A novel monoantennary complex-type sugar chain found in octopus rhodopsin: occurrence of the Gal{beta}1->4Fuc group linked to the proximal N-acetylglucosaniine residue of the trimannosyl core

The N-linked sugar chains were liberated as oligosaccha-ridesfrom octopus rhodopsin by hydrazinolysis. Most of the oligosaccharideswere neutral, and separated into two major components by columnchromatography using immobilized lectins and Bio-Gel P-4. Structuralanalysis of the one major component by sequential exoglycosidasedigestion, chemical fragmentation in combination with meth-ylationanalysis revealed that it is a nonasaccharide; Man16(Gaiβ13GlcNAcβ12Man13)Manβ14GlcNAcβ14(Galβ14Fuc16)GlcNAcThis structure is quite unique in that a novel galactosylatedfucose residue is attached to the reducing terminal N-acetyl-glucosamineresidue. galactosylated Fuc N-linked sugar chain novel structure octopus rhodopsin     

Separation of partially desialylated branched oligosaccharide isomers containing {alpha}(2<-3)- and {alpha}(2<-6)-linked Neu5Ac

The following two tri-sialylated triantennary oligosaccharides,which differ only in the linkage of the Neu5Ac to the uppermostbranch were, individually, partially desialylated to produceall possible di- and mono-sialylated isomers. A tetra-sialylated triantennary isomer, which contained an (26)-linkedNeu5Ac to the GlcNAc on branch III, was also converted to allpossible trisialylated isomers by mild acid hydrolysis as previouslydescribed (Roher et al., Anal Biochem., 212, 7–16, 1993).The resulting branch isomers were separated using high-pH anion-exchangechromatography (HPAEC). Structures were assigned to peak fractionson the basis of the previously described effect of (26)- and(23)-linked Neu5Ac on the elution order of branched lactosamine-typeoligosaccharides (Townsend et al., Anal Biochem., 182, 1–8,1989). No differences in the acid lability of the Neu5Ac linkageto either Gal ((23) or (26)) or GlcNAc ((26)) were observed.Our studies show that chemical desialylation and HPAEC is auseful approach to prepare and identify all possible sialylatedbranch isomers and should prove useful for defining the branchspecificity of sialyltransferases and sialidases. high-pH anion-exchange chromatography pulsed electrochemical detection sialidases sialylated oligosaccharides sialyltransferases     

Further characterization of the binding properties of a GalNAc specific lectin from Codium fragile subspecies tomentosoides

Previous study on the binding properties of a lectin isolatedfrom Codium fragile subspecies tomentosoides (CFT) indicatesthat this lectin recognizes the GalNAc1 sequence at both reducingand nonreducing ends. In this study, the carbohydrate specificityof CFT was further characterized by quantitative precipitin(QPA) and inhibition of lectin-enzyme binding assays. Of theglycoforms tested for QPA, all asialo-GalNAc1 containing glyco-proteinsreacted well with the lectin. Asialo hamster and ovine submandibularglycoproteins, which contain almost exclusively Tn (GalNAclSer/Thr)residues as carbohydrate side chains, and Streptococcus typeC polysaccharide completely precipitated the lectin added, whilethe GalNAcβcontaining Tamm-Horsfall Sd(a⁺) glycopro-teinand its asialo product were inactive. Among the oligo-saccharidestested for inhibiting lectin-glycoprotein interaction, GalNAc13GalNAcβ13Gal14Galβ14GIc(Fp)and Galβ13GalNAc1benzyl (T) were the best, and about 125-foldmore active than GalNAc They were about 3.3, 6.6, and 43 timesmore active than Tn containing glycopeptides, GalNAc13(LFuc12)Gal(A_h) and Galβ13GalNAc(T), respectively. From the presentand previous results, it is concluded that the combining siteof CFT is probably of a groove type that recognizes from GalNAclto pentasaccharide(Fp). The carbohydrate specificity of thislectin can be constructed and summarized in decreasing orderby lectin determinants as follows: Fp and T > Tn cluster> A_h >>I/II. carbohydrate specificities Codium fragile tomentosoides glycoprotein binding lectins     

