Purification and characterization of intracellular galactose oxidase from Dactylium dendroides

The intracellular galactose oxidase from Dactylium dendroides was purified to homogeneity with a 64% yield. The enzyme is a glycoprotein (7.7% neutral sugars, 1.7% aminosugars) with 72,000 Da of molecular mass. The enzyme showed nonlinear double reciprocal plots with O2 and D-galactose, suggesting cooperative binding for both substrates. The intracellular galactose oxidase catalyzes the oxidation of galactose derivatives and dihydroxyacetone but not of glycerol, glycolaldehyde, beta-hydroxipyruvate, and allyl alcohol which are substrates for the extracellular enzyme. Compared with the extracellular galactose oxidase, the intracellular enzyme showed higher carbohydrate content and sensitivity to diethyldithiocarbamate.     

Identification of deoxynivalenol, 3-acetyldeoxynivalenol and zearalenone in the galactose oxidase-producing fungus Dactylium dendroides

The galactose oxidase-producing fungus Dactylium dendroides was re-identified as a Fusarium species. Fungi of this genus are well known for the production of mycotoxins. Verification of growth of this fungus on rice, corn and liquid medium described for the production of galactose oxidase is provided to determine whether the fungus could produce Fusarium toxins, namely, moniliformin, fusaric acid, fumonisin, zearalenone and the trichothecenes, deoxynivalenol, 3-acetyldeoxynivalenol, fusarenone, nivalenol, diacetoxyscirpenol, neosolaniol, and toxin T-2. Under the culture conditions used, deoxynivalenol, 3-acetyldeoxynivalenol and zearalenone were detected in the fungal culture medium. The finding is consistent with the hypothesis that the fungus is in fact a Fusarium species. This revised version was published online in July 2006 with corrections to the Cover Date.     

Cross-reactive polysaccharides from Trypanosoma cruzi and fungi (especially Dactylium dendroides)

Cross-reactivity between fungal and Trypanosoma cruzi polysaccharides, owing to common residues of beta-D-galactofuranose, beta-D-galactopyranose, and alpha-D-mannopyranose, was demonstrated by using rabbit immune sera against T. cruzi epimastigotes and sera from patients with Chagas' disease. Several chagasic (Ch) sera precipitated partly purified galactomannans from Aspergillus fumigatus and from T. cruzi epimastigotes and also the galactoglucomannan from Dactylium dendroides. Reaction of one Ch serum with T. cruzi galactomannan (GM) was completely inhibited by synthetic beta-D-Galf-(1----3)-Me alpha-D-Manp, and that of another Ch serum with a purified D. dendroides galactoglucomannan (GGM) was partly inhibited by (1----6)-linked (81%) or by (1----3)-linked (33%) beta-D-Galf-Me alpha-D-Manp. The beta-D-Galf-(1----3)-alpha-D-Manp epitope was present in both T. cruzi and D. dendroides polysaccharides. Rabbit anti-T. cruzi antisera precipitated A. fumigatus GM, T. cruzi antigenic extracts containing the lipopeptidophosphoglycan (LPPG), T. cruzi alkali-extracted GM, a synthetic GM, and D. dendroides GGM. Weak reactivities were obtained for a Torulopsis lactis-condensi GM containing beta-D-Galp terminal residues and for baker's yeast mannan with alpha-D-Manp-(1----3)-alpha-D-Manp-(1----2)-alpha-D-Manp+ ++-(1----2) side chains. An anti-LPPG rabbit serum precipitated D. dendroides GGM--a reaction inhibited (82%) by beta-D-Galf-(1----3)-Me alpha-D-Manp and. less efficiently, by a (1----5)-linked beta-D-Galf-tetrasaccharide. Sera from mice immunized with D. dendroides whole cells reacted with CL-strain trypomastigotes as shown by indirect immunofluorescence, by a Staphylococcus adherence test, but were not lytic. Mice immunized with D. dendroides were not protected against a challenge with virulent T. cruzi trypomastigotes.     

