Quantitative determination of alpha-amylase in glucoamylase preparations.

The use of modified starch substrates for the measurement of α-amylase activity is described. In the presence of excess glucoamylase, the amount of glucose released from substrates containing blockages to exo-enzyme action is proportional to the amount of α-amylase present. The levels of α-amylase in a number of commercial glucoamylase preparations have been determined by this method. The importance of α-amylase in achieving efficient conversion of starch into glucose is illustrated by a comparison of the time courses of degradation of amylopectin by glucoamylase preparations containing low and high levels of α-amylase.     

Repeated fermentation from raw starch using Saccharomyces cerevisiae displaying both glucoamylase and α-amylase

A diploid yeast strain displaying both α-amylase and glucoamylase was developed for repeated fermentation from raw starch. First, the construct of α-amylase was optimized for cell surface display, as there have been no reports of α-amylase-displaying yeast. The modified yeast displaying both glucoamylase and α-amylase produced 46.5 g/l of ethanol from 200 g/l of raw corn starch after 120 h of fermentation, and this was 1.5-fold higher when compared to native α-amylase-displaying yeast. Using the glucoamylase and modified α-amylase co-displaying diploid strain, we repeated fermentation from 100g/l of raw starch for 23 cycles without the loss of α-amylase or glucoamylase activity. The average ethanol productivity and yield during repeated fermentation were 1.61 g/l/h and 76.6% of the theoretical yield, respectively. This novel yeast may be useful for reducing the cost of bio-ethanol production and may be suitable for industrial-scale bio-ethanol production.     

Measurement of α-amylase and glucoamylase activities produced during fermentation

A method for the automatic measurement of α-amylase and glucoamylase activities during fermentation has been developed. Soluble starch dyed with Remazol Brilliant Orange was used as the substrate for α-amylase and 4-nitrophenyl α-d-glucopyranoside for glucoamylase. The same automatic analysis system could be used for both of these enzymes because the reaction products were measured at the same wavelength. Simultaneous pick-up of enzyme and the respective substrate was enabled by using two samplers. The presence of α-amylase did not interfere with the glucoamylase determination. Absolute values for α-amylase activity were obtained using a mathematical correction. Monitoring of these enzymes was accomplished during microbial fermentation.     

Development of new α-amylases for raw starch hydrolysis

This paper describes the discovery of a new 4 domain α-amylase from Anoxybacillus contaminans which very efficiently hydrolyses raw starch granules. Compared to traditional starch liquefying α-amylases, this new 4 domain α-amylase contains a starch binding domain. The presence of this starch-binding domain enables the enzyme to efficiently hydrolyse starch at a temperature below the gelatinisation temperature. At a reaction temperature of 60°C and in combination with a glucoamylase from Aspergillusniger it was possible to liquefy 99% of the starch obtaining a DX value of 95%.

Furthermore, we describe how the current HFCS process can be turned into a low temperature simultaneous liquefaction and saccharification process by using this new 4 domain α-amylase in combination with a glucoamylase.     

Multi-objective optimization of bioethanol production during cold enzyme starch hydrolysis in very high gravity cassava mash

Cold enzymatic hydrolysis conditions for bioethanol production were optimized using multi-objective optimization. Response surface methodology was used to optimize the effects of α-amylase, glucoamylase, liquefaction temperature and liquefaction time on S. cerevisiae biomass, ethanol concentration and starch utilization ratio. The optimum hydrolysis conditions were: 224 IU/g_starch α-amylase, 694 IU/g_starch glucoamylase, 77 °C and 104 min for biomass; 264 IU/g_starch α-amylase, 392 IU/g_starch glucoamylase, 60 °C and 85 min for ethanol concentration; 214 IU/g_starch α-amylase, 398 IU/g_starch glucoamylase, 79 °C and 117 min for starch utilization ratio. The hydrolysis conditions were subsequently evaluated by multi-objectives optimization utilizing the weighted coefficient methods. The Pareto solutions for biomass (3.655-4.380 × 10⁸ cells/ml), ethanol concentration (15.96-18.25 wt.%) and starch utilization ratio (92.50-94.64%) were obtained. The optimized conditions were shown to be feasible and reliable through verification tests. This kind of multi-objective optimization is of potential importance in industrial bioethanol production.     