Molecular dynamics simulations of oligosaccharides and their conformation in the crystal structure of lectin-carbohydrate complex: importance of the torsion angle {psi} for the orientation of {alpha}1,6-arm

The conformation of the heptasaccharide Man-1,6-(Man-1,3)(Xyl-ß1,2)-Man-ß,4-GlcNAc₂-ß1,4-(L-Fuc-1,3)-GlcNAc₁,the carbohydrate moiety of Erythrina corallodendron lectin (EcorL),the hexasaccharide Man-1,6-(Man-1,3) (GlcNAc-ß1,4)-Man-ß1,4-GlcNAc-ß1,4-GlcNAcand their disaccharide fragments have been studied by moleculardynamics (MD) simulations for 1000 ps with different initialconformations. In the isolated heptasaccharide, the most frequentlyaccessed conformation during MD has a value of 180° aroundMan-1,6-Man linkage. This conformation is stabilized by theformation of a hydrogen bond between the carbonyl oxygen ofGlcNAc₂ with the O3/O4 hydroxyls of the 1,6-linked mannose residue.The conformation of the heptasaccharide found in the crystalstructure of the EcorL-lactose complex (Shaanan et al., Science,254, 862, 1991), that has a value of 76° around Man-1,6-Manlinkage, is accessed, although less frequently, during MD ofthe isolated oligosaccharide. The ,, = 58°,–134°,–60°conformation around Man-₁,6-Man fragment observed in the crystalstructure of the Lathyrus ochnrs lectin complexed with a biantennaryoctasaccharide (Table I in Homans,S.W., Glycobiology, 3, 551,1993) has also been accessed in the present MD simulations.These values for the 1,6-linkage, which are observed in theprotein-carbohydrate crystal structures and are accessed inthe MD simulations, though occasionally, have not been predictedfrom NMR studies. Furthermore, these different values of leadto significantly different orientations of the 1,6-arm for thesame value of . This contrasts with the earlier predictionsthat only different values of can bring about significant changesin the orientation of the ₁,6-arm. The MD simulations also showthat the effects of bisecting GlcNAc or ß1,2-xyloseare very similar on the ₁,3-arm and slightly different on the₁,6-arm. bisecting GlcNAc carbohydrates glycoprotein lectinsaccharide complex     

Sialylation of n-alkyllactosides, galactosides and glucosides by sialyltransferases from rat liver Golgi vesicles

nAlkyl - and -lactosides, galactosides and glucosides with differentalkyl chain lengths (C₂, C₈, C₁₄, and C₂₀) were synthesizedand used as acceptors for sialyltransferases from rat liverGolgi vesicles. The -galactosides, -glucosides, and both - and-lactosides, were sialylated. Keeping the acceptor concentrationconstant, sialylation rates reached a maximum for the n-octyl- and -lactosides, n-Octyl -galactoside and noctyl -glucoside,respectively. noctyl -glucoside, respectivwly. n-Octyl -galactosideand n-octyl -glucoside were not sialylated. The reaction productswere characterized by TLC. With n-octyl lactoside and galactosideas acceptors, two major sialylation products were formed. Thjeycould be separated by preparative TLC, and their structureswere identified as 2–3 and 2–6 sialylated acceptors,respectively, by a combination of periodated oxidation, NaBD₄reduction,permethylation and subsequent analysis by fast atombombardment mass spectrometry (FAB-MS). The structure of thesingle product obtained from n-ictyl -glucoside was determinedto be the 2–6 sialylated glucoside. Competition experimentswith n-octyl lactoside and lactosylceramide and gangliosideGal1-3GalNAc1-4(NeuAc2–3)Gal1–4Glcbeeta1–1Cer(GM1) as acceptors for sialyltransferases suggested that SAT-I[NeuAc2–3Gal1–4Glc1-1Cer (GM3) synthase] was atleast in least in part responsible for the 2–3 sialylationof n-octyl lactoside. alkylgalactosides alkylglucosides alkyllactosides neoglycolipids sialytransferases     

