Stabilization of dextranase from Penicillium funiculosum and Fusarium solani during heating and freeze-drying

Freeze-drying of highly purified dextranse from Penicillium funiculosum and Fusarium solani was accompanied by 90% losses of enzyme activity and solubility. Many carbohydrates were tested as stabilizers, e.g. glucose, maltose, lactose, polyglucine, dextranase hydrolyzate of polyglucine as well as mannitol and ammonium sulfate. Polyglucine, its hydrolyzate, and glucose proved most effective stabilizers. The stabilizing effect of polyglucine hydrolyzate of dextranase during its heating and freeze-drying was compared. The effective concentration of the stabilizer during freeze-drying was 10 times lower than during heating.     

Hydrolysis of streptococcal polysaccharides by micromycete dextranases

The effect of dextranase enzyme preparations obtained from Penicillium piscarium BIM G-102, Penicillium funiculosum, Aspergillus insuetus G-116 and Aspergillus ustus on polysaccharides synthesized by cariesogenic Streptococcus sanguis and Streptococcus mitis was being studied. According to the data obtained dextranases from P. piscarium, P. funiculosum and Asp. ustus can be considered as a promising anticarious agent.     

Preparation and some properties of immobilized Penicillium funiculosum 258 dextranase

The production of dextranase was investigated in static cultures of Penicillium funiculosum 258. Maximal enzyme productivity was attained at pH 8.0, with 3.5% (w/v) dextran (MW, 260 000) as carbon source, NaNO₃ (1%, w/v) and yeast extract (0.2%, w/v) as nitrogen source, 0.4% (w/v) K₂HPO₄ and 0.06% (w/v) MgSO₄. It was possible to increase the productivity of dextranase to 41.8 units ml⁻¹ in the modified medium. The enzyme was immobilized on different carriers by different techniques of immobilization. The enzyme prepared by covalent binding on chitosan using glutaraldehyde had the highest activity, the immobilized enzyme retaining 63% of its original specific activity. Compared with the free dextranase, the immobilized enzyme exhibited: a higher pH optimum, a higher optimal reaction temperature and energy of activation, a higher Michaelis constant, improved thermal stability and higher values of deactivation rate constant. The immobilized enzyme retained about 80% of the initial catalytic activity even after being used for 12 cycles.     

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.     

Quartz sand as an adsorbent for purification of extracellular glucose oxidase from Penicillium funiculosum 46.1

The procedure of purification of extracellular glucose oxidase (GO, EC 1.1.3.4) from culture-liquid filtrate (CLF) of the fungus Penicillum funiculosum 46.1 using alluvial quartz sand as an adsorbent has been developed. The modification of sand by changing the charge and polarity did not lead to a significant increase in its adsorption capacity towards GO. The effectiveness of sand and aluminum oxide, used as sorbents for isolation of GO from CLF, was compared. Glucose oxidase, isolated from CLF by adsorption on sand, exhibited a greater catalytic activity compared to the enzyme specimens obtained by column chromatography on CLF. Sand adsorbed GO from P. funiculosum 46.1 more effectively than aluminum oxide. It is concluded that sand may be used for fractionation of partly purified GO.     

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。     

Crystallization and characterization of monoacylglycerol and diacylglycerol lipase from Penicillium camembertii.

A new lipase from Penicillium camembertii U-150, which is specific for monoacylglycerols and diacylglycerols, but not triacylglycerols, was purified as four active components using concanavalin-A-Sepharose column chromatography, crystallized in the form of needles, and its properties investigated. No significant difference was observed in substrate specificity, but molecular mass and other enzymatic properties, such as pH, heat stability and optimum pH and temperature, were clearly different between the unadsorbed and the three adsorbed components on concanavalin-A-Sepharose; the three adsorbed components were similar to each other and more stable than the unadsorbed component. On the other hand, after enzymatic removal of carbohydrates from the three adsorbed components, their enzymatic properties became similar to those of the unadsorbed component. The carbohydrates of this lipase contribute to the stability of the enzyme, but not to its enzyme activity. The amino acid compositions of the four components did not differ from each other, and tryptic mapping of the deglycosylated components and amino acid composition of the tryptic fragments were identical. The carbohydrate compositions of four intact components were, however, different from each other. All four components have the same polypeptide backbone and multiple forms of this lipase are due to the differences in composition of the carbohydrates bound in this lipase.     

