ISOLATION AND CHARACTERIZATION OF A SOLUBLE GLUCOSE-CONTAINING SIALOGLYCOPROTEIN FROM THE CORTICAL GREY MATTER OF CALF BRAIN

A sialoglycoprotein has been isolated from the cortical grey matter of calf brain after homogenization in 0.32 M-sucrose or in 0.15 M-NaCl. The sialoglycoprotein is present in the supernatant obtained after centrifugation at 100,000 g for 60 min. It is designated GP-350 on account of its elution with 350 mM-NaCl on a DEAE-cellulose column. From DEAE-cellulose chromatography it is evident that compounds comparable to GP-350 occur in the brain of calf and sheep, whereas they seem to be absent in calf liver and kidney. After purification, with polyacrylamide gel electrophoresis only one band can be shown both at pH 8.9 and 7.5. GP-350 consists of about 83 percent of protein and about 17 per cent of carbohydrate. The polypeptide core has an acidic character: amino acid analysis gives 26 per cent for glutamic acid plus aspartic acid and their amides, with a ratio of acidic to basic amino acids of 3.3. The carbohydrate moiety contains 2.4% sialic acid, 5.5 % hexosamine and 9.4% hexose. It is remarkable that this brain sialoglycoprotein comprises 4% glucose. Care was taken to prevent contamination with glucose-containing materials during the purification procedure of GP-350. The complete absence of other glucose-containing compounds which occur in brain, Le. glycogen and gangliosides, was demonstrated. GP-350 accounts for at least 3 per cent of the total saline-extractable protein and about 20 per cent of the total saline-extractable protein-bound sialic acid of the cortical grey matter of calf brain. These percentages correspond to 390 pg of protein and to 14 μg of sialic acid per g wet weight. GP-350 remains soluble when the pH is brought to 3.9 or when ethanol is added to 70 % (v/v).     

Molecular cloning of a human apoC-III variant: Thr 74----Ala 74 mutation prevents O-glycosylation

Apolipoprotein C-III (apoC-III) is a major protein of very low density lipoprotein (VLDL). The apoC-III polypeptide contains a carbohydrate chain containing galactosamine, galactose, and sialic acid attached in O-linkage to a threonine residue at position 74. We have cloned the apoC-III gene from a subject whose serum contained unusually high amounts of apoC-III lacking the carbohydrate moiety (C-III-0). DNA sequence analysis of the cloned gene revealed a single nucleotide substitution (A----G) that encodes an alanine at position 74 instead of the normal threonine. As a result of this amino acid replacement, the mutant apoC-III polypeptide is not glycosylated. The mutation in the apoC-III gene creates a novel AluI site that permits diagnosis of the change by Southern blotting of genomic DNA.     

GP-350, A SIALOGLYCOPROTEIN FROM CALF BRAIN: ITS SUBCELLULAR LOCALIZATION AND OCCURRENCE IN VARIOUS BRAIN AREAS

Abstract— A membrane-bound form of GP-350, a sialoglycoprotein from calf brain has been shown to occur in the crude mitochondrial fraction (P₂). After subfractionation on a discontinuous sucrose gradient, consisting of 0.8 and 1.2 m -sucrose, GP-350 was immunologically only detectable in the synaptosomal fraction. After further separation of the lysed synaptosomal fraction on a discontinuous sucrose gradient (0.4, 0.8 and 1.2 m ) GP-350 could be detected only in the 0.8–1.2 m -sucrose interface.
The membrane-bound GP-350 from the cerebellar grey matter was purified and analysed. The amino acid composition and the data obtained for galactose, galactosamine, glucosamine and sialic acid were quite similar to those of the soluble GP-350, indicating their identity, which was sustained by immunodif-fusion, immunoelectrophoresis and polyacrylamide gel electrophoresis.
The membrane-bound GP-350 was isolated from 15 different brain areas. Per g wet wt at least 60 μg ( corpora quadrigemina inferior ) and at most 470 μg ( thalamus ) of GP-350 protein were obtained. Compared to the soluble GP-350 protein 10–52 per cent could be isolated from the crude mitochondrial fraction. Our results on GP-350 indicate an association with membranes of nerve endings.     