Hydrophobic mannosides act as acceptors for trypanosome {alpha}-mannosyltransferases

A series of hydrophobic mannosides were synthesized and testedfor their ability to act as acceptor substrates for mannosyltransferasesin a Trypanosoma brucei cell-free system. The thiooctyl -mannosidesand octyl -mannosides all accepted single mannose residues in-linkage, as judged by thin layer chromatography of the productsbefore and after jack bean -mannosidase digestion. The mannosylationreactions were inhibited by amphomycin, suggesting that theimmediate donor was dolicholphosphate-mannose (Dol-P-Man) inall cases. The transferred -mannose residues were shown to beboth 1-2 and 1-6 linked by Aspergillus phoenicis -mannosidaseand acetolysis treatments, respectively. These data suggestthat the compounds can act as acceptor substrates for the Dol-P-Mandependent 1-2 and 1-6 mannosyltransferases of the GPI biosyntheticpathway and/or the dolichol-cycle of protein N-glycosylation.One of the compounds, Man1-6Man1-O-(CH₂)₇CH₃, inhibited endogenousGPI biosynthesis in the cell-free system, suggesting that itcould be a substrate for the trypanosome Dol-P-Man:Man₂GlcN-Pl1-2 mannosyltransferase. dolichol glycosylphosphatidylinositol mannosyltransferase trypanosome     

Flexibility in the donor substrate specificity of {beta} 1,4-galactosyltransferase: application in the synthesis of complex carbohydrates

Biosynthetically, bovine N-acetylglucosainine ß 1,4-galacto-syltransferase(GalT) catalyses the transfer of galactosyl residues from UDP-Galto the 4-position of GlcNAc units, resulting in the productionof N-acetyllactosamine sequences. UDP-Glc and UDP-GalNAc werealso found to act as donors for this enzyme, allowing the preparationof ßGlc(14)-ßGlcNAc and ßGalNAc(14)ßGlcNActerminating structures on the milligram scale. GalT could thusbe used to add ßGalNAc to ßGlcNAc(12)Manterminating structures, converting them to the ßGalNAc(14)ßGlcNAc(12)Mansequences found on glycoprotein hormones. GalT did not transferGlcNAc residues from UDP-GlcNAc, but it could utilize UDP-GlcNH₂as a donor. Synthesis of ßGlcNAc(14)ßGlcNAcsequences could therefore be accomplished by transfer of GlcNH₂from its UDP derivative, followed by N-acetylation of the productamino-disaccharide using acetic anhydride in methanol. The productsof the enzymatic reactions were characterized by ¹H-NMR-spectroscopyand fast-atom bombardment mass spectrometry. This work expandsthe scope of the combined chemical-enzymatic synthesis of complexcarbohydrates, using glycosyltrans-ferases, to the productionof oligosaccharides different from those for which these enzymeswere designed. These unnatural reactions should find applicationin glycoprotein and glycolipid remodelling. galactosyltransferase chemica1-enzymatic synthesis of oligosaccharides oligosaccharide analogues sugar-nucleotide analogues carbohydrate remodelling     

Structural characterization of the disialogangliosides of murine peritoneal macrophages

