Glucosylation of raffinose via alternansucrase acceptor reactions

The glucansucrase known as alternansucrase [EC 2.4.1.140] can transfer glucosyl units from sucrose to raffinose to give good yields of oligosaccharides, which may serve as prebiotics. The main products were the tetrasaccharides α-d-Glcp-(1→3)-α-d-Galp-(1→6)-α-d-Glcp-(1↔2)-β-d-Fruf and α-d-Glcp-(1→4)-α-d-Galp-(1→6)-α-d-Glcp-(1↔2)-β-d-Fruf in ratios ranging from 4:1 to 9:1, along with lesser amounts of α-d-Glcp-(1→6)-α-d-Galp-(1→6)-α-d-Glcp-(1↔2)-β-d-Fruf. Ten unusual pentasaccharide structures were isolated. Three of these arose from glucosylation of the major tetrasaccharide product, two each from the minor tetrasaccharides, and three were the result of glucosylations of the fructose acceptor product leucrose or isomaltulose. The major pentasaccharide product arose from glucosylation of the major tetrasaccharide at position 4 of the fructofuranosyl unit, to give a subunit structure analogous to that of maltulose. A number of hexasaccharides and higher oligosaccharides were also produced. Unlike alternansucrase, dextransucrase [EC 2.4.1.5] gave only a single tetrasaccharide product in low yield, and no significant amounts of higher oligosaccharides. The tetrasaccharide structure from dextransucrase was found to be α-d-Glcp-(1→4)-α-d-Galp-(1→6)-α-d-Glcp-(1↔2)-β-d-Fruf, which is at odds with the previously published structure.     

Novel oligosaccharides synthesized from sucrose donor and cellobiose acceptor by alternansucrase

Cellobiose was tested as acceptor in the reaction catalyzed by alternansucrase (EC 2.4.1.140) from Leuconostoc mesenteroides NRRL B-23192. The oligosaccharides synthesized were compared to those obtained with dextransucrase from L. mesenteroides NRRL B-512F. With alternansucrase and dextransucrase, overall oligosaccharide synthesis yield reached 30 and 14%, respectively, showing that alternansucrase is more efficient than dextransucrase for cellobiose glucosylation. Interestingly, alternansucrase produced a series of oligosaccharides from cellobiose. Their structure was determined by mass spectrometry and [13C-1H] NMR spectroscopy. Two trisaccharides are first produced: alpha-D-glucopyranosyl-(1-->2)-[beta-D-glucopyranosyl-(1-->4)]-D-glucopyranose (compound A) and alpha-D-glucopyranosyl-(1-->6)-beta-D-glucopyranosyl-(1-->4)-D-glucopyranose (compound B). Then, compound B can in turn be glucosylated leading to the synthesis of a tetrasaccharide with an additional alpha-(1-->6) linkage at the non-reducing end (compound D). The presence of the alpha-(1-->3) linkage occurred only in the pentasaccharides (compounds C1 and C2) formed from tetrasaccharide D. Compounds B, C1, C2 and D were never described before. They were produced efficiently only by alternansucrase. Their presence emphasizes the difference existing in the acceptor reaction selectivity of the various glucansucrases.     

Alternansucrase acceptor reactions with D-tagatose and L-glucose

Alternansucrase (EC 2.4.1.140) is a d-glucansucrase that synthesizes an alternating alpha-(1-->3), (1-->6)-linked d-glucan from sucrose. It also synthesizes oligosaccharides via d-glucopyranosyl transfer to various acceptor sugars. Two of the more efficient monosaccharide acceptors are D-tagatose and L-glucose. In the presence of d-tagatose, alternansucrase produced the disaccharide alpha-d-glucopyranosyl-(1-->1)-beta-D-tagatopyranose via glucosyl transfer. This disaccharide is analogous to trehalulose. We were unable to isolate a disaccharide product from L-glucose, but the trisaccharide alpha-D-glucopyranosyl-(1-->6)-alpha-d-glucopyranosyl-(1-->4)-l-glucose was isolated and identified. This is analogous to panose, one of the structural units of pullulan, in which the reducing-end D-glucose residue has been replaced by its L-enantiomer. The putative L-glucose disaccharide product, produced by glucoamylase hydrolysis of the trisaccharide, was found to be an acceptor for alternansucrase. The disaccharide, alpha-D-glucopyranosyl-(1-->4)-L-glucose, was a better acceptor than maltose, previously the best known acceptor for alternansucrase. A structure comparison of alpha-D-glucopyranosyl-(1-->4)-L-glucose and maltose was performed through computer modeling to identify common features, which may be important in acceptor affinity by alternansucrase.     

