Mechanism of synthesis of D-glucans by D-glucosyltransferases from Streptococcus mutans 6715

Two glucosyltransferases from Streptococcus mutans 6715 were purified and separated. One of the glucosyltransferases synthesized an insoluble glucan, and the other, a soluble glucan. The enzymes were immobilized on Bio-Gel P-2 beads, and the mechanism of glucan synthesis was studied by pulse and chase techniques with 14C-sucrose. Label was associated with the immobilized enzymes. The label could be quantitatively released by heating at pH 2. Analysis of the labeled products from the pulse experiment showed labeled glucose and labeled glucan; the chase experiment showed labeled glucan and a significant decrease in labeled glucose. The glucans from the pulse and the chase experiments were separated from glucose by chromatography on Bio-Gel P-6. They were reduced with sodium borohydride, and the products hydrolyzed with acid. Analysis of the labeled products from the reduced and hydrolyzed, pulsed glucans showed labeled glucose and labeled glucitol; label in the glucitol was greatly decreased in the chase experiment. These experiments showed that glucose and glucan were covalently attached to the active site of the enzymes during synthesis, and that the glucose was being transferred to the reducing end of the glucan chain. A mechanism for the synthesis of the glucans is proposed in which there are two catalytic groups on each enzyme that holds glucosyl and glucanosyl units. During synthesis, the glucosyl and glucanosyl units alternate between the two sites, giving elongation of the glucans from the reducing end. The addition of increasing amounts of B-512F dextran to the insoluble-glucan-forming glucosyltransferase produced a decrease in the proportion of insoluble glucan formed and a concomitant increase in a soluble glucan. The total amount of glucan synthesized (soluble plus insoluble) was increased 1.6 times over the amount of insoluble glucan formed when no exogenous dextran was added. It is shown that the addition of B-512F dextran affects the solubility of the synthesized alpha-(1 to 3)-glucan by accepting alpha-(1-3)-glucan chains at various positions along the dextran chain, to give a soluble, graft polymer.     

Identification of amino acid residues in Streptococcus mutans glucosyltransferases influencing the structure of the glucan product.

The glucosyltransferases (GTFs) of mutans streptococci are important virulence factors in the sucrose-dependent colonization of tooth surfaces by these organisms. To investigate the structure-function relationship of the GTFs, an approach was initiated to identify amino acid residues of the GTFs which affect the incorporation of glucose residues into the glucan polymer. Conserved amino acid residues were identified in the GTF-S and GTF-I enzymes of the mutans streptococci and were selected for site-directed mutagenesis in the corresponding enzymes from Streptococcus mutans GS5. Conversion of six amino acid residues of the GTF-I enzyme to those present at the corresponding positions in GTF-S, either singly or in multiple combinations, resulted in enzymes synthesizing increased levels of soluble glucans. The enzyme containing six alterations synthesized 73% water-soluble glucan in the absence of acceptor dextran T10, while parental enzyme GTF-I synthesized no such glucan product. Conversely, when residue 589 of the GTF-S enzyme was converted from Thr to either Asp or Glu, the resulting enzyme synthesized primarily water-insoluble glucan in the absence of the acceptor. Therefore, this approach has identified several amino acid positions which influence the nature of the glucan product synthesized by GTFs.     

Isolation and purification of Flavobacterium alpha-1,3-glucanase-hydrolyzing, insoluble, sticky glucan of Streptococcus mutans.

