Characterization of the Different Dextransucrase Activities Excreted in Glucose, Fructose, or Sucrose Medium by Leuconostoc mesenteroides NRRL B-1299

When grown in glucose or fructose medium in the absence of sucrose, Leuconostoc mesenteroides NRRL B-1299 produces two distinct extracellular dextransucrases named glucose glucosyltransferase (GGT) and fructose glucosyltransferase (FGT). The production level of GGT and FGT is 10 to 20 times lower than that of the extracellular dextransucrase sucrose glucosyltransferase (SGT) produced on sucrose medium (traditional culture conditions). GGT and FGT were concentrated by ultrafiltration before sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. Their molecular masses were 183 and 186 kDa, respectively, differing from the 195 kDa of SGT. The structural analysis of the dextran produced from sucrose and of the oligosaccharides synthesized by acceptor reaction in the presence of maltose showed that GGT and FGT are two different enzymes not previously described for this strain. The polymer synthesized by GGT contains 30% α(1→2) linkages, while FGT catalyzes the synthesis of a linear dextran only composed of α(1→6) linkages.     

Characterization of the Different Dextransucrase Activities Excreted in Glucose, Fructose, or Sucrose Medium by Leuconostoc mesenteroides NRRL B-1299

When grown in glucose or fructose medium in the absence of sucrose, Leuconostoc mesenteroides NRRL B-1299 produces two distinct extracellular dextransucrases named glucose glucosyltransferase (GGT) and fructose glucosyltransferase (FGT). The production level of GGT and FGT is 10 to 20 times lower than that of the extracellular dextransucrase sucrose glucosyltransferase (SGT) produced on sucrose medium (traditional culture conditions). GGT and FGT were concentrated by ultrafiltration before sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. Their molecular masses were 183 and 186 kDa, respectively, differing from the 195 kDa of SGT. The structural analysis of the dextran produced from sucrose and of the oligosaccharides synthesized by acceptor reaction in the presence of maltose showed that GGT and FGT are two different enzymes not previously described for this strain. The polymer synthesized by GGT contains 30% alpha(1-->2) linkages, while FGT catalyzes the synthesis of a linear dextran only composed of alpha(1-->6) linkages.     

Properties of Leuconostoc mesenteroides B-512FMC constitutive dextransucrase

Leuconostoc mesenteroides B-512FMC, a constitutive mutant for dextransucrase, was grown on glucose, fructose, or sucrose. The amount of cell-associated dextransucrase was about the same for the three sugars at different concentrations (0.6% and 3%). Enzyme produced in glucose medium was adsorbed on Sephadex G-100 and G-200, but much less enzyme was adsorbed when it was produced in sucrose medium. Sephadex adsorption decreased when the glucose-produced enzyme was preincubated with dextrans of molecular size greater than 10 kDa. The release of dextransucrase activity from Sephadex by buffer (20 mM acetate, pH 5.2) was the highest at 28°–30°C. The addition of dextran to the enzyme stimulated dextran synthesis but had very little effect on the temperature or pH stability. Dextransucrase purified by ammonium sulfate precipitation, hydroxyapatite chromatography, and Sephadex G-200 adsorption did not contain any carbohydrate, and it synthesized dextran, showing that primers are not necessary to initiate dextran synthesis. The purified enzyme had a molecular size of 184 kDa on SDS-PAGE. On standing at 4°C for 30 days, the native enzyme was dissociated into three inactive proteins of 65, 62, and 57 kDa. However, two protein bands of 63 and 59 kDa were obtained on SDS-PAGE after heat denaturation of the 184-kDa active enzyme at 100°C. The amount of 63-kDa protein was about twice that of 59-kDa protein. The native enzyme is believed to be a trimer of two 63-kDa and one 59-kDa monomers.     