The isolation and partial characterization of the major glycoprotein (LGP-I) from the articular lubricating fraction from bovine synovial fluid.

The articular lubricating fraction from bovine synovial fluid was prepared by repeated fractionation in three consecutive CsCl density gradients to remove completely traces of hyaluronic acid. The major glycoprotein consituent (LGP-I) was then isolated by repeated gel-permeation chromatography. The yield of the LGP-I component was about 20 mg/litre of synovial fluid. Sedimentation-equilibrium measurements showed that this glycoprotein was homogeneous and the mol.wt. was calculated to be 227500. Amino acids represented 43% (w/w) and carbohydrate constituents 44% (w/w) of the molecule. Threonine, glutamic acid, proline and lysine (224, 127, 242 and 128 residues/1000 residues respectively) were the major amino acids. Galactosamine, galactose and N-acetylneuraminic acid (202, 162 and 114 residues/molecule of LGP-I component respectively) accounted for 98% of the total carbohydrate residues present. Small amounts of mannose and glucosamine (1 and 9mol respectively/mol of LGP-I component) were also present. After treatment of LGP-I component with alkali and NaB3H4 radioactivity was incorporated into alpha-aminobutyric acid and alanine in a molar ratio of 4:1, and radioactive galactosaminitol was isolated by ion-exchange chromatography from a cleaved oligosaccharide fraction. These data demonstrate the presence of threonine and serine -O-GalNAc linkages, but only 25% of the theoretical likages involving threonine were cleaved by a beta-elimination reaction. Digestion of LGP-I component with Pronase followed by chromatography on DEAE-cellulose yielded glycopeptide fractions with a similar amino acid and carbohydrate composition to the intact molecule. Treatment of desialylated and intact LGP-I component with galactose oxidase followed by reduction with NaB3H4 revealed the presence of 52mol of terminal galactose in the intact molecule and 153mol of galactose/mol of LGP-I component after treatment with neuraminidase. The data indicate the LGP-I component is composed of a single polypeptide chain containg more than 150 oligaosaccharide side chains composed of O-GaINAc-Gal distributed over the length of the peptide chain and that terminal sialic acid residues are linked to galactose in two-thirds of these side chains.     

The vitelline envelope of eggs from the giant keyhole limpet Megathura crenulata. I. Chemical composition and structural studies.

The egg vitelline envelope of the marine invertebrate Megathura crenulata is a glycoprotein composed of 37.3 mol % protein and 62.7 mol % carbohydrate. Of the total amino acid content, 61 mol % consists of a single amino acid, threonine. The carbohydrate content includes galactosamine, galactose, and fucose. The molar ratio of threonine to galactosamine is about 1:1. Most of the threonine residues are linked to galactosamine residues via O-glycosidic bonds. A single peptide that was purified following alkaline borohydride treatment of the vitelline envelope had the structure: Abu-Pro-Abu-(Abu6, Pro1, Thr1), where Abu is 2-aminobutyric acid. Several sugar residues have been isolated following the alkaline hydrolysis of the vitelline envelope that include an octasaccharide Gal4Fu4, an hexasaccharide Gal3Fu3, a trisaccharide Gal3, fucose, and galactose. It is proposed that the vitelline envelope of Megathura crenulata eggs is composed of polypeptide chains built to a large extent of closely spaced threonine residues. Almost every threonine residue is linked to a saccharide moiety.     

The isolation and characterization of glycopeptides and mucopolysaccharides from plasma membranes of an ascites hepatoma, AH 130.