Studies were made on the physical and chemical properties of polysaccharides synthesized by cell-free extracts of Streptococcus mutans, Streptococcus sanguis, and Streptococcus sp. and their susceptibilities to dextranases. Among the polysaccharides examined, insoluble glucans were rather resistant to available dextranase preparations, and the insoluble, sticky glucan produced by S. mutans OMZ 176, which could be important in formation of dental plaques, was the most resistant. By enrichment culture of soil specimens, using OMZ 176 glucans as the sole carbon source, an organism was isolated that produced colonies surrounded by a clear lytic zone on opaque agar plates containing the OMZ 176 glucan. The organism was identified as a strain of Flavobacterium and named the Ek-14 bacterium. EK-14 bacterium was grown in Trypticase soy broth, and an enzyme capable of hydrolyzing the OMZ 176 glucan was concentrated from the culture supernatant and purified by negative adsorption on a diethylaminoethyl-cellulose (DE-32) column and gradient elution chromatography with a carboxymethyl-cellulose (CM-32) column. The enzyme was a basic protein with an isoelectric point of pH 8.5 and molecular weight of 65,000. Its optimum pH was 6.3 and its optimal temperature was 42 C. The purified enzyme released 11% of the total glucose residues of the OMZ 176 glucan as reducing sugars and solubilized about half of the substrate glucan. The products were found to be isomaltose, nigerose, and nigerotriose, with some oligosaccharides. The purified enzyme split the alpha-1,3-glucan endolytically and was inactive toward glucans containing alpha-1,6, alpha-1,4, beta-1,3, beta-1,4, and/or beta-1,6 bonds as the main linkages.     

Effect of dextran and ammonium sulphate on the reaction catalysed by a glucosyltransferase complex from Streptococcus mutans

The highly aggregated proteins precipitated by (NH4)2SO4 from the culture fluid of three strains of Streptococcus mutans gradually released less aggregated glucosyltransferase activities - dextransucrase and mutansucrase - which catalysed the synthesis of water-soluble and insoluble glucans from sucrose. Mutansucrase was eluted from a column of Sepharose 6B before dextransucrase. This activity was lost during subsequent dialysis and gel filtration, but there was a corresponding increase in dextransucrase activity which catalysed the formation of soluble glucan when incubated with sucrose alone, and insoluble glucan when incubated with sucrose and 1.55 M-(NH4)2SO4. Relative rates of synthesis of soluble and insoluble glucan in the presence of 1.55 M-(MH4)2SO4 were dependent upon the enzyme concentration: high concentrations favoured insoluble glucan synthesis. Insoluble glucans synthesized by mutansucrase or by dextransucrase in the presence of 1.55 M-(NH4)2SO4 were more sensitive to hydrolysis by mutanase than by dextranse, but soluble glucans were more extensively hydrolysed by dextranase than by mutanase. Partially purified dextransucrase sedimented through glycerol density gradients as a single symmetrical peak with an apparent molecular weight in the range 100000 to 110000. In the presence of 1.55 M-(NH4)2SO4, part of the activity sedimented rapidly as a high molecular weight aggregate. The results strongly suggest that soluble and insoluble glucans are synthesized by interconvertible forms of the same glucosyltransferase. The aggregated form, mutansucrase, preferentially catalyses (1 leads to 3)-alpha bond formation but dissociates during gel filtration to the dextransucrase form which catalyses (1 leads to 6)-alpha bond formation.     

Characterization of the extracellular,water-insoluble α-D-glucans of oral streptococci by methylation analysis,and by enzymic synthesis and degradation

Methylation analysis of water-insoluble α-D-glucans synthesized from sucrose by culture filtrates from several strains of Streptococcus spp. has proved that all of the glucans were highly branched and that the chains contained (1→6)- and (1→3)-linked D-glucose residues not involved in branch points. Hydrolysis of the glucans with a specific endo-(1→3)-α-D-glucanase demonstrated that the majority of the (1→3)-linked glucose residues were arranged in sequences. D-Glucose was the major product of the hydrolysis, and a small proportion of nigerose was also released. The use of a specific endo-(1→6)-α-D-glucanase similarly indicated that the glucans also contained sequences of (1→6)-linked α-D-glucose residues, and that those chains were branched. Two D-glucosyltransferases (GTF-S and GTF-I), which reacted with sucrose to synthesize a soluble glucan and a water-insoluble glucan, respectively, were separated from culture filtrates of S. mutans OMZ176. The soluble glucan was characterized as a branched (1→6)-α-D-glucan, whereas the insoluble one was a relatively linear (1→3)-α-D-glucan. The hypothesis is advanced that the glucosyltransferases can transfer glucan sequences by means of acceptor reactions similar to those proposed by Robyt for dextransucrase, leading to the synthesis of a highly branched glucan containing both types of chain. The resulting structure is consistent with the evidence obtained from methylation analysis and enzymic degradations, and explains the synergy displayed when the two D-glucosyltransferases interact with sucrose. Variations in one basic structure can account for the characteristics of water-insoluble glucans from S. sanguis and S. salivarius, and for the strain-dependent diversity of S. mutans glucans.     

