The action pattern of Penicillium lilacinum dextranase.

The product distributions resulting from the action of Penicillium lilacinum dextranase on end-labelled oligosaccharides of the isomaltose series have been determined. The initial rates of formation of labelled products were measured for isomaltotriose up to isomalto-octaose, and the molar proportions and radioactivity of the final products from isomaltotriose up to isomaltohexaose were determined. D-Glucose was released only from isomaltotriose and isomaltotetraose, by hydrolysis of the first linkage from the reducing end (linkage 1); the terminal bonds of higher members of the series were not attacked. All oligosaccharides except isomaltotriose were hydrolyzed at more than one linkage. The main points of attack on isomaltotetraose up to isomalto-octaose were at linkage 2, and at the third linkage from the non-reducing end; these two positions coincide for isomaltopentaose. The degradation of isomaltotriose up to isomalto-octaose was entirely hydrolytic. The enzyme also catalyzed an extremely slow, concentration-dependent degradation of isomaltose, and this may have occurred via a condensation to isomaltotetraose, followed by hydrolysis of linkage 1 to give D-glucose and isomaltotriose.     

Quantitative Study of the Anomeric Forms of Isomaltose and Glucose Produced by Isomalto-dextranase and Glucodextranase

A gas-liquid chromatographic method was applied to the determination of anomeric forms of isomaltose and glucose produced by Arthrobacter globiformis isomalto-dextranase and glucodex- tranase. The anomeric forms of products released from isomaltotriose, panose and dextran were quantitatively determined. The isomalto-dextranase that was also capable of splitting the α-1,4- glucosidic linkage of panose was found to exclusively produce α-isomaltose from these substrates, and the glucodextranase, ^-glucose.     

Induction of Lipomyces starkeyi Dextranase

Lipomyces starkeyi ATCC 20825 is a derepressed mutant derived from L. starkeyi ATCC 12659. It requires the presence of an inducer before it produces dextranase. This study was undertaken to determine the most efficient, commercially feasible method for inducing this enzyme. The following compounds induced dextranase synthesis: 1-O-β-methyl-glucopyranoside, 1-O-α-methyl-glucopyranoside, dextran, isomaltopentose, isomaltotetraose, isomaltotriose, and isomaltose. 1-O-β-Methyl-glucopyranoside was found to be a gratuitous inducer. Early in the growth phase, cells produced higher specific levels of enzyme than they did in late log phase. The length of exposure of the yeast cells to the inducer also affected the amount of dextranase produced. The maximum amount of enzyme was produced after 12 h of exposure to the inducer. The saturation concentration was the same for all inducers tested, i.e., approximately 1 mg of inducer for every 2 × 10⁸ cells.     

Hyper-production of an isomalto-dextranase of an Arthrobacter sp. by a proteases-deficient Bacillus subtilis: sequencing, properties, and crystallization of the recombinant enzyme

Arthrobacter globiformis T6 is unique in that it produces an enzyme yielding only isomaltose from dextran. In the present study, the organism was re-identified and its classification as a new species of the genus Arthrobacter, A. dextranlyticum, was proposed. The high G+C gene (66.8 mol%) for the isomalto-dextranase was sequenced. The deduced amino acid sequence, with a calculated molecular mass of 65,993 Da (603 amino acids), was confirmed by nanoscale capillary liquid chromatography coupled to tandem mass spectrometry, which covered 71.1% of the amino acid residues of the entire sequence. The enzyme was grouped into glycoside hydrolase family 27, and the C-terminal domain has homology to carbohydrate-binding module family 6. Hyper-exoproduction of the recombinant enzyme was achieved at a level corresponding to approximately 4.6 g l^–1 of culture broth when proteases-deficient Bacillus subtilis cells were used as the host. The purified enzyme (65.5 kDa) had an optimal pH and temperature for activity of 3.5 and 60°C, respectively. It was crystallized using the sitting-drop vapor-diffusion method at 293 K.     

Isolation of a dextranase constitutive mutant of Lipomyces starkeyi and its use for the production of clinical size dextran

A derepressed and partially constitutive mutant for dextranase of Lipomyces starkeyi was selected after ethyl methane sulphonate mutagenesis by zone clearance on blue dextran agar plates. The mutant produced dextranase when grown on glucose, fructose and sucrose as well as on dextran, and more enzyme was produced by the mutant than by the parental strain when grown on 1% dextran. The pH and temperature optima for the mutant dextranase were 5.5 and 55°C, respectively. Dextranase produced on sucrose produced more isomaltose and less glucose after dextran hydrolysis than the equivalent enzyme produced on dextran. The clinical size dextran (average mol. wt of 75000 ± 25000) yield of mixed culture fermentation with the mutant and Leuconostoc mesenteroides was 94% of the total dextran produced.     