One-step synthesis of isomalto-oligosaccharide syrups and dextrans of controlled size using engineered dextransucrase

Isomalto-oligosaccharides and dextrans of controlled molecular weight of about 10 and 40 kDa were produced using a simple one-step process using engineered L. mesenteroides NRRL B-512F dextransucrase variants. Isomalto-oligosaccharides were produced in a 58% yield by the acceptor reaction with glucose, and reached a degree of polymerization of at least 27 glucosyl units. Reaction conditions for optimal synthesis of dextrans of controlled molecular weight were defined, in respect of initial sucrose concentration and reaction temperature. Thus, we achieved synthesis with impressive yields of 69 and 75% for the 40 and 10 kDa dextran species, respectively. These two dextran sizes are particularly suitable for clinical applications, and are of great industrial demand. Compared with the traditional processes based on chemical hydrolysis and fractionation, which achieve only low yields, the new enzymatic methods offer improvement in quantity, quality and efficiency.     

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.     

Production of insoluble dextran using cell-bound dextransucrase of Leuconostoc mesenteroides NRRL B-523

Water-insoluble, cell-free dextran biosynthesis from Leuconostoc mesenteroides NRRL B-523 has been examined. Cell-bound dextransucrase is used to produce cell-free dextran in a sucrose-rich acetate buffer medium. A comparison between the soluble and insoluble dextrans is made for various sucrose concentrations, and 15% sucrose gave the highest amount of cell-free dextran for a given time. L. mesenteroides B-523 produces more insoluble dextran than soluble dextran. The near cell-free synthesis was validated in a batch reactor, by monitoring the cell growth which is a small (10(6)-10(7) CFU/mL) and constant value throughout the synthesis.     

An overview of purification methods of glycoside hydrolase family 70 dextransucrase

The enzyme dextransucrase (sucrose:1, 6-α-D-glucan 6-α-glucosyltransferase, EC 2.4.1.5) catalyses the synthesis of exopolysaccharide, dextran from sucrose. This class of polysaccharide has been extensively exploited in pharmaceutical industry as blood volume expander, as stabiliser in food industry and as a chromatographic medium in fine chemical industry because of their nonionic nature and stability. Majority of the dextrans are synthesized from sucrose by dextransucrase secreted mainly by bacteria belonging to genera Leuconostoc, Streptococcus and Lactobacillus. Bulk of the information on purification of extracellular dextransucrase has been generated from Leuconostoc species. Various methods such as precipitation by ammonium sulphate, ethanol or polyethylene glycol, phase partitioning, ultrafiltration and chromatography have been used to purify the enzyme. Purification of dextransucrase is rendered difficult by the presence of viscous dextran in the medium. However, processes like ultra-filtration, salt and PEG precipitation, chromatography and phase partitioning have been standardized and successfully used for higher scale purification of the enzyme. A recombinant dextransucrase from Leuconostoc mesenteroides B-512F with a histidine tag has been expressed in E. coli cells and purifi ed by immobilized metal ion chromatography. This review reports the available information on purifi cation methods of dextransucrase from Leuconostoc mesenteroides strains.     

A novel dextransucrase is produced by <Emphasis Type="Italic">Leuconostoc</Emphasis><Emphasis Type="Italic">citreum</Emphasis> strain B/110-1-2: an isolate used for the industrial production of dextran and dextran derivatives

The industrial Leuconostoc strain B/110-1-2 producing dextran and dextran derivatives was taxonomically identified by 16S rRNA as L. citreum. Its dextransucrase enzymes were characterized according to their cellular location and reaction specificity. In the presence of sucrose, the strain B/110-1-2 produced two cell-associated dextransucrases (31.54% of the total glucosyltransferase activity) with molecular weights of 160 and 240 kDa and a soluble dextransucrase (68.46%) at 160–180 kDa. Two open reading frames (ORF) coding for L. citreum strain B/110-1-2 dextransucrases were identified. One of them shared a 52% identity with the alternansucrase ASR of L. citreum NRRL B-1355 and with a putative annotated alternansucrase sequence found in the genome of L. citreum KM20. The structural analysis (HPAEC-PAD, HPSEC, and ¹³C-NMR) of the polymer and oligodextrans produced by the B/110-1-2 dextransucrases suggest this novel glucansucrase has specificity similar to a dextransucrase but not to an alternansucrase, producing a soluble linear dextran with glucose molecules linked mainly in α-1,6 and α-1,3 with α-1,4 branches. These results enhance the understanding of this industrially significant strain and will aid in distinguishing between physiologically similar Leuconostoc spp. strains.     