Penta-, hexa-, and heptasaccharide acceptor products of alternansucrase

In the presence of suitable acceptor molecules, dextransucrase makes a homologous series of oligosaccharides in which the isomers differ by a single glucosyl unit, whereas alternansucrase synthesizes one trisaccharide, two tetrasaccharides, etc. For the example of maltose as the acceptor, if one considers only the linear, unbranched possibilities for alternansucrase, the hypothetical number of potential products increases exponentially as a function of the degree of polymerization (DP). Experimental evidence indicates that far fewer products are actually formed. We show that only certain isomers of DP >4 are formed from maltose in measurable amounts, and that these oligosaccharides belong to the oligoalternan series rather than the oligodextran series. When the oligosaccharide acceptor products from maltose were separated by size-exclusion chromatography and HPLC, only one pentasaccharide was isolated. Its structure was alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. Two hexasaccharides were formed in approximately equal quantities: alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc and alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. Just one heptasaccharide was isolated from the reaction mixture, alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. We conclude that the enzyme is incapable of forming two consecutive alpha-(1-->3) linkages, and does not form products with more than two consecutive alpha-(1-->6) linkages. The distribution of products may be kinetically determined.     

Acceptor products of alternansucrase with gentiobiose. Production of novel oligosaccharides for food and feed and elimination of bitterness

In the presence of suitable acceptor molecules, dextransucrase makes a homologous series of oligosaccharides in which the isomers differ by a single glucosyl unit, whereas alternansucrase synthesizes one trisaccharide, two tetrasaccharides, etc. Previously, we showed that alternansucrase only forms certain isomers of DP > 4 from maltose in measurable amounts, and that these oligosaccharides belong to the oligoalternan series rather than the oligodextran series. We now demonstrate that the acceptor products from gentiobiose, also formed in good yields (nearly 90% in unoptimized reactions), follow a pattern similar to those formed from maltose. The initial product is a single trisaccharide, α-d-Glcp-(1→6)-β-d-Glcp-(1→6)-d-Glc. Two tetrasaccharides were formed in approximately equal quantities: α-d-Glcp-(1→3)-α-d-Glcp-(1→6)-β-d-Glcp-(1→6)-d-Glc and α-d-Glcp-(1→6)-α-d-Glcp-(1→6)-β-d-Glcp-(1→6)-d-Glc. Just one pentasaccharide was isolated from the reaction mixture, α-d-Glcp-(1→6)-α-d-Glcp-(1→3)-α-d-Glcp-(1→6)-β-d-Glcp-(1→6)-d-Glc. Our hypothesis that the enzyme is incapable of forming two consecutive α-(1→3) linkages, and does not form products with more than two consecutive α-(1→6) linkages, apparently applies to other acceptors as well as to maltose. The glucosylation of gentiobiose reduces or eliminates its bitter taste.     

Understanding the polymerization mechanism of glycoside-hydrolase family 70 glucansucrases

Glucan formation catalyzed by two GH-family 70 enzymes, Leuconostoc mesenteroides NRRL B-512F dextransucrase and L. mesenteroides NRRL B-1355 alternansucrase, was investigated by combining biochemical and kinetic characterization of the recombinant enzymes and their respective products. Using HPAEC analysis, we showed that two molecules act as initiator of polymerization: sucrose itself and glucose produced by hydrolysis, the latter being preferred when produced in sufficient amounts. Then, elongation occurs by transfer of the glucosyl residue coming from sucrose to the non-reducing end of initially formed products. Dextransucrase preferentially produces an isomaltooligosaccharide series, whose concentration is always low because of the high ability of these products to be elongated and form high molecular weight dextran. Compared with dextransucrase, alternansucrase has a broader specificity. It produces a myriad of oligosaccharides with various alpha-1,3 and/or alpha-1,6 links in early reaction stages. Only some of them are further elongated. Overall alternan polymer is smaller in size than dextran. In dextransucrase, the A repeats often found in C-terminal domain of GH family 70 were found to play a major role in efficient dextran elongation. Their truncation result in an enzyme much less efficient to catalyze high molecular weight polymer formation. It is thus proposed that, in dextransucrase, the A repeats define anchoring zones for the growing chains, favoring their elongation. Based on these results, a semi-processive mechanism involving only one active site and an elongation by the non-reducing end is proposed for the GH-family 70 glucansucrases.     