The effect of soluble glucan derivates on spleen colony-forming units in sublethally irradiated mice

We examined the effects of 5 soluble derivatives of yeast glucan on the formation of exogenous (CFU-S) and endogenous (E-CFU) colony-forming units in the spleens of sublethally irradiated (⁶⁰Co, 6.5–7.0 Gy) mice of two inbred strains. For the estimation of CFU-S, glucans were administered intravenously either to donors or recipients of spleen cells 24 h prior to irradiation or removal of the spleen. The number of CFU-S was increased when both the donors and recipients were treated with glucan; the highest increase was obtained with glucans S, P and K. All glucan preparations increased significantly also the number of E-CFU even when administered 90 min after irradiation. There exist differences in the response to the stimulatory effect of glucans among individual mouse strains. Thus, for example, the stimulatory effect of glucan KM on the E-CFU number was significantly more pronounced in strain A/Ph than in strain C57B1/6.     

Characterisation of the extracellular polysaccharides produced by isolates of the fungus Acremonium

Solid state (13)C NMR studies of the extracellular glucans from the fungi Acremonium persicinum C38 (QM107a) and Acremonium sp. strain C106 indicated a backbone of (1-->3)-beta-linked glucosyl residues with single (1-->6)-beta-linked glucosyl side branches for both glucans. Analyses of enzymatic digestion products suggested that the average branching frequency for the A. persicinum glucan (66.7% branched) was much higher than that of the Acremonium sp. strain C106 glucan (28.6% branched). The solid state (13)C NMR spectra also indicated that both glucans are amorphous polymers with no crystalline regions, and the individual chains are probably arranged as triple helices.     

Interaction of glucosyltransferase from Streptococcus mutans with various glucans

Cell-free glucosyltransferase of Streptococcus mutans strain B13 (serotype d) exclusively synthesized water-insoluble glucan from sucrose. The insoluble glucan possessed strong glucan-associated glucosyltransferase activity even after extensive washing and lyophilization. Furthermore, cell-free glucosyltransferase became bound to heat-treated water-insoluble glucan or to heat-treated S. mutans B13 cells grown in Todd Hewitt broth, and the resulting glucan and cells adhered to a glass surface in the presence of exogenous sucrose. No other water-insoluble glucans bound significant quantities of glucosyltransferase. Glucan synthesis by free or glucan-bound glucosyltransferase was stimulated by low concentrations (1 to 5 mg ml-1) of isomaltose or water-soluble dextrans of various molecular weights, but higher concentrations (10 mg ml-1) inhibited glucan synthesis. The glucan synthesized in the presence of primer dextrans exhibited a reduced ability to adhere to a glass surface. Certain sugars such as maltose and fructose significantly lowered the yield of insoluble glucans. Preincubation of glucosyltransferase with the low molecular weight dextran T10 increased subsequent binding to S. mutans B13 insoluble glucan, whereas preincubation with higher molecular weight dextrans significantly inhibited the glucosyltransferase binding.     

Chain-length specificities of maize starch synthase I enzyme: studies of glucan affinity and catalytic properties