Polysaccharide-hydrolyzing enzymes in the GenusBacillus

The production of α-amylase, glucoamylase, C_x- and C₁-cellulase, lichenase, xylanase and mannanase was followed in 118 strains of 25 species of the genusBacillus using specific substrates obtained by crosslinking of polysaccharides with 2-chloromethyloxiran. The α-amylase production was also followed using a chromolytic substrate.     

Studies on extracellular and intracellular purified amylases from a thermophilic Bacillus stearothermophilus

Extracellular and intracellular amylases have been purified from a thermophilic Bacillus stearothermophilus and further studies have been made with the purified enzyme. The molecular weights for extra- and intracellular α- and β-amylases were found to be 47 000, 58 000, 39 000 and 67 000, respectively. α-Amylase (1,4-α-d-glucan glucanohydrolase, EC 3.2.1.1) and glucoamylase (1,4-α-d-glucan glucohydrolase, EC 3.2.1.3) were glycoproteins, whereas β-amylase (1,4-α-d-glucan maltohydrolase, EC 3.2.1.2) had little or no carbohydrate moiety. Extracellular FI (α-amylase), FIII (glucoamylase), FIV and FV (α-amylase) had carbohydrate moieties of 14.4, 27.0, 11.0 and 12.5%, respectively, whereas intracellular amylases FI (α-amylase), FII (β-amylase) and FIII (α-amylase) contained 15.2, 0.8 and 13.4% carbohydrate, respectively. The amino acid profile of the amylase protein digest showed a total number of 16 amino acids with aspartic acid showing the highest value followed by glutamic acid and leucine plus isoleucine. Compared to other thermostable amylases, proline and histidine contents were low. Both α- and β- amylase had the - SH group at their active site, which was essential for enzyme activity. EDTA and parachloromercuribenzoate exhibited dose dependent non-competitive inhibition of enzyme activity indicating the involvement of a divalent cation and the - SH group for activity.     

Expression and secretion of barley α-amylase and A.niger glucoamylase inSaccharomyces cerevisiae

cDNAs of barley α-amylase andA. niger glucoamylase were cloned in oneE. coli-yeast shuttle plasmid resulting in the construction of expression secretion vector pMAG15. pMAG15 was transformed intoS. cerevisiae GRF18 by protoplast transformation. The barley α-amylase andA. niger glucoamylase were efficiently expressed under the control of promoter and terminator of yeast PGK gene and their own signal sequence. Over 99% of the enzyme activity expressed was secreted to the medium. The recombinant yeast strain, S.cerevisiae GRF18 (pMAG15), hydrolyzes 99% of the starch in YPS medium containing 15% starch in 47 h. The glucose produced can be used for the production of ethanol.     

Characterization of the amylolytic system ofCandida strains

Some physical and chemical properties ofα-amylase (EC 3.2.1.1) and glucoamylase (EC 3.2.1.3) produced in semisolid fermentation byCandida fennica FTPT-1829,C. famata FTPT-1539 andC. fennica FTPT-8903 were determined. The optimum temperature values were 42, 44, 48 °C and 60, 50, 50 °C forα-amylase and glucoamylase excreted byC. fennica 8903,C. fennica 1829 andC. famata 1539, respectively. The optimum pH values for all strains were 5.0 and 6.0 forα-amylase and glucoamylase, respectively. The degradation of pullulan by all the yeast species indicates debranching activity. This research was carried out with financial support fromPrPq/UFMG. The second author received grants fromRHAE/CNPq.     

Purification and characterization of an extracellular glucoamylase from the yeastCandida tsukubaensis CBS 6389

The starch-degrading yeastCandida tsukubaensis CBS 6389 secreted amylase at high activity when grown in a medium containing soluble starch. The extracellular α-amylase activity was very low. The major amylase component was purified by DEAE-Sephadex A-50 chromatography and Ultrogel AcA 44 gel filtration and characterized as a glucoamylase. The enzyme proved to be a glycoprotein with a molecular weight of 56000. The glucoamylase had a temperature optimum at 55°C and displayed highest activity in a pH range of 2.4–4.8. Acarbose strongly inhibited the purified glucoamylase. Debranching activity was present as demonstrated by the release of glucose from pullulan.     