Plasma membranes were isolated from an ascites hepatoma, AH 130, by the fluorescein mercuric acetate (FMA) method. Glycopeptides and mucopolysaccharides were prepared by digesting the membranes with pronase, then by fractionating the digest chromatographically and electrophoretically. Isolated fractions were analyzed for their amino acid and carbohydrate compositions. Results were compared with those for corresponding fractions from AH 66 (J. Biochem. 76, 319-333 (1974)). Mucopolysaccharides and a series of glycopeptides were isolated from the fraction excluded from Sephadex G-50. The mucopolysaccharides were identified as a family of heparan sulfates with different electrophoretic mobilities. The glycopeptides contained serine, threonine, galactose, galactosamine, glucosamine, and sialic acid as the major constituents as aspartic acid and mannose as minor ones. This suggests that most of the carbohydrate moieties are linked to serine or threonine (O-glycosidic), and that some are linked to asparagine (N-glycosidic). No nearly purely O-glycosidic glycopeptides were found in this fraction from AH 130, through they were the major glycopeptides from the AH 66 plasma membranes. In the fraction included in the gel, glycopeptides containing fucose, galactose, mannose, glucosamine, glaactosamine, and sialic acid were found. The presence of galactosamine suggests that some of the glycopeptides are O-glycosidic though most are N-glycosidic. In the corresponding fraction from AH 66, nearly purely N-glycosidic glycopeptides were found.     

The isolation and characterization of glycopeptides and mucopolysaccharides from plasma membranes of an ascites hepatoma, AH 130 FN.

Plasma membranes were isolated from an ascites hepatoma, AH 130 FN, a free-cell type subline of AH 130, by the fluorescein mercuric acetate (FMA) method. Glycopeptides and mucopolysaccharides were prepared from the membranes by pronase digestion then fractionated chromatographically and electrophoretically. Isolated fractions were analyzed for amino acid and carbohydrate compositions. The results were compared with those for corresponding fractions from AH 66 and AH 130 ((1974) J. Biochem. 76, 319-333; (1975) ibid., 78, 863-872). The fraction excluded from Sephadex G-50 contained mucopolysaccharides and a series of glycopeptides. The mucopolysaccharides were identified as chondroitin sulfate A on the basis of their chemical composition, electrophoretic behavior on cellulose acetate and digestibility with chondroitinase AC [EC 4.2.2.5]. This contrasts with previous findings that mucopolysaccharides from the corresponding fractions from AH 130 and AH 66 were heparan sulfate. The chemical composition of the glycopeptides, which showed high contents of threonine, serine, galactose, galactosamine, glucosamine, and sialic acid, indicated the presence of glycopeptides with O-glycosidic linkages. The glycopeptides also contained a small but significant amount of aspartic acid, suggesting that N-glycosidic glycopeptides were also contained in this fraction. The fraction included in Sepnadex G-50 contaoned N-glycosidic glycopeptides as major components, since the carbohydrate moieties were composed of fucose, galactose, mannose, glucosamine, sialic acid, and a smaller amount of galactosamine. The presence of galactosamine suggested that O-glycosidic glycopeptides were present as minor components. Glycopeptides with both O- and N-glycosidic linkages were isolated from AH 130, but not from AH 66.     

Separation of both the Bbeta- and the gamma-polypeptide chains of human fibrinogen into two main types which differ in sialic acid content

The gamma- and Bbeta-polypeptide chains of purified human fibrinogen have each been resolved into two major species: gammaL and gammaR and BbetaL and BbetaR. These molecular variants, separable on CM-cellulose, differ from each other in sialic acid content: approximately 2 residues of sialic acid per molecule of polypeptide chain for the L species to 1 residue of sialic acid per molecule for the R species. The two types of each polypeptide are demonstrable in preparations of fibrinogen from single donors as well as in pooled fibrinogen. The L and R forms of the gamma chains or the Bbeta chains do not differ in their electrophoretic mobility in sodium dodecyl sulfate-polyacrylamide gels, suggesting that they are similar in molecular weight. They are also indistinguishable in polyacrylamide gels in the presence of urea at pH 2.7. Maps of ninhydrin-positive tryptic peptides of the L and R forms of the gamma chain displayed differences within a small group of peptides which have been shown to contain the sialic acid residues present in the gamma-polypeptides. No differences between the peptide maps of BbetaL and BbetaR chains were obvious. A larger ratio of L/R in the gamma and Bbeta chains of dysfibrinogenemia fibrinogen "Zürich II" than in those of normal fibrinogen explains the higher content of sialic acid measured in the native Zürich II fibrinogen molecule.     