It is widely known that some of the starch synthases and starch-branching enzymes are trapped inside the starch granule matrix during the course of starch deposition in amyloplasts. The objective of this study was to use maize SSI to further our understanding of the protein domains involved in starch granule entrapment and identify the chain-length specificities of the enzyme. Using affinity gel electrophoresis, we measured the dissociation constants of maize SSI and its truncated forms using various glucans. The enzyme has a high degree of specificity in terms of its substrate-enzyme dissociation constant, but has a greatly elevated affinity for increasing chain lengths of alpha-1, 4 glucans. Deletion of the N-terminal arm of SSI did not affect the Kd value. Further small deletions of either N- or C-terminal domains resulted in a complete loss of any measurable affinity for its substrate, suggesting that the starch-affinity domain of SSI is not discrete from the catalytic domain. Greater affinity was displayed for the amylopectin fraction of starch as compared to amylose, whereas glycogen revealed the lowest affinity. However, when the outer chain lengths (OCL) of glycogen were extended using the phosphorylase enzyme, we found an increase in affinity for SSI between an average OCL of 7 and 14, and then an apparently exponential increase to an average OCL of 21. On the other hand, the catalytic ability of SSI was reduced several-fold using these glucans with extended chain lengths as substrates, and most of the label from [14C]ADPG was incorporated into shorter chains of dp < 10. We conclude that the rate of catalysis of SSI enzyme decreases with the OCL of its glucan substrate, and it has a very high affinity for the longer glucan chains of dp approximately 20, rendering the enzyme catalytically incapable at longer chain lengths. Based on the observations in this study, we propose that during amylopectin synthesis shorter A and B1 chains are extended by SSI up to a critical chain length that soon becomes unsuitable for catalysis by SSI and hence cannot be elongated further by this enzyme. Instead, SSI is likely to become entrapped as a relatively inactive protein within the starch granule. Further glucan extension for continuation of amylopectin synthesis must require a handover to other SS enzymes which can extend the glucan chains further or for branching by branching enzymes. If this is correct, this proposal provides a biochemical basis to explain how the specificities of various SS enzymes determine and set the limitations on the length of A, B, C chains in the starch granule.     

Regulation of glucosyl- and fructosyltransferase synthesis by continuous cultures of Streptococcus mutans

Streptococcus mutans strains Ingbritt, and its derivative B7 which had been passaged through monkeys, have been used to investigate how the synthesis of extracellular glucosyl- and fructosyltransferases is regulated. The most active enzyme from carbon-limited continuous cultures was a fructosyltransferase; enzymes catalysing the formation of water-insoluble glucans from sucrose were relatively inactive. Dextransucrase (EC 2.4.1.5), which catalyses soluble glucan synthesis, was most active in the supernatant fluid from cultures grown with excess glucose, fructose or sucrose, but full activity was detected only when the enzyme was incubated with both sucrose and dextran. Little dextransucrase activity was detected in carbon-limited cultures. It is concluded that glucosyl- and fructosyltransferases are constitutive enzymes in that they are synthesized at similar rates during growth with an excess of the substrate or of the products of the reactions which they catalyse. Although the Ingbritt strain was originally isolated from a carious lesion, it is now a poor source of glucosyltransferase activity. Glucosyltransferases were extremely active in cultures of a recent clinical isolate, strain 3209, and were apparently induced during growth with excess glucose.     

Biochemical Characterization of the Chlamydomonas reinhardtii α-1,4 Glucanotransferase Supports a Direct Function in Amylopectin Biosynthesis

Plant α-1,4 glucanotransferases (disproportionating enzymes, or D-enzymes) transfer glucan chains among oligosaccharides with the concomitant release of glucose (Glc). Analysis of Chlamydomonas reinhardtii sta11-1 mutants revealed a correlation between a D-enzyme deficiency and specific alterations in amylopectin structure and starch biosynthesis, thereby suggesting previously unknown biosynthetic functions. This study characterized the biochemical activities of the α-1,4 glucanotransferase that is deficient in sta11-1 mutants. The enzyme exhibited the glucan transfer and Glc production activities that define D-enzymes. D-enzyme also transferred glucans among the outer chains of amylopectin (using the polysaccharide chains as both donor and acceptor) and from malto-oligosaccharides into the outer chains of either amylopectin or glycogen. In contrast to transfer among oligosaccharides, which occurs readily with maltotriose, transfer into polysaccharide required longer donor molecules. All three enzymatic activities, evolution of Glc from oligosaccharides, glucan transfer from oligosaccharides into polysaccharides, and transfer among polysaccharide outer chains, were evident in a single 62-kD band. Absence of all three activities co-segregated with the sta11-1 mutation, which is known to cause abnormal accumulation of oligosaccharides at the expense of starch. To explain these data we propose that D-enzymes function directly in building the amylopectin structure.     