Role of carbohydrate content on the properties of galactose oxidase from Dactylium dendroides

The stability of intracellular, extracellular, and deglycosylated forms of galactose oxidase was compared with respect to the denaturing effects of heat, pH, and guanidine hydrochloride. The highly glycosylated forms were found to be more stable to pH and thermal inactivation. All forms were reversibly denaturated by guanidine hydrochoride, but the extent was dependent on the carbohydrate content. Deglycosylation did not affect the affinity of the enzyme for dihydroxyacetone and galactose. Exposure of different forms of galactose oxidase to proteases like pronase and trypsin resulted in a rapid degradation of the glycoenzymes with the formation of stable products. After pronase digestion of intra- and extracellular forms of galactose oxidase catalytic species were isolated by gel filtration. The species (61 and 42 kDa) isolated from pronase-digested extracellular enzyme lost their ability to oxidize primary alcohols. Species (67 and 46 kDa) obtained from the intracellular enzyme kept the specificity of the original enzyme. Active pronase-derived peptides (42 and 46 kDa, respectively) had a higher carbohydrate content than the inactive ones.     

Effect of Culture Conditions on the Production of d-Galactose Oxidase by Dactylium dendroides

The effects on enzyme production of inoculum size and age, medium composition, and culture conditions were studied in shake flasks and in a pilot-plant fermentor. Using a medium consisting of glucose, yeast extract, and inorganic salts in deionized water, we found that the addition of Cu(++) was essential for the formation of active enzyme. Cultures grown in the absence of added copper produced an inactive enzyme protein which could be activated by 10(-3) M Cu(++). Thiamine fulfilled all requirements for exogenous vitamins for growth and enzyme production. Glucose concentrations higher than 1% markedly suppressed enzyme formation. The mycelium inactivated the enzyme on prolonged incubation of the culture. Mycelial autolysates and sonic extracts were found to contain a thermostable and slowly dialyzable galactose oxidase-inactivating factor. The experiments suggest that this factor operates as a chelating agent which forms complexes with the copper of the enzyme. Copper ions (10(-3) M) prevented enzyme inactivation and restored activity to samples previously inactivated by this factor.     

Purification of galactose oxidase from Dactylium dendroides by affinity chromatography on melibiose-polyacrylamide

Galactose oxidase is a fungal enzyme which is known to oxidize the C-6 hydroxymethyl of galactose and galactosamine to an aldehyde group. It has been widely used in glycoconjugate research, for example in the labeling of asialoglycoproteins. We have developed a simple affinity purification for galactose oxidase using melibiose-polyacrylamide. This affinity procedure was used to purify the enzyme from ammonium sulfate precipitates of culture filtrates of Dactylium dendroides. The material containing proteases and other contaminants is eluted in the buffer wash. The galactose oxidase is then specifically eluted from the column with buffer containing 0.1 M D-fucose or D-galactose. Using this procedure, the enzyme was also purified from commercial samples of galactose oxidase which contain high proteolytic activity.     

Cross-Reactive Polysaccharides from Trypanosoma cruzi and Fungi (Especially Dactylium dendroides)1

ABSTRACT. Cross-reactivity between fungal and Trypanosoma cruzi polysaccharides, owing to common residues of β-D-galactofuranose, β-D-galactopyranose, and α-D-mannopyranose, was demonstrated by using a) rabbit immune sera against T. cruzi epimastigotes and b) sera from patients with Chagas’disease. Several chagasic (Ch) sera precipitated partly purified galactomannans from Aspergillus fumigatus and from T. cruzi epimastigotes and also the galactoglucomannan from Dactylium dendroides. Reaction of one Ch serum with T. cruzi galactomannan (GM) was completely inhibited by synthetic β-D-Galf-(1 → 3)-Me α-D-Manp, and that of another Ch serum with a purified D. dendroides galactoglucomannan (GGM) was partly inhibited by (1 → 6)-linked (81%) or by (1 - 3)-linked (33%) β-D-Galf-Me α-D-Manp. The β-D-Galf-(1 → 3)-α-D-Manp epitope was present in both T. cruzi and D. dendroides polysaccharides. Rabbit anti-T. cruzi antisera precipitated A. fumigatus GM, T. cruzi antigenic extracts containing the lipopeptidophosphoglycan (LPPG), T. cruzi alkali-extracted GM, a synthetic GM, and D. dendroides GGM. Weak reactivities were obtained for a Torulopsis lactis-condensi GM containing β-D-Galp terminal residues and for baker's yeast mannan with α-D-Manp-(1 - 3)-α-D-Manp-(1- → 2)-α-D-Manp-(1 → 2) side chains. An anti-LPPG rabbit serum precipitated D. dendroides GGM—a reaction inhibited (82%) by β-D-Galf-(1 → 3)-Me α-D-Manp and, less efficiently, by a (1 → 5)-linked β-D-Galf-tetrasaccharide. Sera from mice immunized with D. dendroides whole cells reacted with CL-strain trypomastigotes as shown a) by indirect immunofluorescence, b) by a Staphylococcus adherence test, but were not lytic. Mice immunized with D. dendroides were not protected against a challenge with virulent T. cruzi trypomastigotes.     