A new neuraminic acid derivative and three types of glycopeptides isolated from the Cuvierian tubules of the sea cucumber Holothuria forskali

The Cuvierian tubules of Holothuria forskali Della Chiaje, a sea cucumber found in the Adriatic Sea, were investigated with regard to their carbohydrate moieties. From a Pronase digest of these tubules three types of carbohydrate units were isolated and characterized. 1. A high-molecular-weight glycopeptide fraction was shown to contain sulphated polyfucose, galactosamine, a uronic acid and a previously unknown neuraminic acid derivative. The sulphate was shown by i.r. analysis to be present as an O-ester. The carbohydrate unit was linked O-glycosidically to threonine and serine residues in the polypeptide chain. The hitherto unknown neuraminic acid derivative (Hf-neuraminic acid) was resistant to enzymic cleavage by neuraminidase, even after mild alkaline hydrolysis for the removal of O-acyl residues. However, the glycosidic linkage of this compound to the other part of the carbohydrate moiety was readily cleaved by mild acid hydrolysis. Its chromatographic properties distinguished Hf-neuraminic acid from other known neuraminic acid derivatives (N-acetyl-, NO-diacetyl-, NOO-triacetyl- and N-glycollyl-neuraminic acid). Further, this acidic sugar was shown to possess neuraminic acid as its basic structure. Thus, an as yet unknown substituent lends the distinct properties to Hf-neuraminic acid. 2. The carbohydrate composition of a second glycopeptide fraction consisting of a derivative of neuraminic acid, galactose, mannose and glucosamine was similar to that of the well-known carbohydrate groups of the globular glycoproteins. 3. The third fraction contained two glycopeptides containing the disaccharide, glucosylgalactose, which was shown to be linked to the hydroxyl group of hydroxylysine residues of a collagen-like protein. Approximately half of these residues were glycosylated. In addition to these glycopeptides, a small amount of a third glycopeptide that carried only a galactosyl residue was detected. The amino acid sequence of the two major compounds were found to be Gly-Ala-Hyl*-Gly-Ser and Gly-Pro-Hyl*-Gly-Asp, where Hyl* represents a glycosylated amino acid residue.     

Purification, composition, and structure of macrophage adhesion molecule

Macrophage adhesion molecule (MAM) is a surface heterodimer consisting of the trypsin- and plasmin-sensitive glycopeptide gp160 (MAM-alpha) and the glycopeptide gp93 (MAM-beta). MAM, which is the guinea pig analogue of Mo1 and Mac-1, was purified from detergent lysates of peritoneal neutrophils by lentil lectin chromatography and M2-antibody chromatography. The pure heterodimer molecule was dissociated by acidic conditions (pH 3.5), and MAM-alpha and MAM-beta were separated by M7-antibody chromatography. MAM-beta is an approximately 640 amino acid residue polypeptide with exceptionally high cysteine content. At 7.2 residues per 100 amino acids, Cys/2 of MAM-beta is more than 3 times the mean for 200 purified proteins. Reactivity with six beta-subunit-specific monoclonal antibodies recognizing at least four epitopes demonstrated that intrapeptide disulfide bonds are required to maintain the structure of MAM-beta. All six antibodies failed to react when MAM-beta was treated with reducing agents. MAM-beta is 18% carbohydrate; the major monosaccharides are mannose, N-acetylglucosamine, galactose, and sialic acid. MAM-beta is estimated to contain five to six N-linked carbohydrate units. MAM-alpha is an approximately 1100-residue polypeptide with lower Cys/2 content (2.0 residues per 100 amino acid residues). MAM-alpha is 21% carbohydrate. The major monosaccharides are mannose, N-acetylglucosamine, galactose, and sialic acid; the mannose content is higher in MAM-alpha than MAM-beta. MAM-alpha is estimated to contain 12 N-linked carbohydrate units.     

