Biotransformation of hydrolysable tannin to ellagic acid by tannase from Aspergillus awamori

Madhuca indica, locally known as mahua in India is a multipurpose tree species. Mahua, particularly bark contains a significant amount of hydrolysable tannin (17.31%) which can be utilized for ellagic acid production through biotransformation. In the present study, mahua bark utilized not only as a raw material for tannase production but also for ellagic acid a well-known therapeutic compound. After prior confirmation of hydrolysable tannin content in bark, it has been supplemented, as a substrate for tannase production through solid state fermentation of Aspergillus awamori. Tannase production, as well as biodegradation of the hydrolysable tannin reached a maximum at 72?h of incubation time. The optimum conditions for tannase production are solid to liquid ratio of 1:2, 35?°C, pH 5.5 and 72h incubation time which resulted 0.256?mg/mL of an extract of ellagic acid. Maximum tannase activity of 56.16?IU/gds at 35?°C and 72h of incubation time is recorded. It seems that tannase production and biotransformation of hydrolysable tannins using bark powder of mahua can be considered as an appropriate alternative to the existing procedures of ellagic acid production.     

泡盛曲霉植酸酶的酶学性质研究

泡盛曲霉植酸酶作为动物饲料添加剂具有广泛的应用前景。以半固体发酵方式培养泡盛曲霉AS3.324(Aspergillus awamori),并得到纯化的植酸酶。对其酶学性质研究表明:其反应最适温度为50～55℃,最适pH为5.5,在37℃下以植酸钠为底物的Km值为1.05nmol/L,Vmax为2.16μmol/(L.min)。EDTA基本不影响植酸酶活性;Ca2 、Mg2 、Mn2 对植酸酶活性有轻微的抑制作用;Fe2 、Zn2 对酶促反应有显著的抑制作用。对该酶的耐热性研究表明,在较高温度条件处理后,仍有较高残余酶活性,与当今商品化的植酸酶相比,有较强的耐热性。     

Enhancement of acid amylase production by an isolated Aspergillus awamori

AIMS: Evaluation of the influence of fermentation components on extracellular acid amylase production by an isolated fungal strain Aspergillus awamori. METHODS AND RESULTS: Eight fungal metabolic influential factors, viz. soluble starch, corn steep liquor (CSL), casein, potassium dihydrogen phosphate (KH(2)PO(4)) and magnesium sulfate (MgSO(4) x 7H(2)O), pH, temperature and inoculum level were selected to optimize amylase production by A. awamori using fractional factorial design of Taguchi methodology. Significant improvement in acid amylase enzyme production (48%) was achieved. The optimized medium composition consisted of soluble starch--3%; CSL--0.5%; KH(2)PO(4)--0.125%; MgSO(4) x 7H(2)O--0.125%; casein--1.5% at pH 4.0 and temperature at 31 degrees C. CONCLUSION: Optimization of the components of the fermentation medium was carried out using fractional factorial design of Taguchi's L-18 orthogonal array. Based on the influence of interaction components of fermentation, these could be classified as the least significant and the most significant at individual and interaction levels. Least significant factors of individual level have higher interaction severity index and vice versa at enzyme production in this fungal strain. The pH of the medium and substrate (soluble starch) showed maximum production impact (60%) at optimized environment. Temperature and CSL were the least influential factors for acid amylase production. SIGNIFICANCE AND IMPACT OF THE STUDY: Acid amylase production by isolated A. awamori is influenced by the interaction of fermentation factors with fungal metabolism at individual and interaction levels. The pH of the fermentation medium and substrate concentration regulates maximum enzyme production process in this fungal strain.     

