb and III with the cytoskeletal protein-containing Triton residue was seen when Con A was added to a Triton extract of resting cells, indicating that the sedimentation of GPIIb and III seen in Con A-stimulated platelets was not due to precipitation of the glycoproteins by Con A after detergent lysis. Treatment of Triton extracts of Con A-stimulated platelets with DNase I (deoxyribonucleate 5'-oligonucleotidido-hydrolase [EC 3.1.4.5]) inhibited the sedimentation of actin and the two surface glycoproteins in a dose-dependent manner. This inhibition of cosedimentation was not due to an effect of DNase I on Con A-glycoprotein interactions since these two glycoproteins could be quantitatively recovered by Con A- Sepharose affinity absorption in the presence of DNase I. When the Con A bound to the Triton residue was localized ultrastructurally, it was associated with cell-sized structures containing filamentous material. In intact cells, there was simultaneous immunofluorescent coredistribution of surface-bound Con A and myosin under conditions which induced a redistribution of platelet myosin. These data suggest that Con A can, in the intact platelet, induce physical interactions between certain surface glycoproteins and the internal cytoskeleton.     

The subcellular distribution of terminal N-acetylglucosamine moieties. Localization of a novel protein-saccharide linkage, O-linked GlcNAc

Previously our laboratory reported the discovery of a novel protein-saccharide linkage in which single N-acetylglucosamine (GlcNAc) residues are attached in O-linkages to protein (Torres, C. R., and Hart, G. W. (1984) J. Biol. Chem. 259, 3308-3317). This linkage was first found on plasma membrane proteins of living cells by galactosylation with bovine milk galactosyltransferase. Here we report the distribution of O-linked GlcNAc in highly enriched rat liver subcellular organelles. Nonidet P-40 solubilized organelles were labeled by galactosyltransferase with UDP-[3H]galactose, and the amount of radiolabel occurring on GlcNAc residues in O-linkages was assessed by its sensitivity to beta-elimination and by its resistance to deglycosylation with endo-beta-N-acetylglucosaminidase F. The presence of galactose-labeled O-linked GlcNAc residues was confirmed by high voltage paper electrophoresis. There is a 17-fold range per mg of protein in the amount of galactosylatable terminal GlcNAc residues found in the various organelles, as well as a wide range in the organelles' apparent content of O-linked GlcNAc residues. Nuclei and the soluble fraction of rat liver cells are particularly enriched with proteins bearing O-linked GlcNAc residues, although these residues are demonstrable in virtually all organelles tested. Furthermore, examination by sodium dodecyl sulfate-polyacrylamide gel electrophoresis reveals that many different organelle-specific proteins are glycosylated with O-linked GlcNAc residues. Because of the wide occurrence of this unique linkage, these data suggest that glycosylation with O-linked GlcNAc residues is not an exclusive marker for a particular organelle. In addition, we have surveyed the organelles for their content of glycoproteins bearing GlcNAc-terminated N-linked oligosaccharides. Our data demonstrate that there are significant amounts of these oligosaccharides in rough and stripped microsomes, nuclei, and nuclear envelopes. In light of evidence that terminal GlcNAc transferases are localized to the Golgi complex, these data suggest that there are glycoproteins which enter into the Golgi for processing and then are transported back into the rough endoplasmic reticulum, and possibly the nucleus.     

Biosynthetic studies on mannolipids and mannoproteins of normal and vitamin A-depleted hamster livers.

The incorporation of [1-14C]mannose into hamster liver glycolipids and glycoproteins was studied in normal and vitamin A-depleted hamsters. Severly (25% weight loss) and mildly (no weight loss) deficient animals were compared to vitamin A-fed controls. The incorporation of [14C]mannose into glycolipids and glycoproteins decreased in mild and severe vitamin A deficiency by 63-90% compared to vitamin A-fed animals. These results were essentially the same whether expressed per g of wet liver, per DNA or per protein. The size of the pools of mannose, glucose and galactose and their specific radioactivity in liver were determined by gas-liquid chromatography of the boronates of the hexitols (Eisenberg, Jr, F. (1972) Methods Enzymol. XXVIIIB, 168-178) in normal and vitamin A-deficient conditions. It was found that the amount of free hexoses per g of liver was very similar in normal and vitamin A-deficient conditions. The specific radioactivities for mannose and glucose were greater in vitamin A deficiency, thus excluding the possibility that the observed severe decrease in glycopeptide and glycolipid synthesis is a reflection of a similar decrease in the specific radioactivity of the precursor pools. Quantitation of mannose in glycoprotein showed a 79% decrease in vitamin A deficiency. Specific radioactivity of mannose in glycoproteins, 20 min after injection of the label, was 187 dpm/mug of mannose in the normal and 48 kpm/mug of mannose in the vitamin A-deficient livers. It is concluded that vitamin A is necessary for the biosynthesis of liver mannose-containing glycoproteins and glycolipids.     

