Glucan and glucosyltransferase isozymes of Glaucocystis nostochinearum

The storage glucan of the alga, Glaucocystis nostochinearum was isolated in dimethyl sulfoxide. The absorption spectrum of its iodine complex was identical with those of other green algae but differed from that of blue-green algae. It was similar to amylopectin, and was much less branched than the phytoglycogen of Cyanophytes. The pattern of glycosyltransferase isozymes involved in the synthesis of this glucan (phosphorylases, synthetases and branching isozymes) was similar to those of Chlorophytes. The branching isozymes of this alga were typical Chlorophycean “Q” enzymes and could only insert branch linkages into linear amylose-like substrates; they were unable to further branch amylopectins, as can the branching isozymes of blue-green algae. If the plastids of this alga are endosymbiotic blue-green algae, then they have lost the ability to form highly branched glucans typical of Cyanophytes.     

The b.e. and Q types of 1,4-α-d-glucan: 1,4-α-d-glucan-6-glucosyltransferase isozymes in algae

The branching isozymes of the red alga, Rhodymenia pertusa are of two types: Q, which can branch, via the synthesis of α-1,6-glucosyl linkages, linear amyloses to amylopectin; and b.e., which can further branch the amylopectin formed to the more highly-branched floridean starch. Using the technique of tandem crossed-immunoelectrophoresis, it is shown that the Q branching isozyme of the red alga is more closely related to the b.e. type of branching isozymes of Anacystis nidulans and Cyanidium caldarium than it is to the exclusively Q types of branching isozymes found in Chlorella pyrenoidosa and other chlorophytes. The possibility of a biphyletic evolution of the red and the green algae from blue-green ancestral forms is discussed.     

Action of neopullulanase. Neopullulanase catalyzes both hydrolysis and transglycosylation at alpha-(1----4)- and alpha-(1----6)-glucosidic linkages.

The transglycosylation reaction catalyzed by neopullulanase was analyzed. Radioactive oligosaccharides were produced when the enzyme acted on maltotriose in the presence of [U-14C]glucose. Some of the radioactive oligosaccharides had only alpha-(1----4)-glucosidic linkages, but others were suggested to have alpha-(1----6)-glucosidic linkages. The existence of alpha-(1----6)-glucosidic linkages in the products from maltotriose with neopullulanase was proven by proton NMR spectroscopy and methylation analysis. We previously reported that the one active center of neopullulanase catalyzes the hydrolysis of alpha-(1----4)- and alpha-(1----6)-glucosidic linkages (Kuriki, T., Takata, H., Okada, S., and Imanaka, T. (1991) J. Bacteriol. 173,6147-6152). These facts proved that neopullulanase catalyzed all four types of reactions: hydrolysis of alpha-(1----4)-glucosidic linkage, hydrolysis of alpha-(1----6)-glucosidic linkage, transglycosylation to form alpha-(1----4)-glucosidic linkage, and transglycosylation to form alpha-(1----6)-glucosidic linkage. The four reactions are typically catalyzed by alpha-amylase, pullulanase, cyclomaltodextrin glucanotransferase, and 1,4-alpha-D-glucan branching enzyme, respectively. These four enzymes have some structural similarities to one other, but reactions catalyzed by the enzymes are considered to be distinctive: the four reactions are individually catalyzed by each of the enzymes. The experimental results obtained from the analysis of the reaction of the neopullulanase exhibited that the four reactions can be catalyzed in the same mechanism.     

A new GH13 subfamily represented by the α-amylase from the halophilic archaeon Haloarcula hispanica

Extremophiles - α-Amylase catalyzes the endohydrolysis of α-1,4-glucosidic linkages in starch and related α-glucans. In the CAZy database, most α-amylases have been classified...     