Identification of a alpha-NeuAc-(2----3)-beta-D-galactopyranosyl N-acetyl-beta-D-galactosaminyltransferase in human kidney

Microsomal preparations from human kidney were found to contain enzymic activity capable to transfer N-acetylgalactosamine from UDP-N-acetylgalactosamine to native bovine fetuin. The acceptor structures on the fetuin molecules were identified as N- as well as O-linked glycans with a markedly higher incorporation into the N-linked carbohydrate chains. Analysis of the alkali-labile transferase products by thin-layer chromatography indicated that the enzyme is able to synthesize structures having mobilities identical with those found on glycophorin from Cad erythrocytes. Mild acid treatment and enzymic hydrolysis with N-acetylhexosaminidase from jack beans of the N-linked transferase products suggested that beta-D-GalpNAc-(1----4)-[alpha-NeuAc-(2----3)]-beta-D-Galp-(1----s tructures were formed by the enzymic reaction on both N- and O-linked acceptors. The enzyme might, therefore, be involved in the biosynthesis of Sda (and Cad) antigenic structures. By use of various oligosaccharides, glycopeptides, and glycolipids having well characterized carbohydrate sequences, the acceptor-substrate specificity of the N-acetylgalactosaminyltransferase was determined. The enzyme generally recognized alpha-NeuAc-(2----3)-beta-D-Gal groups as acceptors, but in a certain conformation. Thus, tri- and tetra-saccharide alditols, native human glycophorin A, and GM3 were not acceptor substrates although they carry the potential disaccharide acceptor unit. When these structures were presented as sialyl-(2----3)-lactose or as a tryptic peptide from glycophorin A, they were shown to be rather good acceptor substrates for the N-acetyl-beta-D-galactosaminyltransferase from human kidney.     

Effects of Ionic and Osmotic Strength on the Glucosyltransferase of Rhizobium meliloti Responsible for Cyclic beta-(1,2)-Glucan Biosynthesis

The cyclic beta-(1,2)-glucans of Rhizobium meliloti and Agrobacterium tumefaciens play an important role during hypoosmotic adaptation, and the synthesis of these compounds is osmoregulated. Glucosyltransferase, the enzyme responsible for cyclic beta-(1,2)-glucan biosynthesis, is present constitutively, suggesting that osmotic regulation of the biosynthesis of these glucans occurs through modulation of enzyme activity. In this study, we examined regulation of cyclic glucan biosynthesis in vitro with membrane preparations from R. meliloti. The results show that ionic solutes inhibit glucan synthesis, even when they are present at low concentrations (e.g., 10 mM). In contrast, neutral solutes (glucose, sucrose, and the compatible solutes glycine betaine and trehalose) were found to stimulate glucan synthesis in vitro when they were present at high concentrations (e.g., 1 M). Furthermore, high concentrations of these neutral solutes were shown to compensate for the inhibition of glucosyltransferase activity by ionic solutes. Consistent with their ionic character, the compatible solute potassium glutamate and the osmoprotectant choline chloride inhibited glucosyltransferase activity in vitro. The results suggest that intracellular ion concentrations, intracellular osmolarity, and intracellular concentrations of nonionic compatible solutes all act as important determinants of glucosyltransferase activity in vivo. Additional experiments were performed with an ndvA mutant defective for transport of cyclic glucans and an ndvB mutant that produces a C-terminal truncated glucosyltransferase. Cyclic beta-(1,2)-glucan biosynthesis, although reduced, was found to be osmoregulated in both mutants. These results reveal that NdvA and the C terminus of NdvB are not required for osmotic regulation of cyclic beta-(1,2)-glucan biosynthesis.     

植物淀粉合成的调控酶

淀粉是植物中最普通的碳水化合物,是人类最主要的食品来源与重要的工业原料。植物淀粉的生物合成主要涉及了4种酶—ADPG焦磷酸化酶、淀粉合成酶、淀粉分支酶和淀粉去分支酶,它们在淀粉的生物合成中发挥着不同作用。近年来,随着基因工程技术的迅速发展及与这些酶有关的众多突变体的发现,使人们对这些酶的结构、特性、功能及表达调控等方面的研究取得了重要进展。并且,人们已开始利用基因工程技术调控植物淀粉的数量与特性,取得了一定成效。在此,文章介绍了调控植物淀粉合成关键酶的生化特性、基因调控及利用基因工程改良植物淀粉等方面所取得进展。     

De novo synthesis of Escherichia coli glycogen is due to primer associated with glycogen synthase and activation by branching enzyme.