Sialoglycosphingolipids (gangliosides) have been increasinglyimplicated as regulators of membrane signaling events. Macrophageganglioside patterns dramatically increase in complexity whenmurine peritoneal macrophages are stimulated in vivo with theappearance of the sialidase-sensitive monosialoganglioside GMlb(cisGMl) as a major component Gangliosides from stimulated murineperitoneal macrophages were separated into monosialo and polysialofractions and the polysialo fraction structurally characterizedby enzymatic, chemical, and mass spectra methods. All detectablecomponents of the polysialo fraction were determined to be disialogangliosides.Treatment of the polysialo fraction with Clostridium perfringenssiali-dase produced mostly the sialidase-resistant monosialoganglioside,GMIa, and a minor amount of asiaJoGMI. Perio-date oxidationand mass spectrometry analyses demonstrated the lack of tandemdisialo moieties which indicated the absence of GD1b or GD1c(GDI) entities. The combined data showed the major disialogangliosidesconsisted of GDla entities comprising IV3-NeuAc,II3NeuAc-GgOse4Cer,IV3-NeuGc,II3NeuAc-GgOse4Cer, IV3NeuAc,II3NeuGc-GgOse4Cer, andIV3-NeuGc,II3NeuGc-GgOse4Cer. Minor components consisted ofGDl entities, IV3NeuAc, III6NeuAcGgOse4Cer, IV3NeuGc, III6NeuGcGgOse4Cer,and also positional iso-mer(s) of GDl(NeuAc, NeuGc). These isomericcomponents were identified by collision analysis and tandemmass spectrometry. Consistent with previous analyses, the cer-amideportion of all polysialo (disialo) gangliosides contained solelyC18 sphingosine with C16 and C24 fatty acid moieties. Theseresults, combined with the previous characterization of macrophagemonosialogangliosides, indicate normal murine macrophage gangliosidebiosynthesis proceeds along the "a" ganglioside pathway, e.g.,GM3GM2GMlaGDl, and the proposed asialogan-glioside or "" pathway,asialoGMlGMlbGDl. The presence of totally sialidase-sensitivegangliosides appears to be characteristic of functional murineperitoneal macrophages while they are reduced in geneticallyimpaired cells. ganglioside GDla ganglioside GDl murine macrophages tandem mass spectrometry collision induced dis-association electrospray ionization     

Phosphorylation and subcellular location of {alpha}-L-fucosidase in Iymphoid cells from patients with I-cell disease and pseudo-Hurler polydystrophy

Mannose 6-phosphate is a recognition marker used by many newlymade acid hydrolases for their transport to lyso-somes. Previously,we investigated the incorporation of ³²Pi into -L-fucosidaseof lymphoid cell lines from a healthy individual (control) andan I-cell disease patient [DiCioccio and Miller, Glycobiology,1, 595–604 (1991)]. Phosphoserine was found in immunoprecipitable-L-fucosidase of both control and I-cell lymphoid cells, butmannose 6-phosphate was identified only in enzyme of controlcells. Extension of this investigation to lymphoid culturesof a pseudo-Hurler polydystrophy patient also identified onlyphosphoserine in -L-fucosidase. Using [³H] mannose instead of³²Pi, the precise identification of mannose 6-phosphate in -L-fucosidaseof control cells, and its absence in -L-fucosidase of I-celland pseudo-Hurler cells, was established. The stoichiometryof phosphorylation of -L-fucosidase in I-cell, pseudo-Hurlerand control lymphoid cells was 3, 4 and 10 mol Pi/mol enzyme,respectively. -L-Fucosidase was located in lysosomes isolatedfrom control, I-cell and pseudo-Hurler lymphoid cells by subcelluarfractionation on Percoll density gradients. Both I-cell andpseudo-Hurler lymphoid cells displayed normal intralysosomalactivity of -L-fucosidase despite lack of the mannose 6-phosphatemarker. Thus, I-cell and pseudo-Hurler lymphoid cells must possessa mannose 6-phosphate-independent mechanism for directing -L-fucosidaseto lysosomes. Phosphorylation of -L-fucosidase in pseudo-Hurlerand I-cell lymphoid cultures was found almost exclusively inintracellular and not in extracellular enzyme, suggesting thatphosphoserine may participate in the localization of -L-fucosidasein lysosomes of these cells. -L-fucosidase I-cell disease lysosome phosphorylation pseudo-Hurler polydystrophy     

