Glycosyltransferase activity can be modulated by small conformational changes of acceptor substrates

A range of N-acetyllactosamine derivatives (compounds 4-7) that have restricted mobilities around their glycosidic linkages have been employed to determine how small changes in conformational properties of an oligosaccharide acceptor affect catalytic efficiencies of glycosylations by alpha-2,6- and alpha-2,3-sialyltransferases and alpha-1,3-fucosyltransferases IV and VI. Restriction of conformational mobility was achieved by introducing tethers of different length and chemical composition between the C-6 and C-2' hydroxyl of LacNAc. Compound 4 is a 2',6-anhydro derivative which is highly constrained and can adopt only two unusual conformations at the LacNAc glycosidic linkage. Compound 5 is modified by a methylene acetal tether and can exist in a larger range of conformations; however, the Phi dihedral angle is restricted to values smaller than 30 degrees, which are not entirely similar to minimum energy conformations of LacNAc. The ethylene-tethered 6 can attain conformations in the relatively large energy plateau of LacNAc that include syn conformations A and B, whereas compound 7, which is modified by a methylamide tether, can only reside in the B-conformer. 2',6-Dimethoxy derivative 2 was employed to determine the effect of alkylation of the C-6 and C-2' hydroxyls of 5 and 6 whereas 3 was used to reveal the effects of the C-6 amide and C-2' alkylation of 7. The apparent kinetic parameters of transfer to the conformationally constrained 4-7 and reference compounds 1-3 catalyzed by alpha-2,6- and alpha-2,3-sialyltransferases and alpha-1,3-fucosyltransferases IV and VI were determined, and the results correlated with their conformational properties. The data for 4-6 showed that each enzyme recognizes N-acetyllactosamine in a low minimum energy conformation. A small change in conformational properties such as in compound 5 resulted in a significant loss of catalytic activity. Larger conformational changes such as in compound 4 abolished all activity of the sialyltransferases whereas the fucosyltransferases showed some activity, albeit very low. The kinetic data for compounds 4 and 5 demonstrate clearly that different glycosyltransferases respond differently to conformational changes, and the fucosyltransferases lost less activity than the sialyltransferases. Correlating apparent kinetic parameters of conformationally constrained 6 and 7 and their reference compounds 2 and 3 further supports the fact that different enzymes respond differently and indicates that sialyltransferases and fucosyltransferases recognize N-acetyllactosamine in a different conformation. Collectively, the data presented here indicate that small conformational changes of an oligosaccharide acceptor induced by, for example, the protein structure can be employed to modulate the patterns of protein glycosylation.     

An enzymatically produced novel cyclic tetrasaccharide, cyclo-{-->6)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->} (cyclic maltosyl-(1-->6)-maltose), from starch

A bacterial strain M6, isolated from soil and identified as Arthrobacter globiformis, produced a novel nonreducing oligosaccharide. The nonreducing oligosaccharide was produced from starch using a culture supernatant of the strain as enzyme preparation. The oligosaccharide was purified as a crystal preparation after alkaline treatment and deionization of the reaction mixture. The structure of the oligosaccharide was determined by methylation analysis, mass spectrometry, and (1)H and (13)C NMR spectroscopy, and it was demonstrated that the oligosaccharide had a cyclic structure consisting of four glucose residues joined by alternate alpha-(1-->4)- and alpha-(1-->6)-linkages. The cyclic tetrasaccharide, cyclo-{-->6)-alpha-D-Glcp(1-->4)-alpha-D-Glcp(1-->6)-alpha-D-Glcp(1-->4)-alpha-D-Glcp(1-->}, was found to be a novel oligosaccharide, and was tentatively called cyclic maltosyl-maltose (CMM). CMM was not hydrolyzed by various amylases, such as alpha-amylase, beta-amylase, glucoamylase, isoamylase, pullulanase, maltogenic alpha-amylase, and alpha-glucosidase, but hydrolyzed by isomalto-dextranase to give rise to isomaltose. This is the first report of the cyclic tetrasaccharide, which has alternate alpha-(1-->4)- and alpha-(1-->6)-glucosidic linkages.     