Induction of Superoxide Dismutases in Photobacterium Leiognathi

We investigated the induction of Cu, Zn-SOD (bacteriocuprein) and Fe-SOD in Photobacterium leiognathi DK-AI which was isolated from the light organ of the squid, Droteuthis kensaki. The induction of superoxide dismutases depended on the addition of paraquat to the medium. Induction of SOD by paraquat was attributed mostly to the bacteriocuprein by measuring of the activities of both SODs by using densitometry of isoelectrofocusing gel. When paraquat was added to the culture at various times in the early log phase of growth, the most efficient induction of the SODs. which was measured at the time of harvesting the cells (17 hours after inoculation). was observed when paroquart was added at 60 min after the inoculation. Catalase was not significantly induced by the addition of paraquat or increasing of oxygen concentration. We developed an assay of SOD by modification of a cytochrome c-xanthine oxidase method using a computer equipped absorption spectrophotometer.     

Structure-Function Relationships in Iron and Manganese Superoxide Dismutases

Using the complete sequences for MnSOD from Thermus thermophilus and for FeSOD from E. coli, structural models for both oxidized enzymes have been refined, the Mn protein to an R of 0.186 for all data between 10.0 and 1.8 Å, and the Fe protein to an R of 0.22 for data between 10.0 and 2.5 A. The results of the refinements support the presence of a solvent as a fifth ligand to Mn(III) and Fe(III) and a coordination geometry that is close to trigonal bipyramidal. The putative substrate-entry channel is comprised of residues from both subunits of the dimer; several basic residues that are conserved may facilitate approach of O^?₂, while other conserved residues maintain interchain packing interactions. Analysis of the azide complex of Fe(III) dismutase suggests that during turnover O^?₂ binds to the metal at a sixth coordination site without displacing the solvent ligand. Because crystals reduced with dithionitc show no evidence for displacement of the protein ligands, the redox-linked proton acceptor (C. Bull and J.A. Fee (1985), Journol of the American Chemistry Society 107, 3295–3304) is unlikely to be one of the histidines which bind the metal ion. Structural, kinetic, titration, and spectroscopic data can be accommodated in a mechanistic scheme which accounts for the differential titration behaviour of the Fe(II1) and Fc(II) enzymes at neutral and high pH.     

The utilization of copper and its role in the biosynthesis of copper-containing proteins in the fungus, Dactylium dendroides