Previous reports have demonstrated the incorporation of glucose from ADP-glucose into methanol-insoluble and TCA-insoluble fractions in cell extracts of Escherichia coli in the absence of added primer α-glucan. This activity is reduced 6- to 76-fold in cell extracts of three independently isolated glycogen synthase-deficient mutants of E. coli B. Homogeneous preparations of E. coli B glycogen synthase catalyze incorporation of glucose into both methanol- and TCA-insoluble fractions in the absence of added primer. Since glycogen synthase catalyzes these reactions, it is not necessary to propose a protein acceptor glucose or a unique ADP-glucose-glycosyl transferase to catalyze formation of the glucoprotein in E. coli cell extracts to explain glucose incorporation into TCA-insoluble material (R. Barengo et al. (1975) FEBS Lett.53, 274–278). The incorporation of glucose into methanol-and TCA-insoluble fractions is stimulated by 0.25 m citrate and by branching enzyme. Citrate reduces the K_m for the primer, glycogen, about 11- to 15-fold. Branching enzyme can also reduce the concentration of primer required for incorporation of glucose into methanol-insoluble material. The simultaneous presence of both 0.25 m citrate and branching enzyme enables the glycogen synthase reaction rate to proceed at 30% the maximal velocity at a primer concentration of 1 μg/ml. Incorporation of glucose into methanol- or TCA-insoluble material in the absence of primer is completely inhibited by adding α-amylase. Furthermore, incorporation into methanol- or TCA-insoluble material is reduced 13- to 16-fold relative to the reaction occurring in the presence of primer when glycogen synthase is pretreated with glucoamylase and α-amylase. Previous results show that homogeneous preparations of glycogen synthase contain glucan. Heat-denatured glucogen synthase can act as a primer for the glycogen phosphorylase and glycogen synthase reactions. Both the TCA- and methanol-insoluble products form I₂-glucan complexes with wavelength maxima of about 580–590 nm and 610–615 nm, respectively, suggesting that they are mainly linear chain glucans. The products are completely solubilized with α-amylase. The TCA-insoluble product is not solubilized by pronase treatment. The above results strongly suggest that previous reports on formation of glucoprotein primer for glycogen synthesis or on de novo glycogen synthesis in various similar systems is due to endogenous glucan associated with glycogen synthase rather than formation of glucoprotein which then acts as primer for glycogen synthesis.     

The influence of mutanase and dextranase on the production and structure of glucans synthesized by streptococcal glucosyltransferases

Glucanohydrolases, especially mutanase [alpha-(1-->3) glucanase; EC 3.2.1.59] and dextranase [alpha-(1-->6) glucanase; EC 3.2.1.11], which are present in the biofilm known as dental plaque, may affect the synthesis and structure of glucans formed by glucosyltransferases (GTFs) from sucrose within dental plaque. We examined the production and the structure of glucans synthesized by GTFs B (synthesis of alpha-(1-->3)-linked glucans) or C [synthesis of alpha-(1-->6)- and alpha-(1-->3)-linked glucans] in the presence of mutanase and dextranase, alone or in combination, in solution phase and on saliva-coated hydroxyapatite beads (surface phase). The ability of Streptococcus sobrinus 6715 to adhere to the glucan, which was formed in the presence of the glucanohydrolases was also explored. The presence of mutanase and/or dextranase during the synthesis of glucans by GTF B and C altered the proportions of soluble to insoluble glucan. The presence of either dextranase or mutanase alone had a modest effect on total amount of glucan formed, especially in the surface phase; the glucanohydrolases in combination reduced the total amount of glucan. The amount of (1-->6)-linked glucan was reduced in presence of dextranase. In contrast, mutanase enhanced the formation of soluble glucan, and reduced the percentage of 3-linked glucose of GTF B and C glucans whereas dextranase was mostly without effect. Glucan formed in the presence of dextranase provided fewer binding sites for S. sobrinus; mutanase was devoid of any effect. We also noted that the GTFs bind to dextranase and mutanase. Glucanohydrolases, even in the presence of GTFs, influence glucan synthesis, linkage remodeling, and branching, which may have an impact on the formation, maturation, physical properties, and bacterial binding sites of the polysaccharide matrix in dental plaque. Our data have relevance for the formation of polysaccharide matrix of other biofilms.     