Enzymatic synthesis and anti-coagulant effect of salicin analogs by using the Leuconostoc mesenteroides glucansucrase acceptor reaction

Glucansucrases from Leuconostoc mesenteroides catalyze the transfer of glucosyl units from sucrose to other carbohydrates by acceptor reaction. We modified salicyl alcohol, phenol and salicin by using various glucansucrases and with sucrose as a donor of glucosyl residues. Salicin, phenyl glucose, isosalicin, isomaltosyl salicyl alcohol, and a homologous series of oligosaccharides, connected to the acceptors and differing from one another by one or more glucose residues, were produced as major reaction products. By using salicin and salicyl alcohol as acceptors, B-1355C2 and B-1299CB-BF563 dextransucrases synthesized most widely diverse products, producing more than 12 and 9 different kinds of saccharides, respectively. With phenol, two acceptor products and oligosaccharides were synthesized by using the B-1299CB-BF563 dextransucrase. Salicyl derivatives, as acceptor products, showed higher anti-coagulation activity compared with that of salicin or salicyl alcohol that were used as acceptors.     

Gluco-oligosaccharides synthesized by glucosyltransferases from constitutive mutants of Leuconostoc mesenteroides strain Lm 28

Aims:  To find different types of glucosyltransferases (GTFs) produced by Leuconostoc mesenteroides strain Lm 28 and its mutant forms, and to check the effectiveness of gluco-oligosaccharide synthesis using maltose as the acceptor.
Methods and Results:  Constitutive mutants were obtained after chemical mutagenesis by ethyl methane sulfonate. Lm M281 produced more active GTFs than that obtained by the parental strain cultivated on sucrose. GTF from Lm M286 produced a resistant glucan, based on endo-dextranase and amyloglucosidase hydrolysis. The extracellular enzymes from Lm M286 catalyse acceptor reactions and transfer the glucose unit from sucrose to maltose to produce gluco-oligosaccharides (GOS). By increasing the sucrose/maltose ratio, it was possible to catalyse the synthesis of oligosaccharides of increasing degree of polymerization (DP).
Conclusions:  Different types of GTFs (dextransucrase, alternansucrase and levansucrase) were produced from new constitutive mutants of Leuc. mesenteroides . GTFs from Lm M286 can catalyse the acceptor reaction in the presence of maltose, leading to the synthesis of branched oligosaccharides.
Significance and Impact of the Study:  Conditions were optimized to synthesize GOS by using GTFs from Lm M286, with the aim of producing maximum quantities of branched-chain oligosaccharides with DP 3–5. This would allow the use of the latter as prebiotics.     

Characterization of a glucansucrase from Lactobacillus reuteri E81 and production of malto-oligosaccharides

Abstract

Glucansucrases, which can be produced by different Lactic Acid Bacteria (LAB), catalyze the synthesis of α-glucans with different structures and properties using sucrose as substrate. In this study, a novel glucansucrase (GTFA) from Lactobacillus reuteri E81 was identified and heterologously expressed. Alignments of GTFA with other glucansucrases revealed its novelty and a putative 3D model structure was obtained. The biochemical properties of the truncated enzyme without the N-terminal variable region, GTFA-ΔN, was characterized. The K_m and V_max were found to be 7.5?mM and 1.49?IU/mg, respectively, and it showed optimum activities at pH 7 and at 50?°C. The GTFA-ΔN produced in vitro an α-glucan with (α1 → 3) and (α1 → 6) glycosidic linkages using sucrose as the substrate. Importantly, GTFA-ΔN synthesized DP = 9 oligosaccharides using sucrose and maltose as the donor and acceptor sugars, respectively, as detected by TLC, HPLC, LC-MS and NMR analysis.     

Encapsulation in LentiKats of Dextransucrase from Leuconostoc mesenteroides NRRL B-1299, and its Effect on Product Selectivity

Insoluble (cell-bound) dextransucrase from Leuconostoc mesenteroides B-1299 was encapsulated in highly elastic and stable hydrogels formed by polyvinyl alcohol. The gelation was carried out by controlled partial drying at room temperature, resulting in lens-shaped particles, called LentiKats. A similar recovery of activity (approximately 55%) was achieved when compared with entrapment in calcium alginate gels. Under reaction conditions, the protein leakage in LentiKats was reduced from 18% to 4% by pre-treatment of the dextransucrase with glutaraldehyde. The immobilized dextransucrases were tested in the acceptor reaction with methyl α-D-glucopyranoside. The conversion to oligosaccharides using Lentikat-dextransucrase was higher than that obtained for alginate-dextransucrase, probably due to the reduction of diffusional limitations derived from its lenticular shape. In addition, a shift of selectivity towards the synthesis of oligosaccharides containing α(1→2) bonds was observed for the Lentikat-biocatalysts. These non-digestible compounds are supposed to be specifically fermented by beneficial species of the human microflora (prebiotic effect). The Lentikat-entrapped dextransucrase can be efficiently reused in this process at least for five cycles of 24 h.     