The oligosaccharide units of rabbit immunoglobulin G. Multiple carbohydrate attachment sites

The carbohydrate structure of rabbit immunoglobulin G isolated from pooled sera was investigated. Amino sugar analysis of fragments of the molecule allowed three oligosaccharides to be located at separate sites on the H-chain. The corresponding glycopeptides were isolated. The average composition of the C1-oligosaccharide was 2 glucosamine, 1 mannose and 2 galactose residues. It appeared to be present in approx. 15% of the H-chains; the carbohydrate was coupled through the amide group of asparagine in a peptide containing asparagine, glycine and threonine within the Fd fragment of the molecule. The average composition of the C2-oligosaccharide was 1 galactosamine, 1 galactose and either 1 or 2 sialic acid residues. It was present on approx. 40% of the H-chains and was attached glycosidically to the OH group of threonine in a peptide Ser-Lys-Pro-Thr-Cys-Pro-Pro-Glu-Leu in the hinge region of the molecule. The average composition of the C3-oligosaccharide was 5 glucosamine, 2 galactose, 5 mannose, 1 fucose and 1 sialic acid residue. It appeared to be present in all the H-chains and was linked through the amide group of asparagine in a peptide Gln-Gln-Phe-Asn-Ser-Thr-Ile-Arg within the Fc fragment of the molecule.     

Delta 6-desaturase activity in liver microsomes of rats fed diets enriched with cholesterol and/or omega 3 fatty acids.

A glycoprotein antigen was purified from human brain by immunoaffinity chromatography using the 44D10-monoclonal IgG, and its chemical nature was investigated. The yield of antigen was estimated at 91% and a 4340-fold purification was obtained relative to the white-matter homogenate. The antigen preparation from brain was further purified by preparative SDS/polyacrylamide-gel electrophoresis (PAGE) to obtain a glycoprotein with an Mr of 80,000 consisting of a single polypeptide. Amino acid analyses revealed a composition which was high in acidic and neutral amino acids, and low in basic residues. The presence of both glucosamine and galactosamine suggested that the glycoprotein contained both N- and O-linked glycans. Neutral sugar analyses showed that fucose, galactose and mannose were present. An assay for sialic acid determined that there were approximately 20 mol of sialic acid per mol of glycoprotein. Chemical cleavage of oligosaccharides by trifluoromethanesulphonic acid followed by SDS/PAGE showed that carbohydrate accounted for 25,000 of the 80,000-Mr glycoprotein.     

Structural studies on a glycoprotein isolated from alveoli of patients with alveolar proteinosis.

A major glycoprotein 36 000 molecular weight) has been isolated from lung lavage of patients with alveolar proteinosis and found to contain five residues of hydroxyproline, fifty residues of glycine, three residues of methionine, 3 mol of sialic acid, 4.4 mol of mannose, 4.0 mol of galactose, 6.0 mol of glucosamine, and 1 mol of fucose. Cyanogen bromide (CNBr) treatment of the glycoprotein resulted, as expected, in four peptides of apparent molecular weights of 18 000, 12 000, 5000 and 1000, respectively. The chemical compositions of the CNBr peptides indicate the presence of hydroxyproline and high amounts of glycine in all but one of the peptides; two of the four CNBr peptides contain carbohydrate. Gel filtration, acrylamide gel electrophoresis and end-group analyses of the native glycoprotein and its CNBr peptides indicate that the peptides are homogeneous. End-group analyses of the CNBr cleavage products assign the 18 000 molecular weight peptide to the NH2-terminal portion and the 1000 molecular weight peptide to the COOH-terminal portion of the native glycoprotein molecule. Pronase digestion of the 36 000 molecular weight glycoprotein, followed by gel filtration and cation exchange chromatography, resulted in two fractions. One fraction was acidic and contained all the carbohydrate, a high content of aspartic acid and no hydroxyproline. The other fraction was basic and contained 8.4% hydroxyproline, 14% proline, 28% glycine and no carbohydrate, suggesting the presence of collagen-like sequence in the peptide chain. Paper electrophoresis of the basic fraction demonstrated two components, the amino acid compositions of which are identical to those of collagen. Partial amino-terminal sequence analysis of one of the CNBr peptides (18 000 molecular weight) indicated the presence of -Fly-Pro-HyP-Gly-sequence in the peptide chain, which confirms our suggestion that collagen-like regions are present in the native glycoprotein molecule. Limited acid hydrolysis of the acidic fraction and subsequent fractionation of the acid hydrolysate using Dowex column yielded a fraction which produced brown colour with ninhydrin reagent. Paper chromatography of this fraction demonstrated a large component which also stained brown with ninhydrin reagent. After acid hydrolysis, this component was found to consist of equal amounts of asparitic acid and glucosamine, indicating that the N-acetylglucosamine of the oligosaccharides is linked to the asparagine residue of the peptide. No serine or threonine linkages are present.     