Structural analysis of arabinoxylans isolated from native and malted finger millet (Eleusine coracana, ragi)

Structural elucidation of purified arabinoxylans isolated from finger millet and its malt by methylation, GLC-MS, periodate oxidation, Smith degradation, NMR, IR, optical rotation, and oligosaccharide analysis indicated that the backbone was a 1,4-beta-D-xylan, with the majority of the residues substituted at C-3. The major oligosaccharide generated by endo xylanase treatment was homogeneous with a molecular weight of 1865 Da corresponding to 14 pentose residues as determined by MALDI-TOF-MS and gel filtration on Biogel P-2. The structural analysis of this oligosaccharide showed that it contained 8 xylose and 6 arabinose residues, substituted at C-3 (monosubstituted) and at both C-2 and C-3 (disubstituted).     

Glycosylation of internal sugar residues of oligosaccharides catalyzed by alpha-galactosidase from Aspergillus fumigatus

Purified alpha-galactosidase from a thermotolerant fungus Aspergillus fumigatus IMI 385708 was found to catalyze efficiently transgalactosylation reactions using 4-nitrophenyl alpha-D-galactopyranoside as glycosyl donor. Self-transfer reactions with this substrate afforded in low yields several 4-nitrophenyl galactobiosides. Monosaccharides also served as poor glycosyl acceptors. Disaccharides and particularly higher oligosaccharides of alpha-1,4-gluco- (maltooligosaccharides), beta-1,4-gluco- (cellooligosaccharides) and beta-1,4-manno-series were efficiently galactosylated, the latter being the best acceptors that were also doubly galactosylated. With mannooligosaccharides product yields increased with polymerization degree of acceptors reaching 50% at DP of 4-6. Longer oligosaccharide acceptors were galactosylated at internal sugar residues. All galactosyl residues were transferred exclusively to the primary hydroxyl group(s) at C-6 position of oligosaccharide acceptors. This is in accordance with the inability of the enzyme to transfer galactose to beta-1,4-linked xylooligosaccharides. This is the first report of glycosyl transfer reaction to internal sugar residues of oligosaccharides catalyzed by a glycosidase. High affinity to oligosaccharide acceptors also opens a way toward enzymatic glycosylation of polysaccharides, thus modulating their physico-chemical and biological properties.     

Pyranose dehydrogenases: biochemical features and perspectives of technological applications

Pyranose dehydrogenase is a fungal flavin-dependent sugar oxidoreductase which is structurally and catalytically related to fungal pyranose oxidase and cellobiose dehydrogenase and probably fulfills similar biological functions in lignocellulose breakdown. It is a monomeric secretory glycoprotein and is limited to a rather small group of litter-decomposing basidiomycetes. Compared with pyranose oxidase, it displays broader substrate specificity and a variable regioselectivity and is unable to utilize oxygen as electron acceptor using substituted benzoquinones and (organo) metallic ions instead. Depending on the structure of the sugar in pyranose form (mono/di/oligosaccharide or glycoside) and the enzyme source, selective monooxidations at C-1, C-2, C-3, or dioxidations at C-2,3 or C-3,4 of the molecule to the corresponding aldonolactones (C-1), or (di)dehydrosugars (aldos(di)uloses) can be performed. These features make pyranose dehydrogenase a promising and versatile biocatalyst for production of highly reactive, sometimes unique, di- and tri-carbonyl sugar derivatives that may serve as interesting chiral intermediates for the synthesis of rare sugars, novel drugs, and fine chemicals.     

High-performance anion exchange-chromatography of neutral milk oligosaccharides and oligosaccharide alditols derived from mucin glycoproteins.