Structural characterization of enzymatically synthesized dextran and oligosaccharides from Leuconostoc mesenteroides NRRL B-1426 dextransucrase

Leuconostoc mesenteroides NRRL B-1426 dextransucrase synthesized a high molecular mass dextran (>2 × 10⁶ Da) with ～85.5% α-(1→6) linear and ～14.5% α-(1→3) branched linkages. This high molecular mass dextran containing branched α-(1→3) linkages can be readily hydrolyzed for the production of enzyme-resistant isomalto-oligosaccharides. The acceptor specificity of dextransucrase for the transglycosylation reaction was studied using sixteen different acceptors. Among the sixteen acceptors used, isomaltose was found to be the best, having 89% efficiency followed by gentiobiose (64%), glucose (30%), cellobiose (25%), lactose (22.5%), melibiose (17%), and trehalose (2.3%) with reference to maltose, a known best acceptor. The β-linked disaccharide, gentiobiose, showed significant efficiency for oligosaccharide production that can be used as a potential prebiotic.     

Screening and Application of Microbial Esterases for the Enantioselective Synthesis of Chiral Glycerol Derivatives

Glucansucrases from family 70 of glycoside-hydrolases catalyse the synthesis of α-glucans with various types of osidic linkages from sucrose. Among these enzymes, alternansucrase (ASR) and dextransucrase E (DSR-E) catalyse the formation of unusual α-glucans. ASR catalyses the synthesis of linear glucan with α-1,3 and α-1,6 alternating linkages and DSR-E synthesizes a glucan containing α-1,6 linkages in the linear chain and α-1,2 branches. The sequence analysis of these enzymes enabled the identification of structural elements suspected to be involved in the enzyme specificities. Biochemical characterization of ASR and DSR-E variants obtained from gene truncations or site-directed mutagenesis experiments showed that the specificity of these enzymes to form different types of osidic linkage is controlled by two different approaches. For ASR, the double specificity is controlled by only one catalytic domain where important amino acids involved in the enzyme specificity have been identified. In the case of DSR-E, the double specificity is controlled by two different catalytic domains both belonging to family 70, each domain being specific of one type of linkage.     

Immobilization of Chloroplast Photosystems

Highly branched α-glucan molecules exhibit low digestibility for α-amylase and glucoamylase, and abundant in α-(1→3)-, α-(1→6)-glucosidic linkages and α-(1→6)-linked branch points where another glucosyl chain is initiated through an α-(1→3)-linkage. From a culture supernatant of Paenibacillus sp. PP710, we purified α-glucosidase (AGL) and α-amylase (AMY), which were involved in the production of highly branched α-glucan from maltodextrin. AGL catalyzed the transglucosylation reaction of a glucosyl residue to a nonreducing-end glucosyl residue by α-1,6-, α-1,4-, and α-1,3-linkages. AMY catalyzed the hydrolysis of the α-1,4-linkage and the intermolecular or intramolecular transfer of maltooligosaccharide like cyclodextrin glucanotransferase (CGTase). It also catalyzed the transfer of an α-1,4-glucosyl chain to a C3- or C4-hydroxyl group in the α-1,4- or α-1,6-linked nonreducing-end residue or the α-1,6-linked residue located in the other chains. Hence AMY was regarded as a novel enzyme. We think that the mechanism of formation of highly branched α-glucan from maltodextrin is as follows: α-1,6- and α-1,3-linked residues are generated by the transglucosylation of AGL at the nonreducing ends of glucosyl chains. Then AMY catalyzes the transfer of α-1,4-chains to C3- or C4-hydroxyl groups in the α-1,4- or α-1,6-linked residues generated by AGL. Thus the concerted reactions of both AGL and AMY are necessary to produce the highly branched α-glucan from maltodextrin.     