Isolation of a Pure Dextranase from Penicillium funiculosum

A dextranase, produced by Penicillium funiculosum, was purified 1,000-fold to yield the enzyme which was demonstrated by gel electrophoresis and electrofocusing to be a homogeneous protein. The purification method included acetone partition, ammonium sulfate fractionation, gel filtration, iron defecation and precipitation, and diethylaminoethyl-cellulose chromatography. The pure enzyme was also obtained by preparative gel electrophoresis. Gel-permeation chromatography indicates a molecular weight of 41,000. An isoelectric pH of 4.6 was established by electrofocusing. A 1-mg amount of the enzyme hydrolyzes a dextran substrate to yield 27,000 isomaltose reducing units in 2 hr.     

Molecular cloning and nucleotide sequencing of the Arthrobacter dextranase gene and its expression in Escherichia coli and Streptococcus sanguis

A bacterial strain, which assimilated dextran and water-insoluble glucan produced by Streptococcus mutans, was isolated from soil. The bacterium produced and secreted potent dextranase activity, which was identified as Arthrobacter sp. and named CB-8. The dextranase was purified and some enzymatic properties were characterized. The enzyme efficiently decomposed the water-insoluble glucan as well as dextran. A gene library from the bacteria was constructed with Escherichia coli, using plasmid pUC19, and clones producing dextranase activity were selected. Based on the result of nucleotide sequencing analysis, it was deduced that the dextranase was synthesized in CB-8 cells as a polypeptide precursor consisting of 640 amino acid residues, including 49 N-terminal amino acid residues which could be regarded as a signal peptide. In the E. coli transformant, the dextranase activity was detected mostly in the periplasmic space. The gene for the dextranase was introduced into Streptococcus sanguis, using an E. coli-S. sanguis shuttle vector that contained the promoter sequence of a gene for glucosyltransferase derived from a strain of S. mutans. The active dextranase was also expressed and accumulated in S. sanguis cells.     

Properties and applications of Penicillium funiculosum cellulase immobilized on a soluble polymer

Summary The cellobiase and xylanase activities of Penicillium funiculosum were immobilized on a soluble polymer poly(vinyl alcohol) (PVA). The kinetic parameters and the adsorption characteristics of the bound and free enzymes were compared. The Km value of the immobilized preparation was the same as the free enzyme. The hydrolysis of different cellulosic substrates by the bound enzyme is investigated.     

Adsorption and hydrolysis reactions of poly(hydroxybutyric acid) depolymerases secreted from Ralstonia pickettii T1 and Penicillium funiculosum onto poly[(R)-3-hydroxybutyric acid

Reaction processes of poly[(R)-3-hydroxybutyric acid] (P(3HB)) with two types of poly(hydroxybutyric acid) (PHB) depolymerases secreted from Ralstonia pickettii T1 and Penicillium funiculosum were characterized by means of atomic force microscopy (AFM) and quartz crystal microbalance (QCM). The PHB depolymerase from R. pickettii T1 consists of catalytic, linker, and substrate-binding domains, whereas the one from P. funiculosum lacks a substrate-binding domain. We succeeded in observing the adsorption of single molecules of the PHB depolymerase from R. pickettii T1 onto P(3HB) single crystals and the degradation of the single crystals in a phosphate buffer solution at 37 degrees C by real-time AFM. On the contrary, the enzyme molecule from P. funiculosum was hardly observed at the surface of P(3HB) single crystals by real-time AFM, even though the enzymatic degradation of the single crystals was surely progressed. On the basis of the AFM observations in air of the P(3HB) single crystals after the enzymatic treatments, however, not only the PHB depolymerase from R. pickettii T1 but also that from P. funiculosum adsorbed onto the surface of P(3HB) crystals, and both concentrations of the enzymes on the surface were nearly identical. This means both enzymes were adsorbed onto the surface of P(3HB) single crystals. Moreover, QCM measurements clarified quantitatively the differences in detachment behavior between two types of PHB depolymerases, namely the enzyme from R. pickettii T1 was hardly detached but the enzyme from P. funiculosum was released easily from the surface of P(3HB) crystals under an aqueous condition.     