双酶法水解辐照改性马铃薯淀粉动力学研究

为了解辐照改性马铃薯淀粉的酶解特性,用α-淀粉酶和糖化酶同时作用于马铃薯原淀粉和经400 kGy剂量辐照处理后淀粉,考察了pH值、酶解温度、α-淀粉酶用量、糖化酶用量对反应速率的影响.以米氏方程为基础,用Lineweaver-Burk法求解动力学参数.结果表明,辐照后马铃薯淀粉的酶解反应速率明显高于马铃薯原淀粉.在单一水解体系中,α-淀粉酶和糖化酶对辐照前后马铃薯淀粉的降解都遵循Michaelis-Menten方程,α-淀粉酶的Km分别为11.343 mg· mL-1和9.386 mg· mL-1,Vmax分别为0.406 mg（mL·min）-1和1.079 mg（mL·min）-1;糖化酶的Km分别为10.307 mg· mL-1和8.905 mg·mL-1,Vmax分别为0.338 mg（mL·min）-1和0.821mg（mL·min）-1;水解产物葡萄糖对反应体系具有竞争性抑制剂的作用,其抑制常数Ki分别为1.298 mg·mL-1和0.934 mg·mL-1.研究结果表明辐照有效提高了马铃薯淀粉的酶解反应活性.     

A Convenient Method for Rapid Determination of Cereal Proteins: A Device to Eliminate the Effect of Color Substances on the Biuret Procedure

At least, four kinds of amylase inhibitors are found in culture of Streptomyces sp. No.280.¹⁾ A large amount of amylase inhibitors were produced by Streptomyces sp. No. 280 when cultivated on 3% oatmeal medium and it was found that the molecular weight of the inhibitors were transformed to smaller molecules during the cultivation time. The transformation of the amylase inhibitor was found to result from degradation of its carbohydrate moiety by α-amylase in the culture broth. The amylase inhibitor was hydrolyzed partially by the action of taka-amylase A or hog pancreatic α-amylase. With hydrolyzation of amylase inhibitor by α-amylase, neutral sugars (mainly maltose) were liberated from the amylase inhibitor and a modified inhibitor was newly formed, but amylase inhibitory activity against glucoamylase was not changed. The inhibitory activity against muscle Phosphorylase a, however, was almost completely lost.     

Intraspecific protoplast fusion of amylase-producing strains of Candida fennica

The production of -amylase was increased by protoplast fusion of auxotrophic mutants of Candida fennica FTPT-8903. One prototrophic fusant was 90% and 32% more efficient in producing -amylase in semi-solid and liquid fermentation, respectively, than the parental strains. Protoplast fusion did not significantly stimulate the synthesis of glucoamylase in the fusants.     

Fast and reliable method for simultaneous zymographic detection of glucoamylase and α-amylase in fungal fermentation

Detection of α-amylase and glucoamylase in crude fermentation extracts using a single native electrophoresis gel and zymogram is described in this article. Proteins were printed on substrate gel and simultaneously onto a membrane in a three-sandwich gel. α-Amylase was detected on the substrate gel with copolymerized β-limit dextrins and iodine reagent. Glucoamylases were detected on the membrane using a coupled assay for glucose detection. Both amylases were detected in native gel using starch and iodine reagent. The described technique can be a helpful tool for monitoring and control of fermentation processes because fungal amylase producers almost always synthesize both amylases.     