Inhibition of Mammalian Topoisomerase I by Xestoquinone and Halenaquinone

The substrate specificity of dextrin dextranase (EC 2.4.1.2; DDase) was investigated. This enzyme acted on maltose and isomaltose in addition to starch and dextrin, but did not act on other gluco-disaccharides. When various saccharides were allowed to react with salicin as a glucosyl acceptor, glucosyl residues were transferred to salicin on the reaction with maltose, isomaltose, starch, and dextran as glucosyl donors. On the other hand, when starch as a glucosyl donor was allowed to react with various saccharides, glucosyl residues of starch were transferred to d-glucose, d-xylose, and oligosaccharides that had glucosyl or xylosyl residues at non-reducing termini. Methyl α- and β-d-glucosides also acted as acceptors. Furthermore DDase transferred glucosyl residues from starch to glucose derivatives such as 2-deoxy-, 2-acetamido-2-deoxy-, 3-O-methyl-, and 6-deoxy-d-glucoses. When starch was used as a glucosyl donor, two products formed by transglucosylation to d-glucose as an acceptor were found to be maltose and isomaltose, and a product formed by transglucosylation to d-xylose as an acceptor was found to be glucosyl-α-l,4-xylose.     

The effect of maltose on dextran yield and molecular weight distribution

Dextran synthesis has been studied since the Second World War, when it was used as blood plasma expander. This polysaccharide composed of glucose units is linked by an α-1,6-glucosidic bond. Dextransucrase is a bacterial extra cellular enzyme, which promotes the dextran synthesis from sucrose. When, besides sucrose, another substrate (acceptor) is also present in the reactor, oligosaccharides are produced and part of the glucosyl moieties from glucose is consumed to form these acceptor products, decreasing the dextran yield. Although dextran enzymatic synthesis has been extensively studied, there are few published studies regarding its molecular weight distribution. In this work, the effect of maltose on yield and dextran molecular weight synthesized using dextransucrase from Leuconostoc mesenteroides B512F, was investigated. According to the obtained results, maltose is not able to control and reduce dextran molecular weight distribution and synthesis carried out with or without maltose presented the same molecular weight distribution profile.     

Synthesis of methyl alpha-D-glucooligosaccharides by entrapped dextransucrase from Leuconostoc mesenteroides B-1299

The synthesis of methyl alpha-D-glucooligosaccharides, using sucrose as glucosyl donor and methyl alpha-D-glucopyranoside as acceptor, was studied with dextransucrase from Leuconostoc mesenteroides NRRL B-1299. The enzyme was immobilized by entrapment in alginate. By NMR and mass spectrometry we identified three homologous series (S1-S3) of methyl alpha-D-glucooligosaccharides. Series S2 and S3 were characterized by the presence of alpha(1-->2) linkages, in combination with alpha(1-->6) bonds. Two parameters, sucrose to acceptor concentration ratio (S/A) and the total sugar concentration (TSC) determined the yield of methyl alpha-D-glucooligosaccharides. The maximum concentration achieved of the first acceptor product, methyl alpha-D-isomaltoside, was 65 mM using a S/A 1:4 and a TSC of 336 g l(-1). When increasing temperature, a shift of selectivity towards compounds containing alpha(1-->2) bonds was observed. The formation of leucrose as a side process was very significant (reaching values of 32 g l(-1)) at high sucrose concentrations.     

Isolation of a gene from Leuconostoc citreum B/110-1-2 encoding a novel dextransucrase enzyme

The amplicon encoding dextransucrase DSR-F from Leuconostoc citreum B/110-1-2, a novel sucrose glucosyltransferase (GTF)-specific for α-1,6 and α-1,3 glucosidic bond synthesis, with α-1,4 branching was cloned, sequenced, and expressed into Escherichia coli JM109. Recombinant enzyme catalyzed oligosaccharides synthesis from sucrose as donor and maltose acceptor. The dsrF gene encodes for a protein (DSR-F) of 1,528 amino acids, with a theoretical molecular mass of 170447.72 Da (~170 kDa). From amino acid sequence comparison, it appears that DSR-F possesses the same domains as those described for GTFs. However, the variable region is longer than in other GTFs (by 100 amino acids) and two APY repeats (a 79 residue long motif with a high number of conserved glycine and aromatic residues, characterized by the presence of the three consecutive residues Ala, Pro, and Tyr) were identified in the glucan binding domain. The DSR-F catalytic domain possesses the catalytic triad involved in the glucosyl enzyme formation. The amino acid sequence of this domain shares a 56% identity with catalytic domain of the alternansucrase ASR from L. citreum NRRL B-1355 and with the catalytic domain of a putative alternansucrase sequence found in the genome of L. citreum KM20. A truncated active variant DSR-F-∆SP-∆GBD of 1,251 amino acids, with a molecular mass of 145 544 Da (~145 kDa), was obtained.     