Purification and immobilization of dextranase

An enzymic characteristic of Novo dextranase was presented. In addition to a high dextranolytic activity (7,200 U/ml), the crude enzyme also contained small amounts of protease, glucoamylase, polygalacturonase, carboxymethylcellulase, laminarinase and chitinase. A highly purified dextranase was then simply separated from a commercial preparation by column chromatographies on DEAE-Sepharose, CM-Sepharose, and by chromatofocussing on Polybuffer Exchanger PBE-94. The enzyme was recovered with an over 200-fold increase in specific activity and a yield of 84%. The final preparation was homogeneous, as observed during high performance liquid chromatography (HPLC). Size-exclusion HPLC indicated that dextranase had a molecular mass of 35 kDa and its isoelectric point, established by chromatofocussing, was 4.85. Analysis of the dextran break-down products indicated that purified dextranase represents an endolytic mode of action, and isomaltose and isomaltotriose were identified as the main reducing sugars of dextran hydrolysis. The enzyme was then covalently coupled to the silanized porous glass beads modified by glutaraldehyde (Carrier I) or carbodiimide (Carrier II). It was shown that immobilization of dextranase gave optimum pH and temperature ranges from 5.4 to 5.7 and from 50°C to 60°C, respectively. The affinity of the enzyme to the substrate decreased by a factor of more than 13 for dextranase immobilized on Carrier I and increased slightly (about 1.4-times) for the enzyme bound to Carrier II.     

Hydrolysis of fourteen native dextrans by arthrobacter isomaltodextranase and correlation with dextran structure

The isomaltodextranase (EC 3.2.1.94) from Arthrobacter globiformis T6 hydrolysed thirteen dextrans to various extents (11?64% after 13 days) at initially large but gradually decreasing rates. Dextran B-1355 fraction S was, unlike the other dextrans, hydrolysed by the dextranase initially at the lowest rate among the dextrans used, but the rate was maintained for a long period with little decrease, so that the hydrolysis reached as high as 85% after 13 days. Paper chromatography of these dextran digests revealed that this dextranase produces in addition to isomaltose, one or two trisaccharides [isomaltose residues substituted by (1 →2)-, (1→3)-, or (1→4)-α-D-glucopyranosyl groups at the non-reducing D-glucopyranosyl residues] from every dextran used. It is evident that the non-(1→6)-linkages of these trisaccharide products constitute the “anomalous” linkages of the corresponding dextrans. The relative amounts of these trisaccharide products appear to indicate the approxima te relative amounts of a particular linkage among the dextrans, or the relative amounts of two kinds of linkages of each dextran. The kinds and the relative amounts of “anomalous” linkages of some dextrans were established on the basis of the trisaccharides produced by isomaltodextranase.     

Purification and characterization of a dextranase from Sporothrix schenckii

A dextranase (EC 3.2.1.11) was purified and characterized from the IP-29 strain of Sporothrix schenckii, a dimorphic pathogenic fungus. Growing cells secreted the enzyme into a standard culture medium (20 °C) that supports the mycelial phase. Soluble bacterial dextrans substituted for glucose as substrate with a small decrease in cellular yield but a tenfold increase in the production of dextranase. This enzyme is a monomeric protein with a molecular mass of 79 kDa, a pH optimum of 5.0, and an action pattern against a soluble 170-kDa bacterial dextran that leads to a final mixture of glucose (38%), isomaltose (38%), and branched oligosaccharides (24%). In the presence of 200 mM sodium acetate buffer (pH 5.0), the K _m for soluble dextran was 0.067 ± 0.003% (w/v). Salts of Hg²⁺, (UO₂)²⁺, Pb²⁺, Cu²⁺, and Zn²⁺ inhibited by affecting both V _max and K _m. The enzyme was most stable between pH values of 4.50 and 4.75, where the half-life at 55 °C was 18 min and the energy of activation for heat denaturation was 99 kcal/mol. S. schenckii dextranase catalyzed the degradation of cross-linked dextran chains in Sephadex G-50 to G-200, and the latter was a good substrate for cell growth at 20 °C. Highly cross-linked grades (i.e., G-10 and G-25) were refractory to hydrolysis. Most strains of S. schenckii from Europe and North America tested positive for dextranase when grown at 20 °C. All of these isolates grew on glucose at 35 °C, a condition that is typically associated with the yeast phase, but they did not express dextranase and were incapable of using dextran as a carbon source at the higher temperature. Received: 29 December 1997 / Accepted: 4 March 1998     