One-step synthesis of isomalto-oligosaccharide syrups and dextrans of controlled size using engineered dextransucrase

Isomalto-oligosaccharides and dextrans of controlled molecular weight of about 10 and 40 kDa were produced using a simple one-step process using engineered L. mesenteroides NRRL B-512F dextransucrase variants. Isomalto-oligosaccharides were produced in a 58% yield by the acceptor reaction with glucose, and reached a degree of polymerization of at least 27 glucosyl units. Reaction conditions for optimal synthesis of dextrans of controlled molecular weight were defined, in respect of initial sucrose concentration and reaction temperature. Thus, we achieved synthesis with impressive yields of 69 and 75% for the 40 and 10 kDa dextran species, respectively. These two dextran sizes are particularly suitable for clinical applications, and are of great industrial demand. Compared with the traditional processes based on chemical hydrolysis and fractionation, which achieve only low yields, the new enzymatic methods offer improvement in quantity, quality and efficiency.     

Characterization of a novel dextransucrase from Weissella confusa isolated from sourdough

Weissella confusa and Weissella cibaria isolated from wheat sourdoughs produce, from sucrose, linear dextrans due to a single soluble dextransucrase. In this study, the first complete gene sequence encoding dextransucrase from a W. confusa strain (LBAE C39-2) along with the one from a W. cibaria strain (LBAE K39) were reported. Corresponding gene cloning was achieved using specific primers designed on the basis of the draft genome sequence of these species. Deduced amino acid sequence of W. confusa and W. cibaria dextransucrase revealed common structural features of the glycoside hydrolase family 70. Notably, the regions located in the vicinity of the catalytic triad (D, E, D) are highly conserved. However, comparison analysis also revealed that Weissella dextransucrases form a distinct phylogenetic group within glucansucrases of other lactic acid bacteria. We then cloned the W. confusa C39-2 dextransucrase gene and successfully expressed the mature corresponding enzyme in Escherichia coli. The purified recombinant enzyme rDSRC39-2 catalyzed dextran synthesis from sucrose with a K _m of 8.6 mM and a V _max of 20 μmol/mg/min. According to ¹H and ¹³C NMR analysis, the polymer is a linear class 1 dextran with 97.2 % α-(1→6) linkages and 2.8 % α-(1→3) branch linkages, similar to the one produced by W. confusa C39-2 strain. The enzyme exhibited optimum catalytic activity for temperatures ranging from 35 to 40 °C and a pH of 5.4 in 20 mM sodium acetate buffer. This novel dextransucrase is responsible for production of dextran with predominant α-(1→6) linkages that could find applications as food hydrocolloids.     

The mechanism of dextransucrase action: Activation of dextransucrase from Streptococcus mutans OMZ 176 by dextran and modified dextran and the nonexistence of the primer requirement for the synthesis of dextran

Streptococcus mutans OMZ 176 was grown in a sucrose-free medium containing fructose as a carbohydrate source. Dextransucrase was precipitated from the culture supernatant with 40% saturated ammonium sulfate. The activity of dextransucrase was shown to be stimulated by exogenous dextran. Maximum activity was reached when the concentration of exogenous dextran was 2 mg/ml. Dextrans modified at the nonreducing ends by reaction with tripsyl chloride and/or by hydrolysis with an exodextranase also activated dextransucrase four to six times over that of a control. The exodextranasemodified dextrans have nonreducing chains that are very short in comparison with unmodified dextran and the tripsyl-modified dextrans have chains that are blocked at the nonreducing ends with a triisopropylbenzenesulfonyl group on the C₆ hydroxyl group. Because the nonreducing ends of the modified dextrans are not available for reaction, the activation of dextransucrase by these modified dextrans cannot be due to primer reactions with the nonreducing ends. The activation of dextransucrase, thus, must be by an alternate mechanism. Two alternative mechanisms discussed are an allosteric effect and nucleophilic displacement reactions by the added dextran. It was also found that the addition of increasing amounts of dextran shifted the synthesis from an insoluble dextran to a soluble dextran.     