Identification and characterization of an {alpha}-mannosidase from Trypanosoma cruzi

In this report we describe the first purification and characterizationof the acid -mannosidase from the human parasite Trypanosomacruzi. The purified enzyme exhibited a native mol. wt of 240000 Da and is apparently composed of four identical subunitsof mol. wt 58 000 Da. Each of the four subunits contains oneN-linked high-mannose-type oligosaccharide. The -mannosidaseexhibited a pH optimum of 3.5 and a pI of 5.9. This low pH optimumand the ability of swainsonine to inhibit its activity suggestthat the -mannosidase is a lysosomal enzyme. Antibodies againstthe T.cruzi enzyme did not react with mammalian lysosomal -mannosidaseand, conversely, antibody against a rat lysosomal -mannosidasedid not react with the T.cruzi enzyme. Thus, the T.cruzi enzymeappears to be distinct from its mammalian counterpart. -mannosidase lysosomal enzyme Trypanosoma cruzi     

Human Lewis {alpha}1->3/4fucosyltransferase: specificity of fucose transfer to GlcNAc{beta}1->3Gal{beta}1->4Glc{beta}1->1Cer (LcOse3Cer)

Biosynthesis of the Le^x series of carbohydrate antigens proceedsby fucose transfer in 13-linkage to the penultimate GlcNAc residueof a neolacto-series oligosaccharide acceptor, a reaction catalysedby multiple enzymes expressed in human tissues. Particularlybroad acceptor specificity, including the ability to catalysefucose transfer to both lacto- and neolacto-series acceptorsas well as the precursor Lc₃ structure (where Lc₃ lactotriaosylceramide,is GlcNAcß13Galß14Glcß1Cer), existsfor one human fucosyltransferase form, the Lewis 13/4fucosyltransferase(FucT-III). To determine if fucose transfer to Lc₃may representan alternate early step in Le^xor Le^a antigen biosynthesis withthis enzyme, the chemical structure of the fucosylated Lc₃ reactionproduct formed by the Lewis 13/4fucosyltransferase from Colo205 cells has been defined. Transfer of [¹⁴C]fucose to Lc₃ yieldeda labelled product migrating as a tetrasaccharide on thin layerchromatography plates. This product remained an acceptor forboth ß13- and ß14-galactosyl transfer onthe terminal GlcNAc residue. The product was degraded to a fucosylatedtrisaccharide derivative by bovine kidney ß-N-acetylglucosaminidase.Fast atom bombardment mass spectrometry and methylation analysisconfirmed that the product was composed exclusively of the followingstructure containing a fucose linked to the 3-position of theinternal Glc residue: GlcNAcß13Galß14Glcß11Cer Such a structure does not represent an intermdiate in Le^xorLe^a antigen biosynthesis. Thus, the evidence suggests that Le^xor Le^a antigen synthesis results exclusively from fucosylationof complete core chains. fucosyltransferase lacto-series LcOse₃Cer Lewis antigen transfer specificity     

Hearing and glycoconjugates: localization of Ley, Lex and sialosyl-Lex in guinea pig cochlea, particularly at the tectorial membrane and sensory epithelia of the organ of Corti