Characterization of dextranase from Penicillium purpurogenum (Ftoll)]

An extracellular dextranase (E. C. 3.2.1.11) was purified from cell-free culture filtrates of Penicillium purpurogenum (Ftoll). The enzyme was most active at pH 5,5. The dextranase was endo-type, it split quickly isomaltotetraose into two isomaltose molecules, slowly degraded isomaltotriose, and did not act on isomaltose. The rate of isomaltooligosaccharides hydrolysis was increased with the increase of the polymerization degree. Polyols obtained from isomaltooligosaccharides were split more slowly than the respective sugars. The isomaltopentaitol was split at two glucosidic linkages, 38% of hydrolyzed linkages being the second linkage from the sorbitol end of the molecule and 62% being the third one. The degree of degradation of dextrans depended on amount of 1,6 linkages. Isomaltose and tetrasaccharides of two types, 2(2)-alpha-D-glucosylmaltotriose and linear tetrasaccharide(s), are the lowest molecular weight products of exhaustive hydrolysis of branched dextrans.     

Characterization of an Extracellular Dextranase from Fusarium moniliforme

An extracellular dextranase (EC 3.2.1.11) was purified approximately 75-fold from cell-free culture filtrates of Fusarium moniliforme. The purified dextranase was of the endo type, and isomaltose was identified as the primary end product of dextran hydrolysis. The molecular weight of the dextranase was determined to be 39,000 by gel permeation chromatography. The enzyme was most active at pH 5.5, and the temperature optimum was near 55 C. Activity was not inhibited by either ethylenediaminetetraacetic acid or iodoacetate. The Km for dextran with an average molecular weight of 10,000 was estimated to be 1.1 X 10(-4) M. The electrophoretic mobility of the dextranase was distinctly different from that of a Penicillium-derived commercial dextranase. The F. moniliforme dextranase was also found to differ from the commercial preparation by its greater relative activity against glucans isolated from Streptococcus mutans.     

Production and characterization of a dextranase from an isolated Paecilomyces lilacinus strain

Summary Several environments were sampled in a screening procedure to obtain 23 different dextranase-producing fungal strains. The most productive strains were identified as Penicillium purpurogenum and Paecilomyces lilacinus. The culture medium for P. lilacinus strain 6R was optimized, increasing the initial productivity twofold. The enzyme showed optimal activities at pH 5.4 and 65° C, as well as excellent thermal stability at 60° C. An average K _m value of 0.26 g/l was found for dextran over a wide range of substrate molecular mass. The enzyme did not show substrate or product inhibition. From HPLC chromatograms, the 6R dextranase was found to readily reduce dextran to low molecular mass oligosaccharides and isomaltose. An integrated kinetic equation is used to describe batch reactions and application dose. Offprint requests to: A. Lopez-Munguia     

Some Catalytic Properties of an Exo-l,6-α-glucosidase (Glucodextranase) from Arthrobacter globiformis I42

An exo-l,6-α-glucosidase (EC 3.2.1.70) (glucodextranase) produced extraceUularly by Arthrobacter globiformis I42 was found to invert the configuration of glucose released from dextran, and to require calcium for protection against warming. Among isomaltodextrins used as substrates for this enzyme, the rate of hydrolysis for isomaltose was the lowest and increased with the degree of polymerization (d. p.) of the saccharides up to d. p. 7. The minor activities accompanying purified glucodextranase preparations (release of glucose from starch, splitting of maltose, nigerose and kojibiose) were ascribed to the glucodextranase itself. Fourteen native dextrans and soluble potato starch were subjected to digestion by this glucodextranase and the rate, process and extent of hydrolysis of these substrates were studied relative to the composition of non-l,6-α-linkages of these polysaccharides.     