High-temperature enhancement of 13C-N.M.R. chemical-shifts of unusual dextrans,and correlation with methylation structural analysis

Dextran fractions from NRRL strains Leuconostoc mesenteroides B-742, B-1299, B-1355, and Streptobacterium dextranicum B-1254 were examined by ¹³C-n.m.r. spectroscopy at 34 and 90°, and by methylation structural analysis. The native, structurally homogeneous dextran from L. mesenteroides NRRL B-1402 was also examined. The data allow correlations to be made between the structure and physical properties of the S (soluble) and L (less-soluble) fraction pairs of dextrans B-742, B-1254, B-1299, and B-1355. For the dextrans under consideration here, increasing solubility of the dextran (both in water and in aqueous ethanol) was found to correlate with decreasing percentages of α-d-(1→6)-linked d-glucopyranosyl residues. Both the diagnostic nature of the 70–75-p.p.m. spectral region with regard to type of dextran branching, and the increase in resolution of the polysaccharide spectra at higher temperatures, have been further confirmed.     

Gene encoding a dextransucrase-like protein in Leuconostoc mesenteroides NRRL B-512F

A gene, dsrT, encoding a dextransucrase-like protein was isolated from the genomic DNA libraries of Leuconostoc mesenteroides NRRL B-512F dextransucrase-like gene. The gene was similar to the intact open reading frames of the dextransucrase gene dsrS of L. mesenteroides NRRL B-512F, dextransucrase genes of strain NRRL B-1299 and streptococcal glucosyltransferase genes, but was truncated after the catalytic domain, apparently by the deletion of five nucleotides. dsrT mRNA was produced in this strain L. mesenteroides when cells were grown in a sucrose medum, but at a level of 20% of that of dsrS mRNA. The molecular weight of the dsrT gene product was 150,000 by SDS-PAGE. The product did not synthesize dextran, but had weak sucrose cleaving activity. The insertion of five nucleotides at the putative deletion point in dsrT resulted in an enzyme with a molecular weight of 210,000 and with dextransucrase activity.     

Inhibition of dextran synthesis by glucoamylase and endodextranase

In a model experiment, glucoamylase was shown to inhibit α-D-glucan synthesis as catalyzed by potato phosphorylase. Both glucoamylase and endodextranase inhibited dextran synthesis with dextransucrases of Leuconostoc mesenteroides. The inhibition could be ascribed to competition between glucoamylase and dextransucrase for the glucosyl groups at the non-reducing end of dextran. The inhibition caused by endodextranase may result from rapid and random hydrolysis of acceptor dextrans. Moreover, significantly low units of glucoamylase, as compared with endodextranase, effectively inhibited dextran synthesis. These results thus present evidence that bio-synthesis of dextran occurs by the addition of glucosyl groups at the non-reducing end of the growing dextran. The measurement of initial velocity suggested that the ping-pong Bi-Bi mechanism proposed for the levansucrase of Bacillus subtilis is also applicable to dextransucrase.     

Fourier-transform,infrared difference-spectrometry for structural analysis of dextrans

The Fourier-transform (F.t.), infrared (i.r.) spectra of a series of branched dextrans were examined. The dextrans studied were those from the N R R L collection designated Leuconostoc mesenteroides B-1142, B-1191, B-1299 fraction S, B-1355 fraction S, B-1402, and B-1422, and Streptobacterium dextranicum B-1254 fractions S[L] and L[S]. The spectrum of a levan, N R R L L. mesenteroides B-523 fraction M, was also examined, for comparison with the spectra of the dextrans. Meaningful results were obtained by “weight-normalizing” the spectral absorbance to that of the dextran of very low degree of branching (dextran B-1254 fraction L[S]), and then subtracting this spectrum of linear dextran from each of the other polysaccharide spectra. The resulting i.r.-absorbance difference-spectra were plotted, at uniform scale-expansion across the 1800-400-cm^?1 region, resulting in difference-absorbance features at ≈ 1100 and ≈ 800 cm^?1 for all branched dextrans. These absorbance differences could be correlated to the type and degree of dextran branching, which had previously been established by permethylation analysis. It was concluded that such F.t.-i.r. difference-spectra have general application for the structural analysis of polysaccharides.     