Immunohistological examination of guinea pig cochleas was performedusing a panel of 25 monoclonal antibodies directed to variouslacto-, ganglio- and globo-series carbohydrate epitopes as wellas mucin-type epitopes. Lacto-series structures were found tobe localized at specific sites of the tectorial membrane (TM)and Corti's organ, i.e. 13 fucosyl type 2 chain (Le^x) at Kimura'smembrane, marginal band and covering net of TM; 12, 13 difucosyltype 2 chain (Le^y) at covering net; and sialosyl-Le^x and sialosyl-iat Kimura's membrane and sensory epithelia, particularly sensorytips of hair cells of Corti's organ. In striking contrast, ganglio-seriesstructures (GM3, GD3, GD2, 9-O-Ac-GD3) were detected at spiralganglion cells, neuronal fibres and stria vascularis, but werecompletely absent from Corti's organ and most of the TM. Otherepitope structures defined by various antibodies were not detectableat any location. The functional roles of lacto-series carbohydrateepitopes expressed at TM and Corti's organ remain unknown. However,the expression of Le^y (but not other structures) in associationwith developmental deficiency of TM induced by 6-N-propyI-2-thio-uracilin rats suggests that Le^y plays some role in normal TM development.The presence of Le^x at Kimura's membrane and sialosyl-Le^x athair cell sensory tips of Corti's organ suggests the intriguingpossibility that these fucosylated/sialosylated carbohydratestructures play some role in interactions (either attractiveor repulsive) of these inner ear components, which have beenimplicated in the physiology of hearing, i.e. the conversionof sound waves to nerve impulses. cochlea Corti's organ glycoconjugate sialosyl fucosyl type 2 chain tectorial membrane     

Xyloglucan and r{beta}-D-Glucan in Cell Walls of Rice Seedlings

Cell walls of 4-day old rice seedlings were extracted successivelywith ammonium oxalate-oxalic acid, 4% KOH and 24% KOH. A rß-D-glucanpreparation and a xyloglucan preparation were isolated fromthe 4% KOH extract and 24% KOH extract, respectively. Methylationanalysis and enzymic degradation studies of the polysaccharidesshowed that the former was built up predominantly of repeating-oligosaccharideunits of 3-O-rß-cellobiosyl-D-glucose and 3-O-rß-cellotriosyl-D-glucosein a molar ratio of 2.6 : 1.0, and the latter was of repeating-oligosaccharideunits of -D-xylosyl-(16)-rß-D-glucosyl-(14)-[-D-xylosyl-(16)]-rß-D-glucosyl-(14)-D-glucose,-D-xylosyl-(16)-rß-D-glucosyl-(14)-D-glucose and cellobiose. ¹ Present address: Department of Botany, Iowa State University,Ames, Iowa 50011, U.S.A. (Received August 29, 1981; Accepted January 12, 1982)     

The hypothetical N-glycan charge: a number that characterizes protein glycosylation

The production of recombinant glycoprotein therapeutics requirescharacterization of glycosylation with respect to the lot-to-lotconsistency. Here we introduce the ‘hypothetical N-glycancharge Z’ as a parameter that allows to characterize theprotein glycosylation in a simple, however, efficient manner. The hypothetical N-glycan charge of a given glycoprotein isdeduced from the N-glycan mapping profile obtained via HPAE-PAD.In HPAEC, N-glycans are clearly separated according to theircharge, i.e., their number of sialic acid residues, providingdistinct regions for neutral struc tures as well as for themono- di-, tri, and tetrasialylated N-glycans (Hermentin etal., 1992a). Z is defined as the sum of the products of the respective areas(A) in the asialo, monosialo, disialo, trisialo, tetrasialo,and pentasialo region, each multiplied by the correspondingcharge: Thus, a glycoprotein with mostly C4-4^* structures will provideZ400 (e.g., rhu EPO (CHO), Z=361), a glycoprotein carrying largelyC3-3^* structures will amount to Z300 (e.g., bovine fetuin, Z=290),a glycoprotein with mostly C2-2^* structures will have Z200 (e.g.,human serum transferrin, Z=207, or human plasma AT III, Z=180),and a glycoprotein carrying only high-mannose type or trunkatedstructures will provide Z0 (e.g., bovine pancreas ribonucleaseB, Z=15, and hen ovomucoid, Z=15, respectively). The determination of Z was validated in multiple repetitiveexperiments and proved to be highly accurate and reliable. Zmay therefore be regarded as a new and characteristic parameterfor protein N-glycosylation. high-performance anion-exchange chromatography (HPAEC) pulsed amperometric detection (PAD) HPAE-PAD human plasma recombinant expression CHO BHK interleukin 4-receptor erythropoietin fetuin transferrin thyroglobulin antithrombin ribonuclease ovomucoid orosomucoid ₁-acid glycoprotein fibrinogen ₁ T-glycoprotein ₁-antitrypsin ₁-antichymotrypsin ß₂-glycoprotein I thyroxin-binding globulin ₁B-glycoprotein 8S₃-glycoprotein haptoglobin hydrazinolysis PNGase F consistency clearance in vivo half-life     