The degree of branching in (alpha 1,4)-(alpha 1,6)-linked glucopolysaccharides is dependent on intrinsic properties of the branching enzymes

1. Branching enzymes from rat and rabbit liver, as well as from potato and maize were prepared. They were almost free from contaminating glucan-degrading enzymes. 2. In 'sweet corn' maize, two separate fractions with (alpha 1,4)glucan: (alpha 1,4)glucan alpha 6-glycosyltransferase activities were obtained. One of them synthesized amylopectin, the branched component of starch, in the presence of phosphorylase and Glc1P, while the other fraction synthesized phytoglycogen. Furthermore, in a maize variety which does not accumulate phytoglycogen, only one fraction of branching activity was found, that formed amylopectin under the above-mentioned conditions. 3. Comparative analyses performed with native (alpha 1,4)-(alpha 1,6)glucopolysaccharides, and those synthesized in vitro with the branching enzyme from the same tissue, demonstrated a close similarity between both glucans. 4. It may be concluded that the branching enzyme is responsible for the specific degree of (alpha 1,6) branch linkages found in the native polysaccharide.     

Structural and immunological studies of a major polysaccharide from spores of Ganoderma lucidum (Fr.) Karst

A polysaccharide isolated from spores of the fungus, Ganoderma lucidum, was found to be a complex glucan. On the basis of compositional and methylation analyses, periodate oxidation, Smith degradation, 1D and 2D NMR, and ESIMS experiments of the native polysaccharide and its degraded products, the polysaccharide was shown to have a backbone of beta-(1-->3)-linked D-glucopyranosyl residues, with branches of mono-, di- and oligosaccharide side chains substituting at the C-6 of the glucosyl residues in the main chain. Conformational analysis in aqueous solution and immunological activities of the native and degraded glucans were also investigated. The results suggested that the degree of substitution on the main chain and the length of side chains may be very important factors in determining the conformation and the biological activities of beta-(1-->3)-linked glucans.     

Characterisation of Mesorhizobium huakuii cyclic beta-glucan

Periplasmic and extracellular glucans of Mesorhizobium huakuii were isolated and characterized by compositional and MALDI-TOF analyses, as well as 1H and 13C NMR spectroscopy. It was shown that M. huakuii produces a cyclic beta-glucan composed entirely of nonbranched glucose chains and unmodified by nonsugar substituents. The degree of polymerisation of the cyclic oligosaccharides was estimated to be in the range from 17 to 28. The most abundant glucan molecules contained 22 glucose residues. Glucose residues within the glucan were connected by beta-(1,2) glycosidic linkages. The cyclic glucan produced by M. huakuii is quite similar to the periplasmic beta-(1,2) glucans synthesized by Agrobacterium and Sinorhizobium genera. The synthesis of beta-glucan in M. huakuii is osmoregulated and this glucan could function as an osmoprotectant in free living cells.     

Bioengineering and Application of Novel Glucose Polymers

Abstract

Glucan phosphorylase, branching enzyme, and 4-α-glucanotransferase were employed to produce glucose polymers with controlled molecular size and structures. Linear or branched glucan was produced from glucose-1-phosphate by glucan phosphorylase alone or together with bracnhing enzyme, where the molecular weight of linear glucan was strictly controlled by the glucose-1-phosphate/primer molar ratio, and the branching pattern by the relative branching enzyme/glucan phosphorylase activity ratio. Cyclic glucans were produced by the cyclization reaction of 5-αglucanotransferases and branching enzyme on amylose and amylopectin. Molecular size and structure of cyclic glucan was controlled by the type of enyzyme and substrate chosen and by the reaction conditions. This in vitro approach can be used to manufacture novel glucose polymers with applicable value.