High-performance anion-exchange (HPAE) chromatography under alkaline conditions (pH approximately 13) has been used to separate neutral oligosaccharides from human milk as well as oligosaccharide alditols isolated by alkaline borohydride degradation of O-linked glycoproteins having blood group A and H activities. Due to the diminished retention times of the alditols compared to their reducing counterparts, a very low base concentration (approximately 15 mM) was used in the fractionation of oligosaccharide alditols. The method appears to be ineffective in fractionation of monosaccharide alditols. Although the retention times generally increased with increasing oligosaccharide chain length, linkage of Fuc alpha-(1----2) to galactose and by Fuc alpha-(1----3) or Fuc alpha-(1----4) to glcNAc may decrease the retention times of both the alditols and the reducing oligosaccharides. Branching generally increased the retention times for oligosaccharide alditols. The retention times of isomers differing in the position of fucose substitution (LNF-1 vs LNF-2) differed greatly while those of the linkage isomers LNF-2 and LNF-3 were similar but distinct. Pulsed amperometric detection is sensitive at the picomole level both for these underivatized oligosaccharides and alditols. On-line desalting with an ion-exchange membrane has been found to be effective in preparative chromatography of these oligosaccharides for NMR spectroscopy and mass spectrometry.     

Mechanism of formation of the A/B cis ring junction of ecdysteroids in Polypodium vulgare.

1. The fates of the alpha-, 4 alpha- and 4 beta-hydrogen atoms of cholesterol during formation of the A/B cis ring junction of ecdysteroids was investigated by administration of [4-14C, 3 alpha-3H], [4-14C, 4 alpha-3H]- and [4-14C, 4 beta-3H]cholesterol species to the fern, Polypodium vulgare, and isolation of the 20-hydroxyecdysone formed in each case. 2. The 3H was retained in the ecdysteroid formed from each substrate. 3. Location of the 3H in the 20-hydroxyecdysone indicated that migration of 3H from the 3 alpha- and 4 beta-positions to C-4 and C-5, respectively, had occurred, whereas the 4 alpha-3H atom was retained at C-4. 4. A possible mechanism for the formation of the A/B cis ring junction of ecdysteroids in P. vulgare is presented.     

The use of 6alpha-and 6beta-carboxymethyl testosterone-bovine serum albumin conjugates in radioimmunoassay for testosterone.

The synthesis of 6alpha- and 6beta-testosterone-bovine serum albumin (BSA) conjugates is described. 6beta-Carboxymethyl-4-androstene-3,17-dione was prepared by a route analogous to that described earlier for 6beta-carboxymethyl progesterone. Sodium borohydride reduction of the 3 and 17 keto groups and subsequent selective oxidation of the resulting 3beta, 17beta-diol using MnO2 provided 6 -carboxymethyl testosterone. Further acid catalyzed epimerization of the C-6 center gave the isomeric 6alpha-carboxymethyl testosterone. The 6alpha- and 6beta-testosterone derivatives were attached to BSA via a mixed anhydride coupling employing tributylamine and i minus-butylchlorocarbonate. For each molecule of BSA, the 6alpha- and 6beta-conjugates contained an average of 23 and 20 steroid residues, respectively. Antisera to the conjugates exhibited similar high specificities toward various steroids, the only incidence of serious cross-reaction being the expected case of dihydrotestosterone.     

Fast and efficient synthesis of a novel homologous series of L-fucosylated trisaccharides using the Helix pomatia alpha-(1-->2)-L-galactosyltransferase

The alpha-(1-->2)-L-galactosyltransferase from the albumen gland of the vineyard snail Helix pomatia exhibits high alpha-(1-->2)-L-fucosyltransferase activity and can be used to transfer L-fucose from GDP-L-fucose to terminal, non-reducing D-galactose residues of an oligosaccharide, thus providing facile access to a range of H-antigen-containing oligosaccharides. The enzymatic glycosylation was applied here on a milligram scale to a series of disaccharide acceptor substrates. Apparently the site of interglycosidic linkage between the terminal and subterminal acceptor sugar units is of little or no consequence. The homologous series of trisaccharides thus produced were fully characterised by NMR analysis of their peracetates.     