Enzymatic synthesis of p-nitrophenyl 35-O-β-N-acetylglucosaminyl|-α-maltopentaoside by lysozyme; a novel substrate for human amylase assay

Transglycosylation from di-N-acetylchitobiose to the 3-position at the nonreducing end glucosyl group of p-nitrophenyl α-maltopentaoside was regioselectively induced through the use of hen egg-white lysozome. The enzyme formed p-nitrophenyl 3⁵-O-β-N-acetylglucosaminyl-α-maltopentaoside (5% of the enzyme-catalyzed net decreased of p-nitrophenyl α-maltopentaoside) from di-N-acetylchitobiose as a donor and p-nitrophenyl α-maltopentaoside as an acceptor. The rate of the transglycosylation depended on the concentration of substrate, the temperature and the pH. The hydrolytic actions of human pancreatic and salivary α-amylase on this derivative were examined. The maltopentaoside derivative was shown to be useful as a substrate for α-amylase assay through a coupled reaction involving α-D-glucosidase and glucoamylase.     

Cloning of the α-Amylase cDNA of Aspergillus shirousamii and Its Expression in Saccharomyces cerevisiae

α-Amylase cDNA was cloned and sequenced from Aspergillus shirousamii RIB2504. The putative protein deduced from the cDNA open reading frame (ORF) consisted of 499 amino acids with a molecular weight of 55,000. The amino acid sequence was identical to that of the ORF of the Taka-amylase A gene of Aspergillus oryzae, while the nucleotide sequence was different at two and six positions in the cDNA ORF and 3? non-coding regions, respectively, so far determined. The α-amylase cDNA was expressed in Saccharomyces cerevisiae under the control of the yeast ADH1 promoter using a YEp-type plasmid, pYcDE1. The cDNA of glucoamylase, which was previously cloned from the same organism, was also expressed under the same conditions. Consequently, active α-amylase and glucoamylase were efficiently secreted into the culture medium. The amino acid sequence of the N-terminal regions of these enzymes purified from the yeast culture medium confirmed that the signal sequences of these enzymes were cleaved off at the same positions as those of the native enzymes of A. shirousamii.     

Kinetics of the amylase system of Saccharomycopsis fibuliger

The extracellular amylases produced by Saccharomycopsis fibuliger have been studied with the intent of identifying the kinetic mechanism and product distribution, and modelling the production of d-glucose during starch hydrolysis. High performance liquid chromatography was effectively used to separate and quantify the product oligomers released. α-Amylase rapidly hydrolysed the long substrate chains into smaller oligomers which became the substrate for glucoamylase in the production of d-glucose. The formation of a rate limiting substrate occurred late in the reaction. Glucoamylase and α-amylase rates were fitted to Michaelis-Menten models with d-glucose inhibition included.     

Hydrolysis of wheat flour with amylase preparations and individual enzymes

Rheological properties of wheat flour were studied in the course of its processing (cooking and saccharification). The effects of commercial α-amylase preparations were compared during flour preparation. Test preparations were equally potent in decreasing the viscosity of an all-grain batch. Homogenous glucoamylases isolated from Aspergillus differed in the presence or absence of the starch-binding domain. The starch-binding domain provided for the high activity of glucoamylase on insoluble starch, but gave no advantages in saccharification of pretreated wheat flour.     

Some Properties of Amylase Inhibitor Produced by Streptomyces sp. No. 280

A strain of Streptomyces produces a new substance capable of inactivating some amylases. This has not been reported by previous workers.

This amylase inhibitor was purified by means of acetone treatment, active carbon adsorption and column chromatography on DEAE-cellulose.

It was dialyzable through a cellophane membrane and soluble in water and methyl alcohol. The inhibitor had a small molecular weight and was a peptide-like substance. The inhibiting substance was resistant to the temperatures, and acted as inhibitor of glucoamylase, bacterial saccharogenic α-amylase, salivary and pancreatic α-amylases.     

Acid-stable α-Amylase of Black Aspergilli

When black Aspergilli were cultivated in appropriate condition, culture filtrate showed dextrinizing activity even after acid treatment such as pH 2.5, at 37°C for 30 minutes. It suggested the existence of acid-stable dextrinizing amylase. To isolate this enzyme paper el-ectrophoretic procedure was carried out and the spot which showed acid-stable dextrinizing activity was obtained in addition to α-amylase and glucoamylase spots. This new amylase was purified by fractional precipitation with ammonium sulfate, rivanol and acetone, and was obtained in a crystalline form.