Aspects of the utilization of copper by the fungus, Dactylium dendroides, have been studied. The organism grows normally at copper levels below 10 nM. Cells grown in medium containing 30 nM copper or less concentrate exogenous metal at all levels of added copper; copper uptake is essentially complete within 15 min and is not inhibited by cycloheximide, dinitrophenol or cyanide. These results indicate that copper absorption is not an energy-dependent process. The relationship between fungal copper status and the activities of three copper-containing enzymes, galactose oxidase, and extracellular enzyme, the cytosolic, Cu/Zn superoxide dismutase and cytochrome oxidase, has also been established. The synthesis of galactose oxidase protein (holoenzyme plus apo-enzyme) is independent of copper concentration. Cells grown in copper-free medium (less than 10 nM copper) excrete normal amounts of galactose oxidase as an apoprotein. At medium copper levels below 5 micrometer, new cultures contain enough total copper to enable the limited number of cells to attain sufficient intracellular copper to support hologalactose oxidase production. As a result of cell division, however, the amount of copper available per cell drops to a threshold of approx. 10 ng/mg below which point only apogalactose oxidase is secreted. Above 5 micrometer medium copper, holoenzyme secretion is maintained throughout cell growth. The levels of the Cu/Zn superoxide dismutase respond differently in that the protein itself apparently is synthesized in only limited amounts in copper-depleted cells. Total cellular superoxide dismutase activity is maintained under such conditions by an increase in activity associated with the mitochondrial, CN(-)-insensitive, manganese form of this enzyme. Cells grown at 10 micrometer copper show 83% of their superoxide dismutase activity to be contributed by the Cu/Zn form compared to a 17% contribution to the total activity in cells grown at 30 nM copper, indicating that the biosynthesis of the Cu/Zn and Mn-containing enzymes is coordinated. The data show that the level of copper modulates the synthesis of the cytosolic superoxide dismutase. In contrast, the cytochrome oxidase activity of D. dendroides is independent of cellular copper levels obtainable. Thus, the data also suggest that these three enzymes utilize different cellular copper pools. As cells are depleted of copper by cell division, the available copper is used to maintain Cu/Zn superoxide dismutase and cytochrome oxidase activity; at very low levels of copper, only the latter activity is maintained. The induction of the manganisuperoxide dismutase in copper-depleted cells should have practical value in the isolation of this protein.     

Superoxide Dismutases of Escherichia coli: Intracellular Localization and Functions

Escherichia coli B contains two superoxide dismutases which differ with respect to their localization within the cell, the nature of their prosthetic metals, their responses to changes in (p)O(2), and their functions. One of these enzymes, which was liberated from the cells by osmotic shock and which was therefore presumed to be localized in the periplasmic space, is an iron-containing superoxide dismutase. The amount of this iron enzyme did not vary in response to changes in (p)O(2) during growth. In contrast, the other superoxide dismutase was not solubilized by osmotic shock, was a mangano-protein, and was found in greater amounts in cells which had been grown at high (p)O(2). E. coli, which had low levels of the iron-enzyme and high levels of the mangano-enzyme, as a consequence of growth in iron-deficient aerated medium, was killed by exposure to an exogenous flux of O(2) (-) which was generated either photochemically or enzymatically. The addition of bovine superoxide dismutase to the suspending medium protected these cells against this stress. On the other hand, E. coli, which had high levels of the iron-enzyme and low levels of the mangano-enzyme, as a consequence of growth in iron-rich anaerobic medium, was resistant to exogeneous O(2) (-). On the basis of these and of previously reported results (4a, Yost, F. J. and I. Fridovich, J. Biol. Chem., 1973, in press), it appears that the iron superoxide dismutase, of the periplasmic space, serves as a defense against exogenous O(2) (-), whereas the mangano-superoxide dismutase, in the matrix of these cells, serves to counter the toxicity of endogenous O(2) (-).     

Regulation of galactose oxidase synthesis and secretion in Dactylium dendroides: effects of pH and culture density.

The effects of pH and growth density on the amount of an extracellular enzyme, galactose oxidase, synthesized by the fungus Dactylium dendroides were studied. Growth at a pH below 6.7 caused a decrease in the ability of the organism to release galactose oxidase. The enzyme retained by these fungal cells was liberated whenever the pH was raised to 7.0. Cycloheximide addition failed to inhibit the appearance of this protein; [3H]leucine added prior to pH adjustment was not incorporated into the released protein, These observations indicate the released protein is not newly synthesized protein. The retained enzyme would be secreted slowly over a 2-day period if the pH was not increased. In addition to regulating protein retention, pH was also shown to be associated with vacuolization, cell volume, culture density, and inhibition of protein synthesis. Cultures maintained at low pH were characterized by a dense growth consisting of highly vacuolated, buoyant, fungal hyphae. Increasing the pH from 6 to 7 caused a decrease in vacuole size. Cells grown at neutral pH maintained a lower density of growth and, based on activity measurements, synthesized 33% more galactose oxidase. Furthermore, cultures grown at pH 6.0 and maintained at a lower cell density produced galactose oxidase at a level similar to that of cells grown at neutral pH. Thus, the elevated density of the cell culture was inhibitory to galactose oxidase synthesis. The observed effects on protein synthesis and release were rather specific for galactose oxidase, since other extracellular proteins appeared in the earliest stages of growth.     