Temperature studies of glyceraldehyde-3-phosphate dehydrogenase binding to liposomes using fluorescence technique.

Interaction of rabbit muscle glyceraldehyde-3-phosphate dehydrogenase with negatively charged liposomes was investigated as a function of temperature. This interaction affects the temperature-dependent conformational transition in the enzyme and exerts stabilizing effect on the protein structure. It can be seen from the fluorescence quenching experiments that the accessibility of tryptophanyl residues and isoindol probe fluorophores (covalently bound with the protein amino groups) for a dynamic quencher, acrylamide, is altered upon binding. This accessibility represented by effective quenching constant (Keff) strongly depends on temperature for unmodified enzyme and for the enzyme adsorbed on liposomes, it is nearly constant over a wide range of temperatures.     

Molecular cloning of the extracellular endodextranase of Streptococcus salivarius.

We report the cloning in Escherichia coli of the gene encoding an extracellular endodextranase (alpha-1,6-glucanhydrolase, EC 3.2.1.11) from Streptococcus salivarius PC-1. Recombinants from a S. salivarius PC-1-Lambda ZAP II genomic library specifying dextranase activity were identified as plaques surrounded by zones of clearing on blue dextran agar. One such clone, PD1, had a 6.3-kb EcoRI fragment insert which encoded a 190-kDa protein with dextranase activity. The recombinant strain also produced two lower-molecular-mass polypeptides (90 and 70 kDa) that had dextranase activity. Native dextranase was recovered from concentrated culture fluids of S. salivarius as a single 110-kDa polypeptide. PD1 phage lysate and PC-1 culture supernatant fluid extract were used to measure substrate specificity of the recombinant and native forms of dextranase, respectively. Analysis of these reaction products by thin-layer chromatography revealed the expected isomaltosaccharide products yielded by the recombinant-specified enzyme but was unable to resolve the larger polysaccharide products of the native enzyme. Furthermore, S. salivarius utilized neither the substrates nor the products of dextran hydrolysis for growth.     

An Insoluble Colored Substrate for Dextranase Assay

An assay of dextranase (EC 3.2.1.11) was developed by using Sephadex G-200 coupled with Remazol Brilliant Blue (RBB) as an insoluble substrate. The assay procedure included incubation of the suspension of the colored substrate in a buffer containing the enzyme under study, removal of a residual insoluble substrate, and measurement of the absorbance of supernatant fluid containing colored soluble hydrolysis products at 595 nm. The procedure was examined in the screening of dextranase-forming bacilli from the microbial collection of the Institute of Biology, Ufa Research Center, RAS.     

An insoluble colored substrate for dextranase assay

An assay of dextranase (EC 3.2.1.11) was developed by using Sephadex G-200 coupled with Remazol Brilliant Blue (RBB) as an insoluble substrate. The assay procedure included incubation of suspension of the colored substrate in buffer containing enzyme under study, removal of residual insoluble substrate, and measurement of the absorbance of supernatant fluid containing colored soluble hydrolysis products at 595 nm. The procedure was examined in the screening of dextranase-forming bacilli from the microbial collection of the Institute of Biology, Ufa Research Center, RAS.     