Starch synthetases from Vitis vinifera and zea mays

ADPglucose: α-1,4-glucan α-4-glucosyltransferases (starch synthetases) from leaves of Vitis vinifera and leaves and kernels of Zea mays were chromatographed on DEAE-cellulose columns. One form of the enzyme was present in grape leaves having activity both in the presence and absence of primer. Two forms were present in both leaves and kernels of maize. The second peak of activity in maize leaves and the first peak in maize kernels synthesized a polyglucan in the absence of primer. A peak of branching enzyme (Q-enzyme) occurred between the two starch synthetase peaks with both tissues. When fractions containing starch synthetase and branching enzyme were added to the first leaf starch synthetase peak, up to 100-fold activation of the unprimed reaction occurred. Branching enzyme did not stimulate the unprimed activity of the first kernel peak and no branching enzyme could be detected in this peak. The unprimed product was a branched polyglucan with mainly α-1,4-links.     

Identification of Catalytic and Substrate-binding Site Residues in Bacillus cereus ATCC7064 Oligo-1,6-glucosidase

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis α-glucosidase, Aspergillus oryzae α-amylase and pig pancreatic α-amylase which act on α-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae α-amylase and pig pancreatic α-amylase. A single mutation of Asp199→Asn, Glu255→Gln, or Asp329→Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of α-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of α-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (α-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328→Asn caused the essential loss in activity, while the mutation His103→Asn yielded a mutant enzyme that retained 59% of the κ₀/K_m of that for the wild-type enzyme. Since mutants of other α-amylases acting on α-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by Hisl03→Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of α-1,6-glucosidic bond linkage.     

Purification and characterization of Acremonium implicatum alpha-glucosidase having regioselectivity for alpha-1,3-glucosidic linkage

alpha-Glucosidase with a high regioselectivity for alpha-1,3-glucosidic linkages for hydrolysis and transglucosylation was purified from culture broth of Acremonium implicatum. The enzyme was a tetrameric protein (M.W. 440,000), of which the monomer (M.W. 103,000; monomeric structure was expected from cDNA sequence) was composed of two polypeptides (M.W. 51,000 and 60,000) formed possibly by posttranslational proteolysis. Nigerose and maltose were hydrolyzed by the enzyme rapidly, but slowly for kojibiose. The k(0)/K(m) value for nigerose was 2.5-fold higher than that of maltose. Isomaltose was cleaved slightly, and sucrose was not. Maltotriose, maltotetraose, p-nitrophenyl alpha-maltoside and soluble starch were good substrates. The enzyme showed high affinity for maltooligosaccharides and p-nitrophenyl alpha-maltoside. The enzyme had the alpha-1,3- and alpha-1,4-glucosyl transfer activities to synthesize oligosaccharides, but no ability to form alpha-1,2- and alpha-1,6-glucosidic linkages. Ability for the formation of alpha-1,3-glucosidic linkage was two to three times higher than that for alpha-1,4-glucosidic linkage. Eight kinds of transglucosylation products were synthesized from maltose, in which 3(2)-O-alpha-nigerosyl-maltose and 3(2)-O-alpha-maltosyl-maltose were novel saccharides.     

Purification and properties of mycodextranase from Bacillus circulans NHB-1

A Gram-positive bacterium, Bacillus circulans, isolated from soil was found to produce an enzyme hydrolyzing nigeran (mycodextran, alternating α-1,3- and α-1,4-linked glucan). The molecular weight of the purified enzyme was 120,000 and its isoelectric point was 8.30. The optimum pH and temperature for the enzyme activity were 6.0 and 50°C, respectively. The enzyme was stable in the pH range from 6.0 to 7.0 and up to 50°C. The K_m (mg/ml) for nigeran was 1.37. The enzyme specifically hydrolyzed the nigeran into nigerose and nigeran tetrasaccharide by an endo-type action, indicating that it is a mycodextranase (EC 3.2.1.61) cleaving only the α-1,4-glucosidic linkages in nigeran. The N-terminal amino acid sequence of the purified enzyme of B. circulans (APTVYEAESAAKTGGV) was different from that of the mycodexstranase purified from Streptomyces sp. J-13-3 (XDPGDPTDPDPSGVGATLPF).     

Cyclization reaction catalyzed by branching enzyme.