Effect of dietary cyclic nigerosylnigerose on intestinal immune functions in mice

We examined the dietary effects of cyclic nigerosylnigerose (CNN), a dietary indigestible oligosaccharide with four D-glucopyranosyl residues linked by alternating alpha-(1-->3)- and alpha-(1-->6) glucosidic linkages, on the intestinal immune function of mice, and the effects were compared with those of alpha-(1-->3)-linked oligosaccharide (nigerooligosaccharides, NOS) or alpha-(1-->6)-linked oligosaccharide (isomaltooligosaccharides, IMO). BALB/c mice were fed with 1-5% CNN, 5% IMO, or 12.5% NOS for 4 weeks, and the intestinal mucosal immune responses were determined. In the 1-5% CNN fed groups, the amounts of IgA in feces increased significantly. In addition, IgA, transforming growth factor-beta1 (TGF-beta1), and interleukin-6 (IL-6) secretion by Peyer's patch (PP) cells were enhanced in CNN fed mice. In the 5% CNN group, pH in the cecum decreased, and the amounts of lactic acid and butyric acid increased. These findings were not observed in the NOS- or IMO-fed group of mice. They suggest that CNN supplementation changes the intestinal environment of microflora and indirectly enhances the immune function in the gut.     

Role of the two catalytic domains of DSR-E dextransucrase and their involvement in the formation of highly alpha-1,2 branched dextran

The dsrE gene from Leuconostoc mesenteroides NRRL B-1299 was shown to encode a very large protein with two potentially active catalytic domains (CD1 and CD2) separated by a glucan binding domain (GBD). From sequence analysis, DSR-E was classified in glucoside hydrolase family 70, where it is the only enzyme to have two catalytic domains. The recombinant protein DSR-E synthesizes both alpha-1,6 and alpha-1,2 glucosidic linkages in transglucosylation reactions using sucrose as the donor and maltose as the acceptor. To investigate the specific roles of CD1 and CD2 in the catalytic mechanism, truncated forms of dsrE were cloned and expressed in Escherichia coli. Gene products were then small-scale purified to isolate the various corresponding enzymes. Dextran and oligosaccharide syntheses were performed. Structural characterization by (13)C nuclear magnetic resonance and/or high-performance liquid chromatography showed that enzymes devoid of CD2 synthesized products containing only alpha-1,6 linkages. On the other hand, enzymes devoid of CD1 modified alpha-1,6 linear oligosaccharides and dextran acceptors through the formation of alpha-1,2 linkages. Therefore, each domain is highly regiospecific, CD1 being specific for the synthesis of alpha-1,6 glucosidic bonds and CD2 only catalyzing the formation of alpha-1,2 linkages. This finding permitted us to elucidate the mechanism of alpha-1,2 branching formation and to engineer a novel transglucosidase specific for the formation of alpha-1,2 linkages. This enzyme will be very useful to control the rate of alpha-1,2 linkage synthesis in dextran or oligosaccharide production.     

The ALG10 locus of Saccharomyces cerevisiae encodes the alpha-1,2 glucosyltransferase of the endoplasmic reticulum: the terminal glucose of the lipid-linked oligosaccharide is required for efficient N-linked glycosylation

The biosynthesis of the lipid-linked oligosaccharide substrate for N- linked protein glycosylation follows a highly conserved pathway at the membrane of the endoplasmic reticulum. Based on the synthetic growth defect in combination with a reduced oligosaccharyltransferase activity (wbp1), we have identified alg10 mutant strains which accumulate lipid- linked Glc2Man9GlcNAc2. We cloned the corresponding wild-type gene and show in a novel in vitro assay that Alg10p is a dolichyl-phosphoglucose- dependent glucosyltransferase which adds the terminal alpha-1,2 glucose to the lipid-linked Glc2Man9GlcNAc2 oligosaccharide. Hypoglycosylation of secreted proteins in alg10 deletion strains demonstrates that the terminal alpha-1,2-linked glucose residue is a key element in substrate recognition by the oligosaccharyltransferase. This ensures that primarily completely assembled oligosaccharide is transferred to protein.      