A novel alpha1,2-fucosyltransferase (CE2FT-2) in Caenorhabditis elegans generates H-type 3 glycan structures

The 1,2-fucosyltransferase family (1,2FT) is the largest familyof glycosyltransferases in the genome of the free-living nematodeCaenorhabditis elegans, and early evidence suggests that eachmember may have a unique activity. Here we describe a C. elegansgene (designated CE2FT-2) encoding an 1,2FT that has the potentialto generate the sequence Fuc1-2Galβ1-3GalNAc-R, which isthe H-type 3 blood group structure. The CE2FT-2 cDNA encodesa putative transmembrane protein that shows 42% amino acid identityto a previously cloned C. elegans 1,2FT (termed CE2FT-1), buthas a very low identity (16–20%) to 1,2FT sequences inhumans, rabbits, and mice. A recombinant form of CE2FT-2 expressedin human 293T cells has a high 1,2FT activity toward Galβ1-3GalNAc-O-pNP,but unexpectedly, the enzyme is inactive toward the acceptorGalβ-O-phenyl. Thus, CE2FT-2 differs from all other 1,2FTspreviously described from animals that all utilize Galβ-O-phenyl.CE2FT-2 is expressed at all stages of worm development, butremarkably, promoter analysis of the CE2FT-2 gene using greenfluorescent protein reporter constructs indicates that the CE2FT-2is expressed exclusively in pharyngeal cells of the worm fromembryo to an adult stage. Because pharyngeal cells are knownto secrete their glycoconjugates to the nematode surface, theseresults may indicate that products of CE2FT-2 contribute tointeractions of the nematode with its environment or are usedas ligands for bacterial attachment. These findings, along withthose on other 1,2FTs in C. elegans, suggest that each 1,2FTin this organism may have a unique acceptor specificity, expressionpattern, and biological function.     

Sialylation of intestinal microvillar membranes in newborn, sucking and weaned pigs

Affinity cytochemistry and biochemistry revealed distinctivetemporal changes in the expression of sialylated and compositionallyrelated membrane glycoconjugates in the pig small intestinebetween birth and weaning. The expression of membrane NeuAc2,6moieties, recognized by Sambucus nigra agglutinin-1, was highin newborn pigs, declined slightly during sucking and was verylow in weaned animals. Conversely, the expression of membraneNeuAc2r3 moieties, recognized by Maackia amurensis agglutinin-2,was low at birth but higher in sucking and weaned animals. Histobloodgroup O- and A-antigen expression was first detected in a minorityof sucking pigs, but was evident in all weaned pigs examined.Lactase glycoforms were isolated from solubilized microvillarmembranes of newborn and weaned pigs. The newborn (predominantly2,6-sialylated) and weaned (predominantly 1,2-fucosylated) glycoformsexhibited similar specific activity, indicating that postnatallactase decline in the pig intestine is unrelated to temporalchanges in membrane sialylation and fucosylation. fucosylation lactase lectins intestine sialylation     