Characterization of novel thermostable dextranase from Thermotoga lettingae TMO

Biochemical properties of a putative thermostable dextranase gene from Thermotoga lettingae TMO were determined in a recombinant protein (TLDex) expressed in Escherichia coli and purified to sevenfold apparent homogeneity. The 64-kDa protein displayed maximum activity at pH 4.3, and enzyme activity was stable from pH 4.3–10. The optimal temperature was 55–60°C during 15 min incubation, and the half-life of the enzyme was 1.5 h at 65°C. The enzyme showed higher activity against α-(1 → 6) glucan and released isomaltose and isomaltotriose as main products from dextran T2000. An unusual kinetic feature of TLDex was the negative cooperative behavior on the reaction of dextran T2000 cleavage. Enzyme activity was not significantly affected by the presence of metal ions, except for the strong inhibited by 1 mM Fe²⁺ and Ag²⁺. TLDex may prove useful as an enzyme for high temperature sugar milling processes.     

A glycoside hydrolase family 31 dextranase with high transglucosylation activity from Flavobacterium johnsoniae

Glycoside hydrolase family (GH) 31 enzymes exhibit various substrate specificities, although the majority of members are α-glucosidases. Here, we constructed a heterologous expression system of a GH31 enzyme, Fjoh_4430, from Flavobacterium johnsoniae NBRC 14942, using Escherichia coli, and characterized its enzymatic properties. The enzyme hydrolyzed dextran and pullulan to produce isomaltooligosaccharides and isopanose, respectively. When isomaltose was used as a substrate, the enzyme catalyzed disproportionation to form isomaltooligosaccharides. The enzyme also acted, albeit inefficiently, on p-nitrophenyl α-D-glucopyranoside, and p-nitrophenyl α-isomaltoside was the main product of the reaction. In contrast, Fjoh_4430 did not act on trehalose, kojibiose, nigerose, maltose, maltotriose, or soluble starch. The optimal pH and temperature were pH 6.0 and 60 °C, respectively. Our results indicate that Fjoh_4430 is a novel GH31 dextranase with high transglucosylation activity.     

淡紫拟青霉右旋糖酐酶的形成条件

比较了各种碳水化合物对淡紫拟青霉(Paecilomyces lilacinus)右旋糖酐酶形成的影响,右旋糖酐是最好的碳源,也是最佳诱导物。不同分子量(17．2—1000kD)的右旋糖酐对酶形成的诱导作用不同,酶的产生随右旋糖酐分子量的增大而增加。用分子量为1000kD的右旋糖酐作碳源时比用17.2kD的右旋糖酐作碳源时的产酶量高40％以上。用右旋糖酐和其它糖的混合物作碳源时,酶的形成受到不同程度的抑制。右旋糖酐酶形成的其它适宜条件：氮源为牛肉蛋白胨,培养基初始pH6．0—7.0.种龄为48小时,在250ml三角瓶中装50ml培养基,于28℃在200r／min摇床上培养6天。     

Engineered dextranase from Streptococcus mutans enhances the production of longer isomaltooligosaccharides

Herein, we investigated enzymatic properties and reaction specificities of Streptococcus mutans dextranase, which hydrolyzes α-(1→6)-glucosidic linkages in dextran to produce isomaltooligosaccharides. Reaction specificities of wild-type dextranase and its mutant derivatives were examined using dextran and a series of enzymatically prepared p-nitrophenyl α-isomaltooligosaccharides. In experiments with 4-mg·mL^?1 dextran, isomaltooligosaccharides with degrees of polymerization (DP) of 3 and 4 were present at the beginning of the reaction, and glucose and isomaltose were produced by the end of the reaction. Increased concentrations of the substrate dextran (40 mg·mL^?1) yielded isomaltooligosaccharides with higher DP, and the mutations T558H, W279A/T563N, and W279F/T563N at the ?3 and ?4 subsites affected hydrolytic activities of the enzyme, likely reflecting decreases in substrate affinity at the ?4 subsite. In particular, T558H increased the proportion of isomaltooligosaccharide with DP of 5 in hydrolysates following reactions with 4-mg·mL^?1 dextran.Abbreviations CI: cycloisomaltooligosaccharide; CITase: CI glucanotransferase; CITase-Bc: CITase from Bacillus circulans T-3040; DP: degree of polymerization of glucose unit; GH: glycoside hydrolase family; GTF: glucansucrase; HPAEC-PAD: high performance anion-exchange chromatography-pulsed amperometric detection; IG: isomaltooligosaccharide; IGn: IG with DP of n (n, 2?5); PNP: p-nitrophenol; PNP-Glc: p-nitrophenyl α-glucoside; PNP-IG: p-nitrophenyl isomaltooligosaccharide; PNP-IGn: PNP-IG with DP of n (n, 2?6); SmDex: dextranase from Streptococcus mutans; SmDexTM: S. mutans ATCC25175 SmDex bearing Gln100?Ile732     