In vitro oligosaccharide synthesis using intact yeast cells that display glycosyltransferases at the cell surface through cell wall-anchored protein Pir

A glycosyltransferase was fused to the yeast cell wall protein Pir, which forms the Pir1-4 protein family and is incorporated into the cell wall by an unknown linkage to be displayed at the yeast cell surface. We first expressed the PIR1-HA-gma12+ fusion, in which gma12+ encodes alpha-1,2-galactosyltransferase from the fission yeast Schizosaccharomyces pombe under the Saccharomyces cerevisiae GAPDH promoter. The alpha-1,2-galactosyltransferase activity was detected at the surface of the intact cells that produce Pir1-HA-Gma12 fusion. To further demonstrate sequential oligosaccharide synthesis, two plasmids containing PIR1-HA-KRE2 and PIR2-FLAG-MNN1 fusion genes were constructed in which KRE2 and MNN1 encode alpha-1,2-mannosyltransferase and alpha-1,3-mannosyltransferase from S. cerevisiae, respectively. The intact yeast cells transformed with these two plasmids added mannoses initially with an alpha-1,2 linkage and subsequently with an alpha-1,3 linkage to the alpha-1,2-mannobiose acceptor in the presence of a GDP-mannose donor, demonstrating that Pir1 and Pir2 can be used as anchors to simultaneously immobilize several glycosyltransferases at the yeast cell surface. Based on the high acceptor specificity of glycosyltransferases, we propose a simple in vitro method for oligosaccharide synthesis using the yeast intact cell as a biocatalyst.     

Structural analysis of the oligosaccharides of DR1 and DQw1 molecules

The major glycopeptide fractions of the alpha- and beta-chains of HLA-DR1 and DQw1 molecules were isolated on columns of immobilized concanavalin A (Con A), Lens culinaris (Lens), Ricinus communis agglutinin Type I (RCA), and leuko-phytohemagglutinin. Oligosaccharides were prepared from these fractions by enzymatic digestion with Endoglycosidases H or F and were analyzed on Bio-Gel P-6. The glycopeptides tightly bound to Con A (ConA III) were mostly associated with alpha-chains and were resolved as a single oligosaccharide peak (Kd = 0.72) on Bio-Gel P-6 after Endo H digestion. Man-5 is the minimal polymannosyl structure which can be deduced for the ConA III fractions of either DQw1 or DR1 oligosaccharides. The major component of the glycopeptides of the alpha-chains of either DR1 or DQw1 molecules which were weakly bound to Con A (ConA II fraction) did not interact with RCA before or after mild acid hydrolysis or neuraminidase treatment. This component represents a biantennary complex with neither terminal galactose nor sialic acid residues with a minimal structure terminating in N-acetyl glucosamine on the Mannose alpha 1----6 arm, referred to as GnM. The ConA II fractions, which constitute 10% of the total glycopeptides of beta-chains, are associated primarily with fucosylated, sialylated biantennary oligosaccharides not seen on the alpha-chains. The ConA I unbound fractions of either alpha- or beta-chains were mostly bound to RCA after mild acid hydrolysis, suggesting that the minimal structure was a sialylated triantennary structure. The major component associated with the beta-chains was bound to Lens such that a more definite structural assignment can be made, i.e., a triantennary structure with the Mannose on the alpha 1----6 arm substituted at C-2 and C-6. The oligosaccharides of alpha- and beta-chains were resolved as broad peaks on Bio-Gel P-6, suggesting that a mixture of tri- and tetraantennary structures with variable degrees of sialylation and galactosylation were present. The structural differences reported here between oligosaccharides of alpha- and beta-chains of DQw1 and of the two subsets of DR1 molecules could be responsible in part for the differential recognition properties expected of human class II molecules encoded by distinct loci.     

Dextran acceptor reaction of Streptococcus sobrinus glucosyltransferase GTF-I as revealed by using uniformly 13C-labeled sucrose.