Acidophilic tannase from marine Aspergillus awamori BTMFW032

Aspergillus awamori BTMFW032, isolated from sea water, produced tannase as extracellular enzyme under submerged culture conditions. Enzyme with a specific activity of 2761.89 IU/mg protein, a final yield of 0.51 %, and a purification fold of 6.32 was obtained after purification to homogeneity by ultrafiltration and gel filtration. SDS-PAGE analyses under non- reducing and reducing conditions yielded a single band of 230 kDa and 37.8 kDa, respectively, indicating presence of six identical monomers. pI of 4.4 and 8.02 % carbohydrate content in the enzyme were observed. Optimal temperature was 30oC, although the enzyme was active at 5-80 oC. Two pH optima, pH 2 and pH 8, were recorded and the enzyme was stable only at pH 2.0 for 24 h. Methylgallate recorded maximal affinity and K(m) and V(max) were recorded, respectively, as 1.9 X 10?3 M and 830 micronmol/min. Impact of several metal salts, solvents, surfactants, and typical enzyme inhibitors on tannase activity were determined to establish the novelty of the enzyme. Gene encoding tannase isolated from A. awamori is 1.232 kb and nucleic acid sequence analysis revealed an open reading frame consisting of 1122 bp (374 amino acids) of one stretch in -1 strand. In-silico analyses of gene sequences and comparison with reported sequences of other species of Aspergillus indicated that the acidophilic tannase from marine A. awamori is differs from that of other reported species.     

Yellow Pigments of Aspergillus niger and Aspergillus awamori

Alkaline degradation of Aurasperone A, C₃₂H₂₆O₁₀, gave a binaphthyl (IIa), m.p. 255°C and acetone. (IIa) afforded a tetraacetate (IIb), C₃₂H₃₀O₁₂ m.p. 219°C and a tetramethyl ether (IId), C₂₈H₃₀O₈, m.p. 188°C. These facts along with the NMR spectra of aurasperone A and (IIb) confirm that aurasperone A is a dimeric 2-methyl-5-hydroxy-6,8-dimethoxy-4H-naphtho[2,3-b]pyran-4-one with asymmetric C-C linkage (7-10′ or 9-10′). The ether (IId) is not identical with 1,1′ ,3,3′ ?6,6′ ,8,8′-octamethoxy-4,4′-binaphthyl. Thus, it follows that (IId) is a 2,4′-binaphthyl and hence aurasperone A is 2,2′-dimethyl-5,5′- dihydroxy-6,6′,8,8′-tetrahydroxy-7,10′-bi[4H-naphtho[2,3-b]pyran-4-one] (I).     

Purification and Characterization of a Feruloylesterase from Aspergillus awamori

A feruloylesterase was purified from the extracellular broth of Aspergillus awamori grown on wheat bran culture. The purified enzyme gave a single band on SDS-polyacrylamide gel electrophoresis and isoelectric focusing, with an apparent M _r of 35,000 and a pI of 3.8, respectively. The substrate specificity of the purified enzyme differed obviously from that of acetylesterase of A. awamori. The enzyme bound to microcrystalline cellulose.     

Enzyme productivity from the protoplast regenerants of Aspergillus awamori

Protoplasts from the hydroiase enzyme producer Aspergillus awamori were isolated using Bulgarian enzyme preparations—Trichocease-SU and Xylanase. Among the regenerated colonies from protoplasts two were selected with enhanced productivity of xylanase, endoglucanase and β-glucosidase. The endoglucanase produced by the parent and one of the regenerants differ in their absorptivity, sensitivity to product inhibition and heat stability.     

Characteristics of transxylosylation by beta-xylosidase from Aspergillus awamori K4

The Aspergillus awamori K4 beta-xylosidase gene (Xaw1) sequence was deduced by sequencing RT-PCR and PCR products. The ORF was 2,412 bp and the predicted peptide was 804 amino acids long, corresponding to a molecular weight of 87,156 Da. The mature protein was 778 amino acids long with a molecular weight of 84,632 Da. A homology search of the amino acid sequence revealed that it was very similar to the Aspergillus niger beta-xylosidase gene with only five amino acid differences. K4 beta-xylosidase had the same catalytic mechanism as family 3 beta-glucosidases, involving Asp in region A. At an early stage in the reaction with xylobiose and xylotriose, the hydrolysis rate was much lower than the transxylosylation rate, decreasing gradually as the substrate concentration increased, whereas the transxylosylation rate increased greatly. Aspergillus awamori K4 beta-xylosidase had broad acceptor specificity toward alcohols, hydroxybenzenealcohols, sugar alcohols and disaccharides. A consensus portion involving the hydroxymethyl group of the acceptor was confirmed in the major transfer products 1(4)-O-beta-D-xylosyl erythritol, (2-hydroxyl)-phenyl-methyl-beta-D-xylopyranoside, 6S-O-beta-D-xylosyl maltitol (S: sorbitol residue) and 6G-O-beta-D-xylosyl palatinose (G: glucosyl residue). This might suggest that the methylene in the hydroxymethyl group facilitates base-catalyzed hydroxyl group attack of the anomeric center of the xylosyl-enzyme intermediate.     