Comparison of the Surface Proteins and Glycoproteins On Erythrocytes of Calves Before and During Infection With Babesia Bovis

The surface proteins and glycoproteins on red cells from normal and Babesia bovis-infected calf blood have been compared. Several radiolabeling probes were used to label specifically external membrane molecules which were then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and identified by autoradiography or fluorography. No differences were observed among the Coomassie Blue-stained membrane proteins of erythrocytes from individual uninfected calves. Comparison of red cells from these animals also indicated no qualitative differences in the surface proteins with accessible tyrosyl residues labeled by lactoperoxidase-catalyzed radioiodnation, although some quantitative variation in the uptake of radioactivity into particular proteins was observed. the major radioiodinated bands on normal bovine erythrocytes had Mr of 165, 130, 90, and 45 kiloDaltons. However, labeling of surface glycoproteins by the periodate/[³H]NaBH₄ and galactose oxidase (± neuraminidase)/[³H]NaBH₄ methods showed significant differences in the surface proteins of red cells from individual uninfected calves. of 14 animals tested, 5 had major labeled glycoproteins of unique Mr. No changes were observed in radioiodinated surface proteins of total red cell samples from infected calves with 0.5-6% parasitemia. Radioiodination of concentrated infected red cells from the same samples (concentrated by selective hypotonic lysis of uninfected erythrocytes in KC1) resulted in the labeling of 3 new surface proteins, with Mr of 118, 115, and 60 kiloDaltons. the same new ¹²⁵I-labeled bands were identified on infected cells from 3 avirulent strains of B. bovis used in vaccine production. Furthermore, in concentrated infected cells there was very poor radiolabeling of major bands strongly labeled on uninfected cells (Mr 165, 130, and 90 kiloDaltons), suggesting parasite-induced loss of these proteins. Although there were some differences in ³H-labeled surface glycoproteins of red cells from normal and. B. bovis -infected blood, they were restricted to minor labeled bands and were not seen consistently. the labeled surface glycoproteins of concentrated infected cells were very similar to those of the uninfected red blood cells from infected blood.     

Endocytosis and breakdown of ribonuclease oligomers by sinusoidal rat liver cells in vivo. II. Effect of charge.

Experiments presented in this paper suggest that sinusoidal rat liver cells recognize basic groups on proteins and that this recognition results in endocytosis of the proteins. Evidence for involvement of basic groups was obtained in two ways. Firstly, we changed the positively charged amino groups of the cross-linked ribonuclease molecules to neutral or negative by acetylation or succinylation, respectively. The modified proteins did not contain easily reducible disulfide bonds and they were not very sensitive to endoproteases, suggesting that they were not denatured by the acetylation procedures. Acetylation and succinylation reduced uptake of the injected cross-linked ribonuclease derivatives by liver and spleen and abolished their rapid clearance from plasma. In nephrectomized rats about 75% of the polymer, 36% of the acetylated polymer and 32% of the succinylated polymer were endocytosed by liver after 6 h. For the dimer fractions these values were 59%, 23% and 27%, respectively. Autoradiography and subcellular fractionation of liver 30 min post-injection localized the acetylated polymer in the lysosomal/microsomal fraction of sinusoidal liver cells, probably endothelial cells. Secondly, a positive correlation was found between binding of a number of ribonuclease derivatives to the cation exchanger SP-Sephadex G-25 and the rate of endocytosis by sinusoidal liver cells.     