Studies on dextranase from Penicillium aculeatum

A strain of Penicillium aculeatum has been found to synthesize large quantities of dextranase (1,6-α-d-glucan 6-glucanohydrolase, EC 3.2.1.11) in culture filtrate. Some of the conditions governing the enzyme production have been standardized. The enzyme in crude state was found to be highly stable, its activity being maximum at 50 to 60°C and at pH 5 to 6. About 90% of the substrate dextran was converted to isomaltose in a 4 h period at 40°C. The enzyme when purified by salt and solvent fractionation gave 1500 units per mg protein and retained its activity over a long period when stored at 4°C.     

Production and Properties of Alkaline Dextranase from a Newly Isolated Brevibacterium

About 500 strains of dextranase producing microorganisms were examined in detail for pH- activity and enzyme stability. A gram positive bacterium identified as belonging to the genus Brevibacterium was found to produce alkaline dextranase. Maximal dextranase synthesis was obtained when grown aerobically at 26°C for 3 days in a medium containing 1 % dextran, 2% ethanol, 1 % polypeptone and 0.05 % yeast extract together with trace amounts of inorganic salts.

Brevibacterium dextranase had an optimum pH of 8.0 for activity at 37°C and an optimal temperature at 53°C at pH 7.5. The enzyme was quite stable over the range of pH 5.0 to 10.5 on 24 hr incubation at 37°C, especially on alkaline pH. The enzyme was also heat stable at 60°C for 10 min.     

Purification and substrate specificity of an endo-dextranase of Streptococcus mutans K1-R

An extracellular endo-dextranase has been isolated from Streptococcus mutans K1-R. Incubation of cell-free culture fluid with sucrose permitted the removal of a large proportion of the extracellular d-glucosyltransferases by irreversible adsorption onto the insoluble glucans that these enzymes synthesize from sucrose. The remaining d-glucosyltransferases were separated from dextranase by precipitation with ammonium sulphate, chromatography on hydroxylapatite and DEAE-cellulose, followed by filtration on Ultrogel. The major products of action of the purified dextranase on (1→6)-α-d-glucans were isomaltotriose (IM₃), isomaltotetraose (IM₄), and isomaltopentaose (IM₅). Further hydrolysis of IM₄ and IM₅ occurred after prolonged incubation with excess of enzyme, to give d-glucose, IM₂, and IM₃. The relative rate of hydrolysis of isomaltose saccharides fell sharply with decreasing chainlength from IM₁₂ to IM₅. The hydrolysis of dextrans containing 96% or more of (1→6)-α-d-glucosidic linkages, expressed as apparent conversion into IM₃, was virtually complete, and substrates such as Streptococcus sanguis glucan, containing sequences of (1→6)-α-d-glucosidic linkages, were also effectively hydrolyzed. Dextranase activity towards the soluble glucan of Streptococcus mutans was limited, and there was no action on the insoluble glucan synthesized by S. mutans sucrose 3-d-glucosyltransferase.     

Production,characterization and (co-)immobilization of dextranase from <Emphasis Type="Italic">Penicillium aculeatum</Emphasis>

Fermentation kinetics of Penicillium aculeatum ATCC 10409 demonstrated that fungal growth and dextranase release are decoupled. Inoculation by conidia or mycelia resulted in identical kinetics. Two new isoenzymes of the dextranase were characterized regarding their kinetic constants, pI, MW, activation energy and stabilities. The larger enzyme was 3-fold more active (turnover number: 2,230 ± 97 s⁻¹). Pre-treatment of bentonite with H₂O₂ did not affect adsorption characteristics of dextranase. Enzyme to bentonite ratios above 0.5:1 (w/w) resulted in a high conservation of activity upon adsorption. Furthermore, dextranase could be used in co-immobilizates for the direct conversion of sucrose into isomalto-oligosaccharides (e.g. isomaltose). Yields of co-immobilizates were 2–20 times that of basic immobilizates, which consist of dextransucrase without dextranase.