一株产右旋糖苷酶海洋细菌的筛选鉴定

【目的】筛选鉴定产右旋糖苷酶的海洋细菌,并对其所产右旋糖苷酶的酶学性质及在变异链球菌牙菌斑生物膜中的应用进行初步研究。【方法】利用平板透明圈法从海洋环境中筛选产右旋糖苷酶的细菌,根据菌株形态特征、生理特征及16S rDNA序列确定其分类学地位,采用体外生物膜模型研究该酶对变异链球菌牙菌斑生物膜形成的抑制作用。【结果】从海泥中筛选出一株产右旋糖苷酶的细菌KQ11,初步鉴定为节杆菌(Arthrobacter sp.)。该菌株的最适生长温度为30°C,最适生长pH 7.5,最适生长NaCl浓度为0.4%。右旋糖苷酶的最适作用温度为45°C,最适作用pH为5.5。该酶能有效地抑制变异链球菌牙菌斑生物膜的形成。【结论】菌株KQ11右旋糖苷酶能够抑制变异链球菌牙菌斑生物膜的形成,可望用于漱口液等口腔护理产品中。     

beta-Glucosidase of Penicillium funiculosum. II. Properties and mycelial binding

The properties of two isozymes of beta-glucosidase of Penicillium funiculosum (part I of this series) are described. The molecular weights of isozyme 1 was 2.3 x 10(5) by gel filtration and 1.2 x 10(5) by SDS gel electrophoresis, indicating two subunits. The molecular weight of isozyme 2 was unusually low for a fungal beta-glucosidase: 1.6 x 10(4) by gel filtration and 3.7 x 10(4) in the presence of isopropanol. The two enzymes differed from other fungal beta-glucosidases in their substrate specificities. They showed high activity with pNPG, cellobiose, cellotriose, cellotetraose, cellopentaose, gentiobiose, and laminarin, but were inactive with filter paper, CM cellulose, or derivatives or stabilized by bovine serum albumin and several alcohols such as butanol and propanol. It was inhibited by glucono-delta-lactone (K(i) = 0.67muM) and glucose (K(i) = 0.92mM).The enzyme was quantitatively adsorbed by P. funiculosum mycelium at pH 4 and the immobilized enzyme was as enzymically active as the free enzyme, but more heat stable. The binding efficiency was very high (5000 IU enzyme/g mycelium). It could be quantitatively eluted with buffers at pH 7 or by 0.02M Ca, Mg, or Al chlorides. The binding was selective, since mycelium grown on lactose could produce and also bind only beta-glucosidase isozyme 1, whereas mycelium grown on cellulose could produce as well as bind both beta-glucosidase isozymes as well as cellulases. Mycelial binding was unaffected by washing with EDTA or trypsinization, but was totally lost by washing with dilute KOH, HCl, or ethylenediamine.     

Effect of pretreatment on the hydrolysis of cellulose by Penicillium funiculosum cellulase and recovery of enzyme

Penicillium funiculosum produces a complete cellulase which brings about 97% hydrolysis of cotton and has high beta-glucosidase, xylanase, laminarinase, and lichenase activities. This article deals with the effect of different pretreatments on the hydrolysis of sugarcane bagasse by P. funiculosum enzymes and the recovery of enzyme from the insoluble residues. Enzymic saccharification of bagasse pretreated with hot 1N NaOH followed by neutralization with HCI and steam treated under pressure (7 kg/cm(2)) gave 63 and 59% saccharification, respectively, in 48 h. Hemicellulose is not lost in these pretreatments. With a 30% slurry of steam-treated bagasse, a semisolid mass containing 14% sugar was obtained. A 90% recovery of CMCase, beta-glucosidase, and filter paper activity from the hydrolysates was obtained under the following conditions: (1) maintaining the ratio of enzyme to substrate high by stepwise addition of substrate, (2) brief grinding of the residual substrate with glass powder, and (3) addition of 0.4% Tween-80 to the eluting buffer. The high recovery of cellulolytic enzymes indicates that the adsorption of these enzymes on cellulose is not irreversible.     