Optimization of extraction and purification of glucoamylase produced by Aspergillus awamori in solid-state fermentation

Various parameters such as solvent selection, concentration, soaking time, and temperature were tested in a single bioreactor in order to determine optimum extraction conditions of glucoamylase, when produced simultaneously with protease by Aspergillus awamari nakazawa MTCC 6652. Optimum conditions were achieved in a 10% glycerol solution soaked for 2 h at 40°C, followed by concentration of extracted glucoamylase (9,157 U/gds) by acetone precipitation (1:2, v/v), which yielded 51.9% recovery. Ion exchange chromatography and gel filtration showed specific activities of 270.5 and 337.5 U/mg, respectively, while SDS-PAGE and zymogram analysis of glucoamylase indicated the presence of three starch-hydrolyzing isoforms with molecular weights of approximately 109.6, 87.1, and 59.4 kDa, respectively     

The primary structure of Aspergillus niger acid proteinase A

The complete amino acid sequence of the acid proteinase A, a non-pepsin type acid proteinase from the fungus Aspergillus niger var. macrosporus, was determined by protein sequencing. The enzyme was first dissociated at pH 8.5 into a light (L) chain and a heavy (H) chain, and the L chain was sequenced completely. Further sequencing was performed with the reduced and pyridylethylated or aminoethylated derivative of the whole protein, using peptides obtained by digestions with Staphylococcus aureus V8 protease, trypsin, chymotrypsin, and lysylendopeptidase. The location of the two disulfide bonds was determined by analysis of cystine-containing peptides obtained from a chymotryptic digest of the unmodified protein. These results established that the protein consists of a 39-residue L chain and a 173-residue H chain that associate noncovalently to form the native enzyme of 212 residues (Mr 22,265). This is, to our knowledge, the first time that such a protein with a rather short peptide chain associated noncovalently has been found. No sequence homology is found with other acid or aspartic proteinases, except for Scytalidium lignicolum acid proteinase B, an enzyme unrelated to pepsin by sequence, which has about 50% identity with the present enzyme. These two enzymes, however, are remarkably different from each other in some structural features.     

Carboxyl groups in the active center of glucoamylase from Aspergillus awamori

The values for the ionization constants of the catalytic groups of the active site of glucoamylase from Asp. awamori for the free enzyme and for the enzyme--substrate complex were calculated. The temperature dependence of the alkaline branch of the pH-dependence curve and the pH dependence in the presence of methanol were determined. The ionization enthalpy delta H = 1.5 +/- 0.3 kcal/mole, the ionization entropy delta S = 20.5 +/- 1.2 e. u. It was assumed that two carboxyl groups are involved in the catalytic act.     

Comparative study of glycosidase from cattle liver and exoglycanase from Aspergillus awamori]

Anomerities of products were estimated for glucosidases from cattle liver and Aspergillus awamori. It was demonstrated that the enzyme from cattle liver is alpha-glucosidase and that from Asp. awamori is exogluconase. It was demonstrated that alpha-glucosidase hydrolyzes the C1--O bond in the course of reaction. delta-Lactone of gluconic acid is a competitive inhibitor for both enzymes. The secondary kinetic isotope effects for both enzymes were measured. The isotope effect for alpha-glucosidase is equal to 1, for exogluconase 1,1 for glycogen and 1,18 for maltose. Some aspects of mechanisms of both enzymes are discussed in terms of the data obtained.