THE LYSOSOME PERIPHERY: BIOCHEMICAL AND ELECTROKINETIC PROPERTIES OF THE TRITOSOME SURFACE

Normal rat liver lysosomes were isolated by the technique of loading with Triton WR-1339. Purity of the preparation was monitored with marker enzymes; a high enrichment in acid hydrolases was obtained in the tritosome fraction. In 0.0145 M NaCl, 4.5% sorbitol, 0.6 mM NaHCO₃, pH 7.2 at 25°C the tritosomes had an electrophoretic mobility of -1.77 ± 0.02 µm/s/V/cm, a zeta potential of 23.2 mV, a surface charge of 1970 esu/cm², and 33,000 electrons per particle surface assuming a tritosome diameter of 5 x 10^-7 m. Treatment of the tritosomes with 50 µg neuraminidase/mg tritosome protein lowered the electrophoretic mobility of the tritosome to -1.23 ± 0.02 µm/s/V/cm under the same conditions and caused the release of 2.01 µg sialic acid/mg tritosome protein. Treatment of the tritosomes with hyaluronidase did not affect their electrophoretic mobility, while trypsin treatment elevated the net negative electrophoretic mobility of the tritosomes. Tritosome electrophoretic mobilities indicated a homogeneous tritosome population and varied greatly with ionic strength of the suspending media. pH vs. electrophoretic mobility curves indicated the tritosome periphery to contain an acid-dissociable group which likely represents the carboxyl group of N-acetylneuraminic acid; this was not conclusively proven, however, since the tritosomes lysed below a pH of 4 in the present system. Total tritosome carbohydrate (anthrone-positive material as glucose equivalents) was 0.19 mg/mg tritosome protein while total sialic acid was 3.8 µg (11.4 nmol)/mg tritosome protein. A tritosome "membrane" fraction was prepared by osmotic shock, homogenization, and sedimentation. Approximately 25% of the total tritosome protein was present in this fraction. Analysis by gas-liquid chromatography and amino acid analyzer showed the following carbohydrate composition of the tritosome membrane fraction (in microgram per milligram tritosome membrane protein): N-acetylneuraminic acid, 14.8 ± 3; glucosamine, 24 ± 3; galactosamine, 10 ± 2; glucose, 21 ± 2; galactose, 26 ± 2; mannose, 31 ± 5; fucose, 7 ± 1; xylose, 0; and arabinose, 0. The results indicate that the tritosome periphery is characterized by external terminal sialic acid residues and an extensive complement of glycoconjugates. Essentially all the tritosome N-acetylneuraminic acid is located in the membrane and about 53% of it is neuraminidase susceptible.     