The crystal structure of polyhydroxybutyrate depolymerase from Penicillium funiculosum provides insights into the recognition and degradation of biopolyesters

Polyhydroxybutyrate is a microbial polyester that can be produced from renewable resources, and is degraded by the enzyme polyhydroxybutyrate depolymerase. The crystal structures of polyhydroxybutyrate depolymerase from Penicillium funiculosum and its S39 A mutant complexed with the methyl ester of a trimer substrate of (R)-3-hydroxybutyrate have been determined at resolutions of 1.71 A and 1.66 A, respectively. The enzyme is comprised of a single domain, which represents a circularly permuted variant of the alpha/beta hydrolase fold. The catalytic residues Ser39, Asp121, and His155 are located at topologically conserved positions. The main chain amide groups of Ser40 and Cys250 form an oxyanion hole. A crevice is formed on the surface of the enzyme, to which a single polymer chain can be bound by predominantly hydrophobic interactions with several hydrophobic residues. The structure of the S39A mutant-trimeric substrate complex reveals that Trp307 is responsible for the recognition of the ester group adjacent to the scissile group. It is also revealed that the substrate-binding site includes at least three, and possibly four, subsites for binding monomer units of polyester substrates. Thirteen hydrophobic residues, which are exposed to solvent, are aligned around the mouth of the crevice, forming a putative adsorption site for the polymer surface. These residues may contribute to the sufficient binding affinity of the enzyme for PHB granules without a distinct substrate-binding domain.     

The Cell Surface of Trypanosoma musculi Bloodstream Forms. I. Fine Structure and Cytochemistry*†

SYNOPSIS. An extracellular surface coat was observed at the fine-structural level on the outer lamina of the pellicular and flagellar membranes of intact Trypanosoma musculi bloodstream forms. The surface coat had a mean width of 9.2 nm, and was composed of a somewhat electron dense, uneven, fibrillar-like matrix. Brief trypsin treatment of living blood forms completely removed the cell surface coat. Several cytochemical methods applicable to electron microscopy were used to detect the presence and distribution of carbohydrates in the trypanosome's surface coat and pellicular membrane. The polycationic dye compounds employed were: ruthenium red, ruthenium violet, Alcian blue chloride, and lanthanum nitrate. Electron-dense stain reaction products, indicative of polysaccharides, were evident in the surface coat of cells treated with these dyes, which also agglutinated both living and glutaraldehyde fixed cells. Like the surface coat, the pellicular membrane of trypsinized cells gave strong positive staining reactions with the several dyes, indicating the presence of membrane bounded carbohydrates, and living and glutaraldehyde-fixed trypsinized cells were agglutinated with the polycationic stains. Bloodstream forms were treated with the enzymes, α-amylase, dextranase, and neuraminidase. No obvious morphologic difference, however, was apparent between the surface coat of untreated cells and those subjected to treatment with any of the various glycoside hydrolase enzymes. Further, these enzymes had no apparent gross effect on the staining affinity of the surface coat for the several polycationic dyes. Cationized ferritin was used to visualize the negative cell surface charge of T. musculi bloodstream forms. Large quantities of cationized ferritin were bound in the surface coat matrix. Glycoside hydrolase enzyme treatments had no apparent effect on the amount of ferritin bound in the surface coat. Cationized ferritin was bound also to the outer lamina of the pellicular membrane in trypsinized cells, which had quantitatively less ferritin bound per surface unit area than bloodstream forms untreated by the enzyme. Living and glutaraldehyde-fixed cells were agglutinated with cationized ferritin. The results obtained in the various experiments indicated that polyanionic polysaccharides were constituent terminal ligands of the surface coat matrix and pellicular membrane in T. musculi bloodstream forms.