The action of branching enzyme (EC 2.4.l.l8) from Bacillus stearothermophilus on amylose was analyzed. The enzyme reduced the molecular size of amylose without increasing the reducing power. This result could not be explained by the normal branching reaction model. When the product was treated with glucoamylase (an exo++-type amylase), a resistant component remained. The glucoamylase-resistant component was easily digested by an endo-type alpha-amylase or by isoamylase plus glucoamylase. These results suggested that the glucoamylase-resistant component was a cyclic glucan composed of alpha-1,4- and alpha-l,6-glucosidic linkages. In other words, it was suggested that branching enzyme catalyzed cyclization of the alpha-l,4-glucan chain of the amylose molecule to form an alpha-l,6-glucosidic linkage, thereby forming two smaller molecules. Mass spectrometry also supported the cyclic nature of the product.     

Monitoring the hydrolysis and transglycosylation activity of α-glucosidase from Aspergillus niger by nuclear magnetic resonance spectroscopy and mass spectrometry

α-Glucosidase from Aspergillus niger is an enzyme that catalyzes hydrolysis of α-1,4 linkages and transglucosylation to form α-1,6 linkages. In this study, an analytical method of oligosaccharides by nuclear magnetic resonance (NMR) was used to provide quantitative estimation of the fractions of each sugar unit and was applied to characterize the α-glucosidase reaction. Our data indicated that α-glucosidase reacts with the nonreducing end of oligosaccharides to form an α-1,6 linkage, and then a sugar unit with two α-1,6 linkages is gradually produced. Data from mass spectrometry suggested that the sugar unit with two α-1,6 linkages originates mainly from a 3mer and/or 4mer when oligosaccharides are used as substrates.     

Pullulan 4-glucanohydrolase from Aspergillus niger

Pullulan 4-glucanohydrolase, a novel pullulan-hydrolyzing enzyme from Aspergillus niger, was highly purified by means of acetone precipitation, chromatography on P-cellulose and DEAE-cellulose, and gel filtration on Sephadex G-150. More than 430-fold purification was achieved through these procedures from crude extract of wheat bran culture. The enzyme can liberate a large amount of isopanose and a small amount of tetrasaccharide from pullulan. The optimum pH of the enzyme action on pullulan was 3.0–3.5 and the optimum temperature was 40 °C at pH 3.5. The enzyme activity remained intact after heating at 50 °C for 30 min at pH 3.7–4.5. The enzyme was stable at pH 2.0–8.0 on storage at 5 °C for 24 hr. The purified enzyme attacked reducing end α-1,4-glucosidic linkages adjacent to α-1,6-glucosidic linkages in pullulan, 6³-α-glucosylmaltotriose, 6²-α-maltosylmaltose and panose, to liberate isopanose, isomaltose and maltose, isopanose and glucose, and isomaltose and glucose, respectively. The molecular weight of the enzyme determined by gel filtration on Bio-Gel P-150 was about 74,000.     

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.     

Glucosyltransferase isozymes forming storage glucan in prochloron, a prokaryotic green alga

Since the prokaryotic, green marine alga Prochloron has not, as yet, been cultured, lyophilized cells were used in a microadaptation of polyacrylamide gel electrophoresis (PAGE) in order to isolate the glucosyltransferase isozymes. The pattern obtained with these capillary gels was identical with those of cyanophytes. Besides two phosphorylase and synthase isozymes, three branching isozymes of the b.e. type were found to be present.     

Purification and characterization of highly branched α-glucan-producing enzymes from Paenibacillus sp. PP710

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.     

Some properties of starch branching enzyme from indica rice endosperm (Oryza sativa L.)

Starch branching enzyme (α-1,4-glucan: α-1,4-glucan-6-glycosyl transferase; EC 2.4.1.18) catalyzes the formation of the α-1,6-bond in branched starch molecules such as amylopectin. Some characteristics of starch branching enzyme in rice endosperm (Oryza sativa L.) were determined because of the importance of starch structure for rice quality. Two or three peaks of starch branching enzyme activity were resolved by anion-exchange chromatography of extracts from high amylose rice. The properties of rice starch branching enzyme were similar to those found for the enzyme from other plant sources except for a much lower molecular weight. Rice branching enzyme had an apparent molecular weight of 40 000 as estimated by gel permeation chromatography. Multiple forms of starch branching enzyme could also be resolved in milled rice, suggesting that relationships between starch quality and characteristics of starch branching enzyme could be examined in the mature grain after harvest.     