The ninth component of human complement: purification and physicochemical characterization

A procedure for the isolation of the human complement (C) protein C9 is described. The procedure allowin. The purified protein has the electrophoretic mobility of an alpha-globulin, and is a single polypeptide chain with a m.w. of 71,000. No impurities were detected either on gel electrophoretic or immunochemical examination. C9 is a glycoprotein containing 7.8% carbohydrate, and in terms of residues per mole, 3.0 glucosamine, 17.6 neutral hexose, and 7.4 sialic acid. Its amino acid composition is typical of a globular serum protein. Upon automated Edman degradation of reduced and alkylated C9, no amino acid residues were released, suggesting a blocked N-terminus. The concentration of C9 in normal human serum is 58 +/- 8 microgram/ml. A high titer rabbit antiserum was produced and employed to immunochemically deplete serum of C9. The CH50 of the C9-depleted serum was identical to that of whole human serum; however, membrane fragments of erythrocytes lysed by C9-depleted serum lacked the typical ultrastructural C lesions, which constitute the dimeric membrane attack complex.     

Nature of the Carbohydrate Side Chains and Their Linkage to the Protein in Chicken Egg White Ovomucin

Some proteolytic digests of chicken egg white ovomucin were fractionated and characterized. It was shown that there are at least three types of carbohydrate side chains in ovomucin; a chain composed of galactose, galactosamine, sialic acid and sulfate in a molar ratio of about 1: 1: 1: 1, a chain composed of galactose and glucosamine in a molar ratio of about 1:1, and a chain composed of mannose and glucosamine in a molar ratio of about 1:1. It was also shown that the carbohydrate side chain composed of galactose, galactosamine, sialic acid and sulfate is linked O-glycosidically to serine or threonine in the protein core of ovomucin.     

Structural studies on rabbit transferrin: isolation and characterization of the glycopeptides

The structure of rabbit transferrin was investigated with regard to number, size, and composition of the heteropolysaccharide units and their relative location on the polypeptide chain. The composition and molecular weight of the Pronase glycopeptides revealed that rabbit transferrin contains two heteropolysaccharide units, each composed of 2 sialic acid residues, 2 galactose residues, 3 mannose residues, and 4-N-acetylglucosamine residues. The composition and molecular weight of the tryptic glycopeptides further substantiated the existence of two identical heteropolysaccharide units and revealed that both units have identical amino acid residues in the immediate vicinity of the carbohydrate attachment sites to the polypeptide chain, suggesting a sequence homology surrounding the two glycosylation sites. Characterization of the cyanogen bromide fragments from rabbit transferrin indicated that both heteropolysaccharide units are located within a single polypeptide fragment representing approximately one-third of the molecule.     

The effect of neuraminidase on genetic variants of alpha anitrypsin.

Sera of Pi types M, F, S, Z, IM, FM, MS, and MZ were incubated with neuraminidase and the reaction products followed by electrophoresis. The alpha1 antitrypsin components showed a series of changes in mobility as sialic residues were removed. Removal of sialic acid was confirmed by chemical assay. Results of studies with two different electrophoretic systems suggested that the Z type alpha1 antitrypsin has less sialic acid than the M, F, and S types. There was no evidence that other genetic variants have a reduced sialic acid content. The two major bands of alpha1 antitrypsin seen in certain electrophoretic systems may reflect a difference of one sialic acid residue. It is proposed that the Z protein lacks a carbohydrate chain with two terminal sialic acid residues. This carbohydrate deficiency results in lack of secretion of type Z alpha1 antitrypsin from the endoplasmic reticulum, perhaps because of binding to sites specific for the incomplete glycoprotein or because of aggregation of the Z asialo protein. A carbohydrate chain could be prevented from attaching to the Z type either because of a conformational change or because of the replacement of a carbohydrate-binding asparagine residue in the Z protein.     

Thyroid cell surface glycoproteins. Nature and disposition of carbohydrate units and evaluation of their blood group I activity