Purification of membrane-bound dopamine beta-monooxygenase from chromaffin granules: relation to soluble dopamine beta-monooxygenase

Previous studies have indicated that α-d-1-fluoroglucose is a glycosyl donor for glucosyl transferases (5, 6) including dextransucrases formed by Leuconostoc and Streptococcus mutans. The present report confirms these observations with dextransucrase isolated from S. sanguis and conclusively establishes the details of this reaction as well as proving that mechanism of fluoroglucose transfer is comparable to that glucosyl transfer from sucrose. A new procedure for monitoring the reaction is reported, and is based on the measurement of proton formation using the pH indicator, bromcresol purple. Production of F^? was found to be stoichiometric with proton production. Rate studies with the substrate indicate that α-1-fluoroglucose undergoes spontaneous hydrolysis, which is greatly increased in the presence of nucleophilic buffers. When [¹⁴C]maltose and α-1-fluoroglucose or [¹⁴C]α-1-fluoroglucose and maltose were incubated with dextransucrase, a series of oligosaccharide products was observed. The results indicate that the glucosyl moiety of α-1-fluoroglucose transferred to the acceptor. The nature of formation of the products are consistent with a series of precursor-product reactions. Product analysis of the saccharides by borohydride reduction analysis demonstrated that the glucosyl unit was added to the nonreducing end of maltose. When either [¹⁴C]fructose or [¹⁴C]-α-1-fluoroglucose were incubated with enzyme, a reaction was observed which was analogous to the isotopic-exchange reaction catalyzed by the enzyme in the presence of [¹⁴C]fructose and sucrose.     

Improvement of Gene Targeting in Aspergillus nidulans with Excess Non-Homologous Fragments

An α-glucosidase was purified in an electrophoretically pure state from an extract of koji culture of Aspergillus sp. KT-11. This enzyme was found to have a transferring activity when the reaction was done in a high concentration of leucrose at pH 4.5. Two kinds of transfer products, fractions I and II, were obtained from leucrose by the enzyme and they were identified as [(α-D-glucopyranosyl-(1 →6)-α-D-glucopyranosyl-(1 →6)- α -D-glucopyranosyl-(1→5)-D-fructopyranose] and [α-D-glucopyranosyl-(1 →6)-α-D-glucopyranosyl-(1→5)-D- fructopyranose], respectively. These are considered to be novel oligosaccharides     

Structural analysis of enzyme-resistant isomaltooligosaccharides reveals the elongation of α-(1→3)-linked branches in Weissella confusa dextran

Weissella confusa VTT E-90392 is an efficient producer of a dextran that is mainly composed of α-(1→6)-linked D-glucosyl units and very few α-(1→3) branch linkages. A mixture of the Chaetomium erraticum endodextranase and the Aspergillus niger α-glucosidase was used to hydrolyze W. confusa dextran to glucose and a set of enzyme-resistant isomaltooligosaccharides. Two of the oligosaccharides (tetra- and hexasaccharide) were isolated in pure form and their structures elucidated. The tetrasaccharide had a nonreducing end terminal α-(1→3)-linked glucosyl unit (α-D-Glcp-(1→3)-α-D-Glcp-(1→6)-α-D-Glcp-(1→6)-α-D-Glc), whereas the hexasaccharide had an α-(1→3)-linked isomaltosyl side group (α-D-Glcp-(1→6)[α-D-Glcp-(1→6)-α-D-Glcp-(1→3)]-α-D-Glcp-(1→6)-α-D-Glcp-(1→6)-α-D-Glc). A mixture of two isomeric oligosaccharides was also obtained in the pentasaccharide fraction, which were identified as (α-D-Glcp-(1→6)-α-D-Glcp-(1→3)-α-D-Glcp-(1→6)-α-D-Glcp-(1→6)-α-D-Glc) and (α-D-Glcp-(1→6)[α-D-Glcp-(1→3)]-α-D-Glcp-(1→6)-α-D-Glcp-(1→6)-α-D-Glc). The structures of the oligosaccharides indicated that W. confusa dextran contains both terminal and elongated α-(1→3)-branches. This is the first report evidencing the presence of elongated branches in W. confusa dextran. The (1)H and (13)C NMR spectroscopic data on the enzyme-resistant isomaltooligosaccharides with α-(1→3)-linked glucosyl and isomaltosyl groups are published here for the first time.