Molecular dynamics simulations of high-mannose oligosaccharides

Conformations of several high-mannose-type oligosaccharidesthat are generated during the biosynthetic degradation of Man₉GlcNAc₂to Man₅GlcNAc₂ have been studied by molecular dynamics (MD).Simulations were performed on NCI-FCRDC's Cray Y-MP 8D/8128supercomputer using Biosym's CVFF force field for 1000 Ps withdifferent initial conformations. The conformations of the two1,3- and the two 1,6-linkages in each oligomannose were different,suggesting that deriving oligosaccharide conformations basedon the conformational preferences of the constituent disaccharidefragments will not always yield correct results. Unlike otheroligomannoses, Man₉GlcNAc₂ appears to take more than one distinctconformation around the core 1,6-linkage. These various conformationsmay play an important role in determining the processing pathways.Using the data on the preferred conformations of these oligomannosesand the available experimental results, possible pathways forprocessing Man₉GlcNAc₂ to Man₅GlcNAc₂ by 1,2-linkage-specificmannosidases have been proposed. Conformational analysis ofMan₅GlcNAc₂ indicates that the addition of ß1,2-GlcNActo the 1,3-linked core mannose, besides serving as a prerequisitefor mannosidase II action as suggested earlier, may also preventthe removal of 1,3-mannose. The MD simulations also suggestthat the processing of the precursor oligosaccharide duringAsn-linked complex and hybrid glycan biosynthesis proceeds ina well-defined pathway involving more than one 1,2-linkage-specificmannosidase. Knowledge of the conformation of the processingintermediates obtained from the present study can be used todesign highly specific substrate analogues to inhibit a particularmannosidase, thereby blocking one processing pathway withoutinterfering with the others. carbohydrates conformation glycosidase inhibitors mannosidase oligosaccharide processing     

Structural variations in the glycosaminoglycan-protein linkage region of recombinant decorin expressed in Chinese hamster ovary cells

Decorin is a small flbroblast proteoglycan consisting of a coreprotein and a single chondroitin/dermatan sulfate chain. Thestructure of the carbohydrate-protein linkage region of therecombinant decorin expressed in Chinese hamster ovary cellswas investigated. The decorin was secreted in the culture mediumand isolated by anion-exchange chromatography. The glycosaminoglycanchain was released from the decorin by β-elimination usingalkaline NaBH₄, and then digested with chondroitinase ABC. Thesetreatments resulted in a major and a few minor hexasaccharidealditols derived from the carbohydrate-protein linkage region.Their structures were analyzed by enzymatic digestion in conjunctionwith high-performance liquid chromatography. Two of these compoundshave the conventional hexasaccharide core, HexA1-3GalNAcβ1-4GlcAβ1-3Galβ1-3Galβ1-4Xyl-ol.One is nonsulfated, and the other is monosulfated on C4 of theGalNAc residue. They represent 12% and 60% of the total linkageregion, respectively. The other compound has the hexasaccharidealditol with an internal iduronic acid residue HexA1-3GalNAc(4-sulfate)β1-4IdoA1-3GaIβ1-3Galβ1-4Xyl-ol,which was previously demonstrated in one of the five linkagehexasaccharide alditols isolated from dennatan sulfate proteoglycansof bovine aorta (Sugahara et al, J. Biol Chem., 270, 7204–7212,1995).The compound accounts for 11% of the total linkage region. Thesestructural variations in the linkage hexasaccharide region ofthe decorin strikingly contrast to the uniformity demonstratedin the linkage hexasaccharide structure of human inter--trypsininhibitor (Yamada et al, Glycobiology, 5, 335–341,1995)and urinary trypsin inhibitor (Yamada et al, Eur. J. Biochem.,233, 687–693, 1995), both of which have a single chondroi-tinsulfate chain with a uniform linkage hexasaccharide structure,HexA1-3GalNAc(4-sulfate)β1-4GlcAβ1-3Gal(4-sulfate)β1-3Galβ1-4Xyl,containing a 4-O-sulfated Gal residue. chondroitin sulfate decorin dermatan sulfate glycosaminoglycan proteoglycan