Effect of environment pH on storage glucan synthesis in three thermophilic algae

Plectonema nostocorum, a thermophilic cyanophyte which lives under alkaline conditions at pHs approaching 13, forms a storage glucan showing a maximum absorption of its iodine complex almost identical with that of another thermophilic cyanophyte, Oscillatoria princeps, which exists at a more neutral pH, and with that of the acidophilic thermophile, Cyanidium caldarium. Gel electrophoretic patterns of the storage glucan-forming isozymes of Plectonema do not differ essentially from those of Oscillatoria. The a₂ phosphorylase isozyme appears to be primer-independent, and resembles the a₂ isozymes of both Oscillatoria and Cyanidium. The isozymes responsible for forming α-1,6-glucosidic branched linkages in Plectonema are of the b.e. type (able to further branch amylopectin), rather than of the Q type (able to branch amylose only to amylopectin).     

Genetic and Biochemical Evidence for the Involvement of α-1,4 Glucanotransferases in Amylopectin Synthesis

We describe a novel mutation in the Chlamydomonas reinhardtii STA11 gene, which results in significantly reduced granular starch deposition and major modifications in amylopectin structure and granule shape. This defect simultaneously leads to the accumulation of linear malto-oligosaccharides. The sta11-1 mutation causes the absence of an α-1,4 glucanotransferase known as disproportionating enzyme (D-enzyme). D-enzyme activity was found to be correlated with the amount of wild-type allele doses in gene dosage experiments. All other enzymes involved in starch biosynthesis, including ADP-glucose pyrophosphorylase, debranching enzymes, soluble and granule-bound starch synthases, branching enzymes, phosphorylases, α-glucosidases (maltases), and amylases, were unaffected by the mutation. These data indicate that the D-enzyme is required for normal starch granule biogenesis in the monocellular alga C. reinhardtii.     

Starch- and glycogen-debranching and branching enzymes: Prediction of structural features of the catalytic (β/α)8-barrel domain and evolutionary relationship to other amylolytic enzymes

Sequence alignment and structure prediction are used to locate catalytic α-amylase-type (β/α)₈-barrel domains and the positions of their β-strands and α-helices in isoamylase, pullulanase, neopullulanase, α-amylase-pullulanase, dextran glucosidase, branching enzyme, and glycogen branching enzymes—all enzymes involved in hydrolysis or synthesis of α-1,6-glucosidic linkages in starch and related polysaccharides. This has allowed identification of the transferase active site of the glycogen debranching enzyme and the locations of β ? α loops making up the active sites of all enzymes studied. Activity and specificity of the enzymes are discussed in terms of conserved amino acid residues and loop variations. An evolutionary distance tree of 47 amylolytic and related enzymes is built on 37 residues representing the four best conserved β-strands of the barrel. It exhibits clusters of enzymes close in specificity, with the branching and glycogen debranching enzymes being the most distantly related.     

Enzymatic transglycosylation of ginsenoside Rg1 by rice seed α-glucosidase

Six α-monoglucosyl derivatives of ginsenoside Rg1 (G-Rg1) were synthesized by transglycosylation reaction of rice seed α-glucosidase in the reaction mixture containing maltose as a glucosyl donor and G-Rg1 as an acceptor. Their chemical structures were identified by spectroscopic analysis, and the effects of reaction time, pH, and glycosyl donors on transglycosylation reaction were investigated. The results showed that rice seed α-glucosidase transfers α-glucosyl group from maltose to G-Rg1 by forming either α-1,3 (α-nigerosyl)-, α-1,4 (α-maltosyl)-, or α-1,6 (α-isomaltosyl)-glucosidic linkages in β-glucose moieties linked at the C6- and C20-position of protopanaxatriol (PPT)-type aglycone. The optimum pH range for the transglycosylation reaction was between 5.0 and 6.0. Rice seed α-glucosidase acted on maltose, soluble starch, and PNP α-D-glucopyranoside as glycosyl donors, but not on glucose, sucrose, or trehalose. These α-monoglucosyl derivatives of G-Rg1 were easily hydrolyzed to G-Rg1 by rat small intestinal and liver α-glucosidase in vitro.