A sucrose glucosyltransferase GTF-I from cariogenic Streptococcus sobrinus transferred the uniformly 13C-labeled glucosyl residue ([U-(13)C]Glc) from [U-(13)C]sucrose to exogenous dextran T500 at the non-reducing-end, mostly by alpha-(1-->6) linkages and partially by alpha-(1-->3) linkages, as revealed by the 13C-(13)C NMR coupling pattern. With increasing amounts of [U-(13)C]sucrose, transfer of [U-(13)C]Glc to the alpha-(1-->3)-linked chain became predominant without increase in the number of chains. The transfer of [U-(13)C]Glc to an isomaltopentaose acceptor occurred similarly to its transfer to T500. alpha-(1-->3)-branches in the [U-(13)C]dextran, specifically synthesized from [U-(13)C]sucrose by a Streptococcus bovis dextransucrase, were not formed by GTF-I, as judged by the observation that a newly-formed alpha-1,3,6-branched [U-(13)C]Glc was not detected, which could have been formed by transferring the unlabeled Glc from sucrose to the internal alpha-(1-->6)-linked [U-(13)C]Glc at C-3. The 13C-(13)C one-bond coupling constants (1J) were also recorded for the C-1--C-6 bond of the internal alpha-(1-->6)-linked [U-(13)C]Glc and of the non-reducing-end [U-(13)C]Glc.     

Trichoderma reesei alpha-1,2-mannosidase: structural basis for the cleavage of four consecutive mannose residues.

The process of N-glycosylation of eukaryotic proteins involves a range of host enzymes that delete or add saccharide monomers. While endoplasmic reticulum (E.R.) mannosidases cleave only one mannose to produce the Man8B isomer, an alpha-1,2-mannosidase from Trichoderma reesei can sequentially cleave all four 1,2-linked mannose sugars from a Man(9)GlcNAc(2) oligosaccharide, a feature reminiscent of the activity of Golgi mannosidases. We now report the structure of the T. reesei enzyme at 2.37 A resolution. The enzyme folds as an (alpha alpha)(7) barrel. The substrate-binding site of the T. reesei mannosidase differs appreciably from the Saccharomyces cerevisiae enzyme. In the former, shorter loops at the surface allow substrate protein to come closer to the catalytic site. There is more internal space available, so that different oligosaccharide conformations are sterically allowed in the T. reesei alpha-1,2-mannosidase.     

Chromosomal and plasmid-encoded enzymes are required for assembly of the R3-type core oligosaccharide in the lipopolysaccharide of Escherichia coli O157:H7

The type R3 core oligosaccharide predominates in the lipopolysaccharides from enterohemorrhagic Escherichia coli isolates including O157:H7. The R3 core biosynthesis (waa) genetic locus contains two genes, waaD and waaJ, that are predicted to encode glycosyltransferases involved in completion of the outer core. Through determination of the structures of the lipopolysaccharide core in precise mutants and biochemical analyses of enzyme activities, WaaJ was shown to be a UDP-glucose:(galactosyl) lipopolysaccharide alpha-1,2-glucosyltransferase, and WaaD was shown to be a UDP-glucose:(glucosyl)lipopolysaccharide alpha-1,2-glucosyltransferase. The residue added by WaaJ was identified as the ligation site for O polysaccharide, and this was confirmed by determination of the structure of the linkage region in serotype O157 lipopolysaccharide. The initial O157 repeat unit begins with an N-acetylgalactosamine residue in a beta-anomeric configuration, whereas the biological repeat unit for O157 contains alpha-linked N-acetylgalactosamine residues. With the characterization of WaaJ and WaaD, the activities of all of the enzymes encoded by the R3 waa locus are either known or predicted from homology data with a high level of confidence. However, when core oligosaccharide structure is considered, the origin of an additional alpha-1,3-linked N-acetylglucosamine residue in the outer core is unknown. The gene responsible for a nonstoichiometric alpha-1,7-linked N-acetylglucosamine substituent in the heptose (inner core) region was identified on the large virulence plasmids of E. coli O157 and Shigella flexneri serotype 2a. This is the first plasmid-encoded core oligosaccharide biosynthesis enzyme reported in E. coli.     