Lectin-Carbohydrate Interactions: Fine Specificity Difference Between Two Mannose-Binding Proteins

Two types of rat mannose-binding proteins (MBPs), MBP-A (serum type) and MBP-C (liver type), have similar binding specificity for monosaccharide and similar binding site construct according to the X-ray structure, but exhibit different affinity toward natural oligosaccharides and glycoproteins. To understand the basis for this phenomenon, we used cloned fragment of MBP-A and -C (entire carbohydrate-recognition domain and a short connecting piece) that exists as stable trimers in various binding studies. Binding of a number of mannose-containing di- and tri-saccharides and high-mannose type oligosaccharides indicated that MBP-C has an extended binding area of weak interaction with the second and the third mannose residues, whereas MBP-A recognizes just a single mannose residue. In addition, MBP-C has a weak secondary binding site some 25 Å away from the primary site. These findings explain the higher affinity of MBP-C for natural high-mannose type oligosaccharides as compared to MBP-A. A huge affinity differential manifested by natural glycoproteins (e.g., inhibitory potency of thyroglobulin is ~200 fold higher for MBP-C than for MBP-A in a solid-phase assay) may be due to steric hindrance experienced by MBP-A in the competition assay, and suggests different arrangement of subunit in the MBP trimers.     

Endocytosis and breakdown of ribonuclease oligomers by sinusoidal rat liver cells in vivo. I. Effect of size.

Aspects of protein structure determining endocytosis of proteins by sinusoidal rat liver cells in vivo have been studied, using cross-linked or aggregated derivatives of bovine pancreatic ribonuclease A (labelled with 125I) as probes. Ribonuclease was cross-linked by reaction with dimethylsuberimidate, a way of modification that does not change the charge of the protein. Monomer, dimer and polymer fractions were isolated by gel filtration and characterized in respect of size and number of amino groups modified. Maintenance of enzyme activity, stability of disulfide bonds, and lack of susceptibility to endoproteases showed that the cross-linking procedure did not result in gross conformational changes of the ribonuclease molecules. Monomer, dimer and polymer fractions were injected into nephrectomized rats and plasma clearance and uptake in liver and spleen were determined. About 30% of the injected polymer fraction was found in liver 15 min after injection; for dimer and monomer fractions values of 6% and 2% of the dose were found. Similar differences were found in spleen. Autoradiography, cell isolation, and subcellular fractionation showed that in liver the radioactive proteins were taken up in lysosomes of sinusoidal cells. Similar results were obtained with fractions of aggregated ribonuclease prepared by freeze-drying the protein from 50% acetic acid. Our results demonstrate that the rate of uptake of the ribonuclease derivatives is positively correlated with the size of the molecules. Similarity of the results obtained with cross-linked and aggregated fractions suggests that the number of ribonuclease 'subunits'/molecule, rather than the procedures used to prepare the polymers, determine the rate of uptake by liver and spleen.     

Endocytes and breakdown of ribonuclease oligomers by sinusoidal rat liver cells in vivo: II. Effect of charge

Experiments presented in this paper suggest that sinusoidal rat liver cells recognize basic on proteins and that this recognition results in endocytosis of the proteins. Evidence for involvement of basic groups was obtained in two ways.Firstly, we changedd the opsitively charged amino groups of the cross-linked ribonuclease molecules to neutral or negative by acetylation or succinylation, respectively. The modified proteins did not contain easily reducible disulfide bonds and they were not very sensitive to endoproteases, suggesting that they were not denatured by the acetylation procedures. Acetylation and succinylation reduced uptake of the injected cross-linked ribonuclease derivatives by liver and spleen and abolsihed their rapid clearance from plasma. In nephrectomized rats about 75% of the polymer, 36% of the acetylated polumer and 32% of the succinylated polumer were endocytosed by liver after 6 h. For the dimer fraction these values were 59%, 23% and 27%, respectively. Autoradiography and subcellular fractionation of liver 30 min post-injection localized the acetylated polumer in the lysosomal/microsomal fraction of sinusoidal liver cessls, probably endothelial cells.Secondly, a positive correlation was found between binding of a number of ribonuclease derivatives of the cation exchanges SP-Sephadex G-25 and the rate of endocytosis by sinusoidal liver cells.     