Recombinant Human Superoxide Dismutases: Production and Potential Therapeutical Uses

In many pathological situations, tissue damage is caused by cellular generation of superoxide free radicals (O₂-). These active species are generated during post-ischemic reperfusion of organs, in hyperoxic tissue, during acute and chronic inflammation and during exposure to ionizing radiation. Exogenous superoxide dismutase (SOD) was shown to significantly prevent such damage.

The genes for human cytosolic Cu/ZnSOD and mitochondrial MnSOD were cloned and introduced into an E. coli expression system. The proteins were expressed in high yields and purified to homogeneity, yielding pharmaceutical-grade materials. These enzymes were used in a variety of in vivo animal models for the demonstration of their protective effects against oxidative damage. Comparative pharmacokinetic studies in rats have revealed that the half-life of Cu/ZnSOD was 6–10min., while that of MnSOD was 5–6 hours, thus indicating that MnSOD may be superior to Cu/ZnSOD for the treatment of chronic diseases. Indeed, MnSOD was found to be erective as an anti-inflammatory agent in the rat carrageenan induced paw edema acute inflammation model. Both enzymes were also effective in ameliorating post-irradiation damage in mice exposed to whole-body or localized chest X-ray radiation.     

Comparative Anti-Inflammatory Activity of Different Superoxide Dismutases and Liposomal Sod in Ischemia

Comparison of superoxide dismutases from different sources with respect to biological activity in the rat tourniquet poditis model shows that anti-ischemic activity is very variable although all the enzymes have the same specific enzymic activity. Both bovine Cu-SOD and E. coli Mn-SOD have excellent properties whereas yeast Cu-SOD and the homologous rat Cu-SOD show zero activity. The results confirm earlier demonstrations that (1) “All superoxide dismutases are equal but some are more equal than others”, (2) at the dose levels used (compatible with possible clinical use) homologous enzyme is inefficient and hence human Cu-SOD may not be effective in humans, (3) liposomal encapsulation of bovine Cu-SOD greatly enhances biological efficacity, provides a slow release mechanism of the enzyme and provides a powerful drug for the treatment of ischemic injury.     

Anaerobic Inductions of Active Forms of Superoxide Dismutases in Escherzchia Coli

Escherichio coli growing anaerobically respond to NO^?₃ with a ～ 3-fold induction of active FeSOD and a ～ 5.5-fold induction of an inactive, but activatable form of MnSOD (pro-MnSOD). Paraquat, which mediates anaerobic electron flow to NO₃-, increased the induction of pro-MnSOD to ~ 25-fold. Strains with defects in the SOD genes or which lacked nitrate reductase activity failed to accumulate active or pro-forms of SODS in response to NO₃-± PQ^{+ +}. Diamide caused anaerobic induction of active MnSOD and this effect was also observed in a glutathione-negative strain. These inductions required de novo synthesis of protein, even when cell content of pro-MnSOD had been elevated by exposure to NO₃-+ PQ⁺⁺ prior to addition of diamide.

These results indicate that oxidation of a cell component increases biosynthesis of the SOD gene product and this postulated oxidation can be caused by terminal electron acceptors, such as dioxygen or NO₃-. In addition, it appears that insertion of the correct metal can be rate-limiting, leading to competition by other metals and to the accumulation of inactive, incorrectly substituted pro-forms. Metal insertion may be dependent upon the valence of the metal, which may be influenced, in turn, by the redox status of the cells. Diamide and redox active agents such as ferricyanide may thus allow anaerobic production of active MnSOD by favoring the production of a complexed form of Mn(III) which can compete favorably with other metal cations for the active site of nascent MnSOD.     