Anti-herpetic activity of a sulfated xylomannan from Scinaia hatei

Many viruses display affinity for cell surface heparan sulfate proteoglycans with biological relevance in virus entry. This raises the possibility of the application of sulfated polysaccharides in antiviral therapy. In this study we have analyzed polysaccharide fractions isolated from Scinaia hatei. The crude water extract (ShWE) as well as one fraction (F1) obtained by size exclusion chromatography had potent anti-HSV activity. Their inhibitory concentration 50% (IC50) values ranging from 0.5 to 4.6 microg/ml were much lower than the cytotoxic concentration 50% (CC50) values (1000 microg/ml). These fractions had very low anticoagulant activity. Furthermore, they had a weak inactivating effect on virions in a virucidal assay at concentrations in the range of 60-100 microg/ml. Chemical, chromatographic and spectroscopic methods showed that the major polysaccharide, which had 0.4 sulfate group per monomer unit and an apparent molecular mass of 160 kDa, contained a backbone of alpha-(1-->3)-linked D-mannopyranosyl residues substituted at C-6, C-4 and C-2 with single stub of beta-d-xylopyranosyl residues. Sulfate groups, when present, are located at C-4 of alpha-(1-->3)-linked D-mannopyranosyl units, and appeared to be very important for the anti-herpetic activity of this polymer.     

Fibrillogenic C-terminal fragment of alpha-1-antitrypsin activates human monocytes via oxidative mechanisms

Production of alpha-1-antitrypsin by human monocytes is an important factor in controlling tissue damage by proteases in the microenvironment of inflammation. Increases of four- to eightfold in levels of native and fragmented forms of alpha-1-antitrypsin have been detected in inflammatory loci in vivo. In this study we have extended our previous observation that the carboxyl-terminal peptide (C-36) of alpha-1-antitrypsin produced by specific proteinase cleavage, when added in its fibrillar form at concentrations of 5 microM or more to monocytes in culture, induces cytotoxic effects. Experiments with synthetic amyloid-forming peptides suggest fibril cytotoxicity to be mediated via a common oxidative stress mechanism. We undertook to determine whether C-36 fibril cytotoxicity also involves this common pathway. Monocytes stimulated with C-36 fibrils for 1 h showed significant elevation in monocyte chemoattractant protein-1 expression, induced reduced nicotinamide-adenine dinucleotide phosphate oxidase activity, increased intracellular lipid peroxidation, altered mitochondrial membrane potential, and increased cytosolic cytochrome c and caspase-3 activity. Treatment of monocytes with C-36 fibrils after 24 h also resulted in increased cytosolic cathepsin D activity, suggesting that lysosomes may also be destabilized over longer periods of time. In contrast, native alpha-1-antitrypsin only showed concentration and time-dependent effects on chemoattractant protein-1 expression, and these appear to be independent of oxidative stress. These results indicate that the cytotoxicity of the fibrillar fragment is mediated via oxidative mechanisms and support important multiple roles for native and also for cleaved forms of alpha-1-antitrypsin in monocyte recruitment and activation during inflammatory processes such as atherosclerosis.     

New strategy for the conformational analysis of carbohydrates based on NOE and 13C NMR coupling constants. Application to the flexible polysaccharide of Streptococcus mitis J22.

For complex oligosaccharides, which are relatively rigid with modest excursions from a single minimum energy conformation, it is straightforward to build conformational models from NOE data. Other oligosaccharides are more flexible with transitions between distinct minima separated by substantial energy barriers. We show that modeling based on scalar coupling data is superior to NOE-based modeling for the latter case. Long range 13C-13C and 13C-1H coupling constants measured for the heptasaccharide repeating subunit of the cell wall polysaccharide from Streptococcus mitis J22 are correlated with individual glycosidic dihedral angles, effectively uncoupling the degrees of freedom of the oligosaccharide and allowing a search for combinations of dihedral angles which are energetically reasonable, i.e., with no bad van der Waals contacts, and which can be combined to satisfy all the measured J values. Allowed values of the individual angles can then be combined to search for overall oligosaccharide conformations which contribute to the ensemble. We show that while the polysaccharide from S. mitis J22 is flexible, requiring multiple conformations, most of the flexibility is localized to a few bonds and only a rather small number of conformations is required to reproduce the experimental NOE and scalar coupling data.