The distribution along the polypeptide of the carbohydrate units of two major calf thyroid cell surface glycoproteins, GP-1 and GP-3, was obtained from a study of their glycopeptides obtained after Pronase digestion. The GP-3 molecule (Mr = 20,000) yielded two large glycopeptides (Mr = 9,500 and 7,000) in equimolar amounts which each consisted of one N-linked (Mr = 5,400) and several small O-linked oligosaccharides accounting for a total of nine carbohydrate attachment sites in a 27-amino acid residue segment of the peptide chain. The Pronase treatment of GP-1 (Mr = 100,000) revealed the presence of a large protease-resistant fragment (Mr = 50,000) which contained 34 carbohydrate units (eight N-linked and 26 O-linked) in a segment of 105 amino acids. In addition to these densely glycosylated peptides (one glycosylation site/3 amino acid residues), small glycopeptides with polymannose saccharide units were found in the digests of both proteins. The occurrence of repeating N-acetyllactosamine sequences in the N-linked carbohydrate units of GP-1 and GP-3 was suggested by the composition and size of the oligosaccharides released by hydrazinolysis and was demonstrated by endo-beta-galactosidase treatment. The cleavage products from digestion with this enzyme were identified as NeuAc alpha 2----6Gal beta 1----4GlcNAc beta 1----3Gal, Gal alpha 1----3Gal beta 1----4GlcNAc beta 1----3Gal, Gal beta 1----4GlcNAc beta 1----3Gal, and GlcNAc beta 1----3Gal with the tetrasaccharides constituting the predominant species. The terminal alpha-D-Gal residues accounted for the binding of GP-1 and GP-3 glycopeptides to Bandeiraea simplicifolia I-agarose; concanavalin A-Sepharose affinity chromatography indicated that most of the N-linked carbohydrate units of both glycoproteins contained more than two branches. Difference in the branching on the poly-N-acetyllactosamine sequences of GP-1 and GP-3 was suggested by the finding that only the latter glycoprotein, as well as its glycopeptides, reacted with anti-blood group I antibodies; neither glycoprotein demonstrated blood group i antigenicity. Examination of cultured thyroid follicular cells revealed that both I and i determinants were present at the cell surface.     

Studies on protein–polysaccharides from pig laryngeal cartilage. Heterogeneity, fractionation and characterization

1. Protein-polysaccharides from pig laryngeal cartilage extracted by two procedures described in the preceding paper (Tsiganos & Muir, 1969) were shown to consist of macromolecules of various sizes as assessed by gel filtration in 4% and 6% agarose. 2. A larger proportion of the smaller molecules was present in the preparation obtained by brief extraction in iso-osmotic sodium acetate (procedure I) than in that obtained by more prolonged extraction in 10% (w/v) calcium chloride (procedure II). 3. Two fractions were separated by gel filtration in 6% agarose and by electrophoresis in compressed glass fibre. These fractions differed in chemical composition and in antigenic determinants. The gel-retarded fraction R and that of higher electrophoretic mobility possessed the same single antigen, whereas the gel-excluded fraction E and the slower electrophoretic fraction contained all the antigens of the starting material including that of fraction R. 4. Five N-terminal amino acid residues were identified in preparation I and fraction E, only two of which were present in fraction R. 5. The relative proportions of gel-excluded and gel-retarded fractions did not change when solutions of high ionic strength, urea or guanidine hydrochloride were used for elution. 6. The differences in chemical and amino acid composition between fractions R and E showed that the latter was not a simple aggregate of the former. Fraction E contained more basic and aromatic amino acids, and some methionine and cystine; the last two were absent from fraction R. Hydroxyproline was not detected in either fraction. 7. The number of glycosidic linkages in both fractions was estimated by alkaline beta-elimination. Appreciable amounts of threonine as well as serine were destroyed in both fractions. An average chain length for chondroitin sulphate was calculated from the galactosamine content of both fractions and the amounts of hydroxy amino acid destroyed. Average chain lengths were also calculated from the xylose and galactosamine content of each fraction. Each independent method gave a value of approximately 28 disaccharide units for the chain length in both fractions and hence their difference in size could not be explained by differences in the length of carbohydrate chains. 8. All fractions contained glucosamine, which was attributed to keratan sulphate. Content of both protein and keratan sulphate increased with the size of the macromolecules. 9. It is suggested, from these results, that chondroitin sulphate-protein complexes normally exist as a heterogeneous population of macromolecules in cartilage, and that keratan sulphate is involved in the formation of larger molecules.