Isolation and characterization of a mannan-binding protein from rabbit liver

A membrane protein which binds mannan has been isolated from rabbit liver by affinity chromatography. Upon polyacrylamide gel electrophoresis, a single major band was recovered with an estimated molecular weight of 31,000. When assayed as inhibitors, N-acetylmannosamine, N-acetylglucosamine, and mannose were potent inhibitors of mannan binding; N-acetylgalactosamine and mannose-6-phosphate were inert. Glycoproteins with terminal N-acetylglucosamine and/or mannose residues which are cleared rapidly from the circulation by the liver were the most potent inhibitors. On the basis of these results, it is proposed that the mannan-binding protein is the principle mediating the hepatic uptake of glycoproteins with terminal N-acetylglucosamine and/or mannose residues.     

Surface glycoproteomic analysis of hepatocellular carcinoma cells by affinity enrichment and mass spectrometric identification

Cell surface glycoproteins are one of the most frequently observed phenomena correlated with malignant growth. Hepatocellular carcinoma (HCC) is one of the most malignant tumors in the world. The majority of hepatocellular carcinoma cell surface proteins are modified by glycosylation in the process of tumor invasion and metastasis. Therefore, characterization of cell surface glycoproteins can provide important information for diagnosis and treatment of liver cancer, and also represent a promising source of potential diagnostic biomarkers and therapeutic targets for hepatocellular carcinoma. However, cell surface glycoproteins of HCC have been seldom identified by proteomics approaches because of their hydrophobic nature, poor solubility, and low abundance. The recently developed cell surface-capturing (CSC) technique was an approach specifically targeted at membrane glycoproteins involving the affinity capture of membrane glycoproteins using glycan biotinylation labeling on intact cell surfaces. To characterize the cell surface glycoproteome and probe the mechanism of tumor invasion and metastasis of HCC, we have modified and evaluated the cell surface-capturing strategy, and applied it for surface glycoproteomic analysis of hepatocellular carcinoma cells. In total, 119 glycosylation sites on 116 unique glycopeptides were identified, corresponding to 79 different protein species. Of these, 65 (54.6?%) new predicted glycosylation sites were identified that had not previously been determined experimentally. Among the identified glycoproteins, 82?% were classified as membrane proteins by a database search, 68?% had transmembrane domains (TMDs), and 24?% were predicted to contain 2-13 TMDs. Moreover, a total of 26 CD antigens with 50 glycopeptides were detected in the membrane glycoproteins of hepatocellular carcinoma cells, comprising 43?% of the total glycopeptides identified. Many of these identified glycoproteins are associated with cancer such as CD44, CD147 and EGFR. This is a systematic characterization of cell surface glycoproteins of HCC. The membrane glycoproteins identified in this study provide very useful information for probing the mechanism of liver cancer invasion and metastasis.     

Differential recognition of core and terminal portions of oligosaccharide ligands by carbohydrate-recognition domains of two mannose-binding proteins

Two different mannose-binding proteins (MBP-A and MBP-C), which show 56% sequence identity, are present in rat serum and liver. It has previously been shown that MBP-A binds to a range of monosaccharide-bovine serum albumin conjugates, and that, among oligosaccharide ligands tested, preferential binding is to terminal nonreducing N-acetylglucosamine residues of complex type N-linked oligosaccharides. In order to compare the binding specificity of MBP-C, an expression system has been developed for production of a fragment of this protein which contains the COOH-terminal carbohydrate-recognition domain. After radioiodination, the domain has been used to probe natural glycoproteins, neoglycoproteins, and neoglycolipids. Like MBP-A, MBP-C binds several different monosaccharides conjugated to bovine serum albumin, including mannose, fucose, and N-acetylglucosamine, although binding to the last of these is relatively weaker than observed for MBP-A. The results of binding to natural glycoproteins and to neoglycolipids containing oligosaccharides derived from these proteins are most compatible with the interpretation that MBP-C interacts primarily with the trimannosyl core of complex N-linked oligosaccharides, with additional ligands being terminal fucose and perhaps also peripheral mannose residues of high mannose type oligosaccharides. This binding specificity is thus quite distinct from that of MBP-A. The presence of multiple MBPs with distinct binding specificities in preparations derived from serum and liver explains conflicting conclusions which have been reached about carbohydrate recognition by these proteins.