Studies of the Cellular Distribution of Superoxide Disrnutases in Adult and Fetal Rat Tissues

Activities of three types of superoxide dismutase in tissue fractions were significantly lower in fetal and adult brain and fetal limb preparations than in fetal and adult heart preparations. An exception was the cyto-plasmic fraction of adult brain that had levels of Cu, Zn-superoxide dismutase activity comparable to those in cytoplasmic fractions of heart. In addition, Mn superoxide dismutase activity appeared to be very low in all fetal mitochondrial matrix fractions and cytoplasmic fractions as well as in adult brain. Finally, the results of these studies emphasize the importance of two antioxidant defense systems in the tissues studied, one associated with the mitochondrial electron transport system and the other, the cytosolic Cu, Zn enzyme.     

Bacterial Evolutionary Precursors of Eukaryotic Copper–Zinc Superoxide Dismutases

Internalization of a bacteria by an archaeal cell expedited eukaryotic evolution. An important feature of the species that diversified into the great variety of eukaryotic life visible today was the ability to combat oxidative stress with a copper–zinc superoxide dismutase (CuZnSOD) enzyme activated by a specific, high-affinity copper chaperone. Adoption of a single protein interface that facilitates homodimerization and heterodimerization was essential; however, its evolution has been difficult to rationalize given the structural differences between bacterial and eukaryotic enzymes. In contrast, no consistent strategy for the maturation of periplasmic bacterial CuZnSODs has emerged. Here, 34 CuZnSODs are described that closely resemble the eukaryotic form but originate predominantly from aquatic bacteria. Crystal structures of a Bacteroidetes bacterium CuZnSOD portray both prokaryotic and eukaryotic characteristics and propose a mechanism for self-catalyzed disulfide maturation. Unification of a bacterial but eukaryotic-like CuZnSOD along with a ferredoxin-fold MXCXXC copper-binding domain within a single polypeptide created the advanced copper delivery system for CuZnSODs exemplified by the human copper chaperone for superoxide dismutase-1. The development of this system facilitated evolution of large and compartmentalized cells following endosymbiotic eukaryogenesis.     

鸡冠花幼苗热胁迫耐性与其SOD之间的关联

为探讨鸡冠花热胁迫耐性与其SOD之间的关联,选用耐热品种Variety-Centrury Green 10叶期幼苗为试材,用二乙基二硫代氨基甲酸钠(DDTC)进行48 h预处理,之后在45℃人工培养箱中进行热胁迫处理,观察其外观形态.结果表明,20 mmol/L DDTC预处理显著抑制叶片SOD活性,明显减弱鸡冠花的热胁迫耐性,表现为幼苗热胁迫耐受时间显著缩短,弯颈、死亡率明显提高.在自然状态下,叶片中有1种MnSOD、1种Cu/ZnSOD和3种FeSOD;迁移率大小依次为Cu/ZnSODFeSODMnSOD;谱带强弱依次为FesOD>Cu/znSOD>MnSOD.经热胁迫处理后,各种SOD同工酶条带亮度均呈现不同程度的增强—减弱的变化趋势,并诱导产生了1条新的Cu/Zn-SOD条带,与此同时MnSOD条带最先消失.由此推测,鸡冠花品种间耐热性差异与其SOD活性相关,与胁迫强度相对应,同时也与Cu/ZnSOD2的诱导产生相关联. 表现为幼苗热胁迫耐受时间显著缩短,弯颈、死亡率明显提高.在自然状态下,叶片中有1种MnSOD、1种Cu/ZnSOD和3种FeSOD;迁移率大小依次为Cu/ZnSODFeSODMnSO ;谱带强弱依次为FesOD>Cu/znSOD>MnSOD.经热胁迫处理后,各种SOD同工酶条带亮度均呈现不同程度的增强一减弱的变化趋势,并诱导产生了1条新的Cu/Zn-SOD条带,与此同时MnSOD条带最先消失.由此推测,鸡冠花品种间耐热性差异与其SOD活性相关,与胁迫强度相对应,同时也与Cu/ZnSOD2的诱导产生