Structure and property engineering of α-D-glucans synthesized by dextransucrase mutants

Seven dextran types, displaying from 3 to 20% α(1→3) glycosidic linkages, were synthesized in vitro from sucrose by mutants of dextransucrase DSR-S from Leuconostoc mesenteroides NRRL B-512F, obtained by combinatorial engineering. The structural and physicochemical properties of these original biopolymers were characterized. When asymmetrical flow field flow fractionation coupled with multiangle laser light scattering was used, it was determined that weight average molar masses and radii of gyration ranged from 0.76 to 6.02 × 10(8) g·mol(-1) and from 55 to 206 nm, respectively. The ν(G) values reveal that dextrans Gcn6 and Gcn7, which contain 15 and 20% α(1→3) linkages, are highly branched and contain long ramifications, while Gcn1 is rather linear with only 3% α(1→3) linkages. Others display intermediate molecular structures. Rheological investigation shows that all of these polymers present a classical non-Newtonian pseudoplastic behavior. However, Gcn_DvΔ4N, Gcn2, Gcn3, and Gcn7 form weak gels, while others display a viscoelastic behavior that is typical of entangled polymer solutions. Finally, glass transition temperature T(g) was measured by differential scanning calorimetry. Interestingly, the T(g) of Gcn1 and Gcn5 are equal to 19.0 and 29.8 °C, respectively. Because of this low T(g), these two original dextrans are able to form rubber and flexible films at ambient temperature without any plasticizer addition. The mechanical parameters determined for Gcn1 films from tensile tests are very promising in comparison to the films obtained with other polysaccharides extracted from plants, algae or microbial fermentation. These results lead the way to using these dextrans as innovative biosourced materials.     

Kinetic modeling of oligosaccharide synthesis catalyzed by leuconostoc mesenteroides NRRL B-1299 dextransucrase

The kinetic behavior of soluble and insoluble forms of dextransucrase from Leuconostoc mesenteroides NRRL B-1299 was investigated with sucrose as substrate and maltose as acceptor. To study the parameters involved, a kinetic model was applied that was previously developed for L. mesenteroides NRRL B-512F dextransucrase. There are significant correlations between the parameters of the soluble form of B-1299 dextransucrase and those calculated for the B-512F enzyme; that is, their properties are comparable and differ from those of the insoluble form of B-1299 dextransucrase. Whereas the calculated parameters for high maltose concentrations describe the kinetic behavior very well, the time curves for low maltose concentrations were not described correctly. Therefore, the parameters were calculated separately for the two ranges. Copyright 1999 John Wiley & Sons, Inc.     

Development of constitutive dextransucrase hyper-producing mutants of Leuconostoc mesenteroides using the synchrotron radiation in the 70-1000 eV region

After irradiation with photons in the energy range of 70-1000 eV using the synchrotron radiation facility at Pohang, Korea, dextransucrase constitutive and hyper-producing mutants from Leuconostoc mesenteroides were isolated. The mutant (B-512FMCM) produced 13 times higher activity and showed complete constitutivity for dextransucrase production. It synthesized the same dextran as B-512FMC. The dextransucrase of the mutant transferred glucose from dextran to maltose. This novel method is a new technique for the development of industrial microorganisms.     

Purification and some properties of free and cell-associated dextransucrase from Streptococcus sanguis.

Dextransucrase of Streptococcus sanguis occurred in cell-free and cell-associated forms. Cell-free dextransucrase was purified by four successive chromatographies on Bio-Gel P 60, DEAE-cellulose, and Bio-Gel P 200 from the culture supernatant. The purification of cell-associated dextransucrase was made from the pellet of Streptococcus sanguis culture. Bacterial pellet was extracted with 1 M phosphate buffer (pH 6.0) and chromatographied by using an immunosorbent column. The two enzymes gave single bands in polyacrylamide gel electrophoresis. The molecular weight determined by sodium dodecyl sulfate polyacrylamide gel was about 100 000 daltons for the two forms of dextransucrases. The optimum pH of the cell-free and cell-associated enzymes was around 6 and the temperature optimum was broad for the two enzymes. The KM values for sucrose were respectively 2 mM and 3 mM for cell-free and cell-associated enzymes. When primer dextran was added, the reaction velocity increased but the KM for sucrose remained the same, and the KA for dextran was 200 muM for the two dextransucrases. Trehalose and maltose acted also as glucosyl residue acceptors. Purified enzymes had dextran synthesising activity and invertase-like activity. The same properties of the two forms of enzymes and the positive cross reaction against anti free and anti cell-associated globulins stongly suggest the identity of the two enzymes.